Silicon ChipJanuary 2006 - Silicon Chip Online SILICON CHIP
  1. Outer Front Cover
  2. Contents
  3. Publisher's Letter: Australia should build nuclear power stations
  4. Feature: Holden’s EFIJY Show Car by Jeff Brown
  5. Review: Tektronix Arbitrary/Function Generators by Peter Smith
  6. Project: Pocket TENS Unit For Pain Relief by John Clarke
  7. Feature: Excellence In Education Technology Awards by Silicon Chip
  8. Project: “Little Jim” AM Radio Transmitter by Jim Rowe
  9. Book Store
  10. Project: Universal High-Energy Ignition System; Pt.2 by John Clarke
  11. Project: Building The Ultimate Jukebox; Pt.2 by Ross Tester
  12. Project: Build A MIDI Drum Kit; Pt.3 by John Clarke
  13. Project: PICAXE-Based 433MHz Wireless Thermometer by Stan Swan
  14. Vintage Radio: The AWA B25/6 stereogram by Rodney Champness
  15. Salvage It: A human-powered LED torch for next to nothing by Julian Edgar
  16. Advertising Index

This is only a preview of the January 2006 issue of Silicon Chip.

You can view 41 of the 120 pages in the full issue, including the advertisments.

For full access, purchase the issue for $10.00 or subscribe for access to the latest issues.

Items relevant to "Pocket TENS Unit For Pain Relief":
  • Pocket TENS Unit PCB [11101061] (AUD $10.00)
  • PCB pattern for the Pocket TENS Unit (PDF download) [11101061] (Free)
  • Pocket TENS Unit front panel artwork (PDF download) (Free)
Items relevant to "“Little Jim” AM Radio Transmitter":
  • "Little Jim" AM Transmitter PCB [06101062] (AUD $15.00)
  • MC1496BDG or MC1496DR2G Balanced Modulator/Demodulator IC (SOIC-14) (Component, AUD $3.00)
  • PCB patterns for the "Little Jim" AM Radio Transmitter (PDF download) [06101061/2] (Free)
  • "Little Jim" AM Radio Transmitter front panel artwork (PDF download) (Free)
Items relevant to "Universal High-Energy Ignition System; Pt.2":
  • (2005 Version) PIC16F88-E/P programmed for the Universal High Energy Electronic Ignition System [ignition.hex] (Programmed Microcontroller, AUD $15.00)
  • PCB pattern for the Universal High-Energy Ignition System (PDF download) [05112051] (Free)
  • Universal High-Energy Ignition System front panel artwork (PDF download) (Free)
Articles in this series:
  • Universal High-Energy Ignition System; Pt.1 (December 2005)
  • Universal High-Energy Ignition System; Pt.1 (December 2005)
  • Universal High-Energy Ignition System; Pt.2 (January 2006)
  • Universal High-Energy Ignition System; Pt.2 (January 2006)
Items relevant to "Building The Ultimate Jukebox; Pt.2":
  • Ultimate Jukebox front panel artwork (PDF download) (Free)
Articles in this series:
  • Building The Ultimate Jukebox; Pt.1 (December 2005)
  • Building The Ultimate Jukebox; Pt.1 (December 2005)
  • Building The Ultimate Jukebox; Pt.2 (January 2006)
  • Building The Ultimate Jukebox; Pt.2 (January 2006)
  • Building The Ultimate Jukebox; Pt.3 (February 2006)
  • Building The Ultimate Jukebox; Pt.3 (February 2006)
Items relevant to "Build A MIDI Drum Kit; Pt.3":
  • PIC16F88-I/P programmed for the MIDI Drum Kit [drumkit16.hex] (Programmed Microcontroller, AUD $15.00)
  • PIC16F88 firmware and source code for the MIDI Drum Kit [drumkit16.hex] (Software, Free)
  • PCB patterns for the MIDI Drum Kit (PDF download) [01211051/2/3] (Free)
  • MIDI Drum Kit front panel artwork (PDF download) (Free)
Articles in this series:
  • Build A MIDI Drum Kit (November 2005)
  • Build A MIDI Drum Kit (November 2005)
  • Build A MIDI Drum Kit; Pt.2 (December 2005)
  • Build A MIDI Drum Kit; Pt.2 (December 2005)
  • Build A MIDI Drum Kit; Pt.3 (January 2006)
  • Build A MIDI Drum Kit; Pt.3 (January 2006)
  • Build A MIDI Drum Kit; Pt.4 (February 2006)
  • Build A MIDI Drum Kit; Pt.4 (February 2006)
Stereo Headphone Distribution Amp Ref: Silicon Chip November 05 Enables you to drive up to two stereo headphones from any line level (1 volt peak to peak) input. The circuit features a facility to drive headphones with impedances from about 8600 Ω. The Jaycar kit comes with all specified board components & quality fibreglass tinned P.C.B. YOUR LOCAL JAYCAR STORE Freecall Orders: Ph 1800 022 888 NEW SOUTH WALES Albury Ph (02) 6021 6788 Alexandria Ph (02) 9699 4699 Bankstown Ph (02) 9709 2822 Blacktown Ph (02) 9678 9669 Bondi Junction Ph (02) 9369 3899 Brookvale Ph (02) 9905 4130 Campbelltown Ph (02) 4620 7155 Erina Ph (02) 4365 3433 Hornsby Ph (02) 9476 6221 Newcastle Ph (02) 4965 3799 Parramatta Ph (02) 9683 3377 Penrith Ph (02) 4721 8337 Silverwater Ph (02) 9741 8557 St. Leonards Ph (02) 9439 4799 Sydney City Ph (02) 9267 1614 Taren Point Ph (02) 9531 7033 Wollongong Ph (02) 4226 7089 VICTORIA Coburg Ph (03) 9384 1811 Frankston Ph (03) 9781 4100 Geelong Ph (03) 5221 5800 Melbourne Ph (03) 9663 2030 Ringwood Ph (03) 9870 9053 Springvale Ph (03) 9547 1022 Sunshine Ph (03) 9310 8066 QUEENSLAND Aspley Ph (07) 3863 0099 Mermaid Beach Ph (07) 5526 6722 Townsville Ph (07) 4772 5022 Underwood Ph (07) 3841 4888 Woolloongabba Ph (07) 3393 0777 AUSTRALIAN CAPITAL TERRITORY Canberra Ph (02) 6239 1801 TASMANIA Hobart Ph (03) 6272 9955 SOUTH AUSTRALIA Adelaide Ph (08) 8231 7355 Clovelly Park Ph (08) 8276 6901 WESTERN AUSTRALIA Perth Ph (08) 9328 8252 NORTHERN TERRITORY Darwin Ph (08) 8948 4043 NEW ZEALAND Christchurch Ph (03) 379 1662 Glenfield Ph (09) 444 4628 Hamilton Ph (07) 846 0177 Manukau Ph (09) 263 6241 Newmarket Ph (09) 377 6421 Wellington Ph (04) 801 9005 Freecall Orders Ph 0800 452 9227 8 EXCLUSIVE TO JAYCAR 34. To ensure the best possible performance to the Headphone Amp kit, this provides regulated ±15V and +5V outputs. Toroidal transformer required use MT-2086 Cat. KC-5418 $ 95 Parramatta Store now open until 5pm Saturdays! These clocks are hypnotic! Ref: Silicon Chip June 2005. They consist of an AVR driven clock circuit, that also produces a dazzling display with the 60 LEDs around the perimeter. It looks amazing, but can't be properly explained here. We have filmed it in action so you can see for yourself on our website! Kit supplied with double sided silkscreened plated through hole PCB and all board components as well as the special clock housing! Available in Red (KC-5404) and Blue (KC-5416) Cat. KC-5417 $ 95 Headphone Amp Power Supply 17. "Clock Watchers" LED Clock Kits Cat. KC-5404 $ 00 Cat. KC-5416 $ 95 189. 129. Lead Acid Battery Zapper Kit Extend the working life of your lead acid battery! Ref: Silicon Chip July ‘05. Designed to produce bursts of high-energy pulses to help reverse the damaging effects of sulphation in "wet" lead acid batteries. This is particularly useful when a battery has been sitting for a length of time without use. Its effects are dependent on the battery’s condition and type, but the results can be quite impressive. Kit supplied with case, Cat. KC-5414 $ .95 silk screened lid, leads, inductor and all electronic components. 39 Universal High Energy Ignition Now with PIC Ref: Silicon Chip June 98 A high energy 0.9ms spark burns fuel faster and more efficiently to give you more power! Includes PCB, case and all electronic components. Annunciator Kit Exclusive to Jaycar Ref: Silicon Chip Dec 05 Need people to take a number when waiting to be served? This electronic signaling device has digits 75mm high, each using 28 high intensity red LEDs. The numbers display from 00 to 99 is incremented by pressing a button on the separate small control box. The annunciator features a built in piezo buzzer to produce a short 'beep' each time the display is updated. Kit includes: PCB, Case and all Cat. KC-5420 electronic components. $ 95 Power: Regulated 12VDC 59. NEW & IMPROVED Cat. KC-5419 $ 95 94. Performance Electronics for Cars Book Where Have All The Scoreboards Gone? Basketball Scoreboard Kit Over 160 pages! The Performance Electronics for Cars Book from Silicon Chip publications has chapters on modification and theory, Cat. BS-5080 $ 80 as well as the 16 projects. 19. Independent Electronic Boost Controller Change between 2 completely different boost maps at the flick of a switch. Boost curve selection is via a dashboard switch & it is all programmed using the Handheld Digital Controller - KC-5386. Kit supplied with PCB, machined case, and all electronic components. Suitable for EFI and engine management systems only Cat. KC-5387 $ .95 179 Smart Fuel Mixture Display This new ‘smart’ version has a few additional touches such as, auto dimming for night driving, emergency lean-out alarm, and better circuit protection. Another great feature, is the ‘dancing’ display which operates when the ECU is operating in closed loop. Closed loop means that the air/fuel ratio is optimum for fuel economy & emission performance. Kit supplied with PCB and all electronic components. •Car must be fitted withair flow and EGO sensors Cat. KC-5374 $ .95 (standard on all EFI systems) for full functionality. 27 PRICES VALID TO END JANUARY 2006 Exclusive To Jaycar! This kit enables you to make a full-sized electronic scoreboard, in particular for Basketball but also adaptable for netball and other games. Ref: Silicon Ship March/April/May 2005. It can built for the fraction of the cost of commercial equivalents and has a completely wireless scoring console that can control one or multiple scoreboards. You can mount the scoreboard high up in the court plug it in to a 240VAC power point and then control them from a table courtside with no messy wiring. It features Home/Away team scores 0 to 199 game period, countdown time, Home/Away time and the addition of a new 'foul' feature. It measures 900 x 600mm and comes with all pre-cut scoreboard woodwork, screen printed face, display filters, mounting plates, preprogrammed microcontroller, printed circuit boards, 2.4GHz transmitter & receivers, pre-punched control console with special piezo end-of-game quarter sounder, and all electronic components to Cat. KC-5408 make one scoreboard. $ 00 Extra Scoreboards Available Contain everything included in the original kit without parts for the control console Cat. KC-5409 $649.00 799. FOR INFORMATION AND ORDERING TELEPHONE> 1800 022 888 INTERNET> www.jaycar.com.au Contents www.siliconchip.com.au Vol.19, No.1; January 2006 FEATURES    8 Holden’s EFIJY Show Car Stunning looks and PICAXE-based electronics – by Jeff Brown 14 Review: Tektronix Arbitrary/Function Generators New AFG3000 Series from Tektronix feature large LCDs and generate function, pulse and arbitrary waveforms – by Peter Smith Holden’s EFIJY Show Car: PicaxeBased Electronics – Page 8. 25 Excellence In Education Technology Awards SILICON CHIP’s new awards for electronics technology in education PROJECTS TO BUILD 16 Pocket TENS Unit For Pain Relief Alleviate pain electronically with this TENS unit (Transcutaneous Electrical Nerve Stimulation). It’s pocket-size and easy to build – by John Clarke 32 “Little Jim” AM Radio Transmitter Use it to transmit to your vintage radio set or to a car radio. A range of just four metres keeps it legal but where did the name come from? – by Jim Rowe 68 Universal High-Energy Ignition System; Pt.2 Six versions to build, to suit your car’s trigger input. And there’s info on converting a points distributor to Hall Effect pickup – by John Clarke 78 Building The Ultimate Jukebox; Pt.2 Pocket TENS Unit For Pain Relief – Page 16. Second article has all the details on building the wooden cabinet and applying the carpet treatment – by Ross Tester 86 Build A MIDI Drum Kit; Pt.3 Building the various sensors and the stand – by John Clarke 98 Picaxe-Based 433MHz Wireless Thermometer Want to transmit temperature data 50 metres or more from a remote sensor to display on a PC? It’s surprisingly easy – by Stan Swan SPECIAL COLUMNS 44 Circuit Notebook (1) Winch Controller For Boaties & 4WDers; (2) Pushbutton Relay Selector; (3) Dual Input-Combining Stereo Line Amplifier; (4) Battery Desulphation Progress Monitor; (5) Nicad Charger With Voltage Cutout “Little Jim” AM Radio Transmitter – Page 32. 52 Serviceman’s Log I hate servicing rear-projection sets – by the TV Serviceman 104 Vintage Radio The AWA B25/6 stereogram – by Rodney Champness 109 Salvage It! A human-powered LED torch for next to nothing – by Julian Edgar DEPARTMENTS   2   4 65 103 Publisher’s Letter Mailbag Product Showcase Order Form siliconchip.com.au 114 117 118 120 Ask Silicon Chip Notes & Errata Market Centre Ad Index Building The HEI & Converting A Points “Dizzie” To Hall Effect Pickup – Page 68. January 2006  1 SILICON CHIP www.siliconchip.com.au Publisher & Editor-in-Chief Leo Simpson, B.Bus., FAICD Production Manager Greg Swain, B.Sc.(Hons.) Technical Editor Peter Smith Technical Staff John Clarke, B.E.(Elec.) Ross Tester Jim Rowe, B.A., B.Sc, VK2ZLO Reader Services Ann Jenkinson Advertising Enquiries Lawrence Smith Benedictus Smith Pty Ltd Phone (02) 9211 8035 Fax: (02) 9211 0068 lawrence<at>benedictus-smith.com Regular Contributors Brendan Akhurst Rodney Champness, VK3UG Julian Edgar, Dip.T.(Sec.), B.Ed, Grad.Dip.Jnl Mike Sheriff, B.Sc, VK2YFK Stan Swan SILICON CHIP is published 12 times a year by Silicon Chip Publications Pty Ltd. ACN 003 205 490. ABN 49 003 205 490 All material copyright ©. No part of this publication may be reproduced without the written consent of the publisher. Printing: Hannanprint, Noble Park, Victoria. Distribution: Network Distribution Company. Subscription rates: $83.00 per year in Australia. For overseas rates, see the subscription page in this issue. Editorial office: Unit 8, 101 Darley St, Mona Vale, NSW 2103. Postal address: PO Box 139, Collaroy Beach, NSW 2097. Phone (02) 9979 5644. Fax (02) 9979 6503. E-mail: silchip<at>siliconchip.com.au Publisher’s Letter Australia should build nuclear power stations Australian cities are facing power shortages and we need to build new power stations to keep up with the demand. The New South Wales state government has just announced the intention to build two new gas-fired power stations (300MW & 400MW) and that is a good move, especially as they have not opted for coal-fired stations. We have been against the building of new coalfired stations in Australian for quite a few years now. But the new gas-fired stations are mainly intended for meeting peak loads, not base load. Ultimately, New South Wales and other states are going to need more base load power stations. And in the past, the only option has been coal-fired. Renewable power such as hydro, wind and solar can only take us so far, since they can only make a relatively small contribution (say 20% maximum) to the overall energy mix. But coal-fired stations are no longer an attractive option. For a start, Australia is already being pilloried for its large carbon dioxide emissions and more coal-fired stations will only make that worse. Second, open-cut coal mines are an enormous blight on the landscape – hundreds of square kilometres of open-cut scar has to be seen to be believed – and extremely costly to restore and re-vegetate. And you can forget these weird schemes for underground carbon dioxide sequestration – that just ain’t gonna happen in spite of there being at least one small installation overseas. So that leaves nuclear power. And why not? There is no pollution in normal operation (apart from the huge amounts of waste heat produced, as with any thermal power station). Nor is there any huge mining scar – we already have several uranium mines which could easily satisfy Australia’s demand. And we will eventually be storing long-term nuclear waste in the Northern Territory, following recent enabling legislation. So why not take the next logical step and build some nuclear power stations? The first one could be sited next to the proposed Sydney water desalination plant at Kurnell. This will need a great deal of power and it just makes a lot of sense to build the power station next to it, just as Perth’s desalination plant will be built next to the existing Kwinana power station. To make it worthwhile, the proposed nuclear power station should not just meet the demands of the desalination plant when it is operating but also make a reasonable contribution to Sydney’s base load. In fact, if possible, it would make sense to power the desalination plant only at night and provide base power during the day. That probably means a rating of at least one Gigawatt but perhaps it should be substantially bigger, so older inefficient coal-fired stations can be taken off line. Sure, there will initially be a huge outcry from those people who are paranoid about nuclear power but tens of millions of people in the UK, Europe, Japan and the USA have managed to live happily near nuclear power stations for decades so why should we be any different? But has any Australian government got the gumption to do it? Leo Simpson ISSN 1030-2662 * Recommended and maximum price only. 2  Silicon Chip siliconchip.com.au Innovative • Unique • Interesting • Hard to find products PCI-X Serial Card Add two RS232 ports to any system with low voltage 32 or 64bit PCI slots. Cat 2870-7 $149 A dual band GSM & GPRS modem that is capable of transmitting data, short messages (SMS) & fax messages. Cat 10175-7 $579 Cordless Pen Mouse Ideal for use in confined areas Never reach behind your PC again! where a normal This 5.25 bay has USB 2.0 ports, Firewire, mouse cannot Power out, Audio In/Out and a 6 in 1 be used. Also memory card reader. ideal for use Cat 6765-7 $129 with a notebook/laptop. Cat 9287-7 $107 RAID Server Wireless VGA Receiver Using an existing wireless network and the software provided, the user can duplicate and transmit their display to a projector or plasma screen etc. Perfect for schools, boardrooms, lecture theatres etc. Cat 3582-7 $679 VGA Splitter/Extender This programmer connects to the LPT port and has a 32 pin ZIF socket. It will program from 16k to 8M. Cat 3159-7 $479 RFID Controller 4 Camera Inputs Ideal for home/office/shop security, users can setup their own security system with easy installation. It is the cost-effective solution to replace VCR tape recorders. Cat 3575-7 $179 USB to IDE Adapter with Power DVI Booster/Extender PDA Keyboard Adapter Use a full size keyboard on your PDA & your PC. Simply flick a switch & this Ir adapter changes between the two. Cat 9229-7 $69 FireWire 800 Card This PCI card supports Split VGA and extend the both FireWire A and the second output to a max- new B with speeds up to imum of 80m. 800Mbps. Cat 3070-7 $199 Cat 2997-7 $99 Eliminate the video degradation that occurs beyond 7.5m of DVI cable. The DVI Booster requires no extra power supply, additional wiring or sender and receiver system. Supports resolutions up to 1080p or 1920x1920 up to 30mtrs in distance. Cat 3587-7 $369 12v ATX Power Supply Powers a standard ATX PC from a 12v source. Perfect for putting a PC in cars or boats etc. Cat 8551-7 $289 LCD Monitor Arm Holds up to a 17" LCD screen. Uses standard VESA mounts and can be mounted on a wall or desk. Cat 4666-7 $79 RS232 to RS485 Firewire Hub/Repeater Convert RS232 to RS485. Runs up to 1200m and works in half or full duplex. Cat IC485S-7 $129 Have all your firewire devices plugged in at once with this 6 port hub. Cat 2847-7 $74 • Normally delivered next day • Not sure what product you require? Call us for friendly advice! USB to Parallel EPROM Programmer USB DVR Surveillance System Easily connect any IDE drives to your PC using a high-speed USB 2.0 port. An external power adapter is included to power drives if necessary. Cat 6857-7 $39 Front Access Bay Great for servers this RAID device takes two IDE drives and mirrors them. If one drive fails it will work from the other until the faulty one is replaced and then rebuild "on the fly" to minimize downtime. Cat 2874-7 $569 What’s New? Allows the user to plug an older parallel printer into a USB port. Cat 2729-7 $46 Serial to Ethernet Suited for security applications this RFID controller Easily web enable your features secure access serial devices. Available via RFID tag or PIN code or both. Can be in 1, 2, 4 & 8 port models. Cat 15141-7 (1 port) attached to a PC for access logging. $259 Cat 1008143-7 $549 ask<at>mgram.com.au 1800 625 777 www.mgram.com.au Data Collector This tiny portable barcode scanner can store up to 1000 barcodes! Cat 9286-7 $399 Receipt Printer A dot-matrix receipt printer. Easy maintenance and low running costs make it ideal. Cat 5849-7 $499 Cordless Skype Phone This cordless phone works with Skype and can be used as a standard phone. Cat 10172-7 $199 Serial over Bluetooth This unique unit will allow a serial connection to become wireless using Blue Tooth. Cat 11920-7 $459 Dealer inquiries welcome siliconchip.com.au PCMCIA IDE Adapter Easily read your old full size ATA flash memory with this front access IDE adapter. Hot swap compatible. Cat 6668-7 $99 Internet Security Router with VPN Server Provide secure connections to your traveling salesmen or wireless users with up to 100 VPN tunnels. Cat 10164-7 $669 1800 625 777 ask<at>mgram.com.au www.mgram.com.au January 2006  3 All prices subject to change without notice. For current pricing visit our website. Pictures are indicative only. SHORE AD/MGRM0106 12v Mini PC This mini barebones PC is based on the VIA Eden 800Mhz processor and motherboard. It can operate on 12v or 240v making it ideal for use in boats or cars. Cat 1167-7 $750 GSM/GPRS Serial Modem MAILBAG Vale Ray Kelly I am sure that the Vintage Radio article on “Ray Kelly and the HRSA” published in the December 2005 issue of SILICON CHIP will have been of much interest to many of your readers. Sadly, Ray Kelly passed away on Saturday November 19th, 2005, some 23 years after he set up the HRSA. He will be greatly missed by the many members that he so willingly assisted over those years. Warwick Woods, President, Historical Radio Society of Aust. BPL will be carefully regulated It was with some concern that I read your editorial on BPL in the November 2005 issue of SILICON CHIP. BPL has evolved over recent years and in its current format it operates in the USA, Europe and Asia within regulated standards. The Australian regulator, ACMA, will ensure that the same standards apply to any deployment of this or any other technology in our country. Otherwise they will simply refuse to license it. Also, it is no longer utilities alone that are involved in BPL. The largest investors in BPL are Google and IBM and Intel has recently taken a leadership role in this technology as well. In addition, I take exception to your claims that the IT organisations, the utilities and the regulators have not thought through the issues that you outline in your editorial or that these utilities would be able, in some way or other, to influence our highly-regarded regulators in Australia and elsewhere. These regulators are independent and are quite capable of making their own decisions on these matters. I am concerned that the tone of your article could generate unnecessary anxiety in the marketplace. There are no plans anywhere in the world that would see nationwide BPL deployment. At best, BPL might take 10% of overall broadband penetration. Its key markets would be in regional deployment and on the edges of cities, where fixed telecommunications networks 4  Silicon Chip are less economically viable. Furthermore, it is quite possible that BPL is an interim technology, bridging the gap between the current inadequate copper-based networks (which are often unable to deliver true broadband services, especially in regional areas) and the Fibre-to-theHome networks of the future. Nevertheless, there will always be areas in Australia where Fibre-to-theHome will not be feasible and both wireless technologies and BPL will have a longer-term role to play in these markets. Is BPL the final broadband solution? Certainly not but it is an excellent technology which at the very least should be considered for delivery of broadband to areas that otherwise would be under-serviced or not serviced at all. I have organised three BPL Summits and I invited the radio amateurs to attend these discussions. In addition, upon my advice, they have also been invited to the various industry demonstrations, seminars and trials. I had hoped the amateurs would take up the invitation to work with the industry to find solutions. Unfortunately, despite several appeals from me, they have declined to do so and their objective continues to be a total shutdown of BPL in Australia. My argument is that even if BPL were to achieve a 10% penetration, it would take several years to reach that level, during which time there would be ongoing opportunities for fine tuning, reviews and other chances to get it right. Whatever happens, the possible (still not certain) interference to radio amateurs would always be limited, while the benefits to regional BPL broadband users would be enormous. For example, perhaps 1000 amateurs would be affected, while possibly 500,000 regional users would benefit. I have great faith in our regulators to make sure that the appropriate decisions will be made regarding this technology, decisions which will be in the best interests of our country and which will take into account both amateur radio and the regional broadband users. Paul Budde, www.budde.com.au Paul Budde is an independent telecommunications analyst and commentator. He is working with the utilities and the telecoms industry to develop better infrastructure-based broadband competition in Australia. Old computers & printers great for components I like the idea of your “Recycle It” column. At the end of last year, I collected a pile of old (386/486) computers and old printers from our local high-school. Many of the computers were completely unsalvageable and I had no real use for the printers apart from a little laser printer that works like a charm. It took me several weeks but after wrecking the machines I now have an enormous supply of components. Components were lifted from the motherboards using a heat gun. The printers and a range of 5.25-inch floppy drives yielded a collection of stepper motors, gears and wheels. The old AT style keyboards supplied hundreds of little switches, some of which I have used by mounting them on a custom PC board and fitting them back into a shortened keyboard case. The keys were spray-painted and re-labeled. Using a PIC chip and the original coiled cord, I can connect these custom keypads to any circuit that can accept a serial signal. At the moment, that means small robots which are driven using the stepper motors I harvested from the siliconchip.com.au printers. I also have a huge assortment of connectors, piezo and dynamic speakers and ribbon cables which are used on the robots, and logic circuits, most of which of have tested OK. This is not to mention the dozens of LEDs from the computers and printers, as well as PC-board headers that also come in handy. Perhaps you could do an article on what you can get from old (older is better) PCs. Tim Polmear, Moora, WA. Comment: we featured an article on this subject some years ago. As you have found, it is still very worthwhile doing. Concerns about bilge sniffer I have some comments regarding the Bilge Sniffer in the September 2005 issue. It is indicated in the article that the device is intended to be used in an area which may contain a flammable vapour (I accept that using this device might of course prevent a larger problem), however the device has no protection technique employed to itself (or the fans which you are proposing to attach to it) to prevent it being a source of ignition. Such devices would normally have to be certified by a test house (LOSC/ Test Safe in NSW, for example), to some sort of standard. I would be inclined to at least consult and design the device around those standards even though it might not be tested to those standards. (I am talking about AS2380.1 through to AS2380.7). At the very least, I would be inclined to have the hydrocarbon sensor located on a cable in the said potentially flammable atmosphere and have the monitor and its heat-generating voltage regulator and a relay in a known safe area. There are some other items that could be attended to, like making sure the hydrocarbon sensor is protected from excess voltage and current. One really important thing to consider are the fans. Fans are a good source of ignition; they generate static energy and they have brushes, both of which are excellent sources of ignition. It is not acceptable to push air into a cavity either, as this can disperse siliconchip.com.au gas/vapour into other areas, and not just back outside. See also AsNZS3000:2000, page 212. Alex Scott, via email. Comment: your points are valid but it must be said that the best source of ignition in a boat’s bilge is the engine itself. Without some sort of vapour alarm, it is a potential accident waiting to happen. Atmel’s AVR, from JED in Australia JED has designed a range of single board computers and modules as a way of using the AVR without SMT board design How to re-transmit a television signal I would like to comment on your reply to the email from R. F. in the “Ask SILICON CHIP” pages of the November 2005 issue. The email requested information on how to re-transmit a television signal into a valley in which a clear signal cannot be received. One thing you forgot to mention was that the transmitting antenna at the top of the hill should be in the opposite polarity to the receiving antenna at the top of the hill; eg, if the receiving antenna is horizontally polarised, the transmitting antenna should be vertically polarised. This is to prevent interference between the two antennas, and also between the original signal and the receiving antenna at the bottom of the hill. I experimented some years ago when the new UHF translators were being installed on the NSW Central Coast. While receiving vertical and horizontally polarised signals with a Wissi EE 06 antenna and a field strength meter, it appears that for a horizontally polarised signal, there is a 25% attenuation between horizontal and 45 degrees and thence a 75% attenuation between 45 degrees and vertical. The reverse is true for a vertically polarised signal. If memory serves me correctly, the rejection ratio between horizontal and vertical polarisation is in the order of 30dB. Brad Sheargold, Collaroy, NSW. Active TV re-transmission system Regarding re-transmitting TV signals (page 106, November 2005 issue), I have seen it done on UHF and with the antennas separated by at least 200-300 metres out of line-of-site to avoid positive feedback. I must stress The AVR570 module (above) is a way of using an ATmega128 CPU on a user base board without having to lay out the intricate, surface-mounted surrounds of the CPU, and then having to manufacture your board on an SMT robot line. Instead you simply layout a square for four 0.1” spaced socket strips and plug in our pre-tested module. The module has the crystal, resetter, AVR-ISP programming header (and an optional JTAG ICE pad), as well as programming signal switching. For a little extra, we load a DS1305 RTC, crystal and Li battery underneath, which uses SPI and port G. See JED’s www site for a datasheet. AVR573 Single Board Computer This board uses the AVR570 module and adds 20 An./Dig. inputs, 12 FET outputs, LCD/ Kbd, 2xRS232, 1xRS485, 1-Wire, power reg. etc. See www.jedmicro.com.au/avr.htm $330 PC-PROM Programmer This programmer plugs into a PC printer port and reads, writes and edits any 28 or 32-pin PROM. Comes with plug-pack, cable and software. Also available is a multi-PROM UV eraser with timer, and a 32/32 PLCC converter. JED Microprocessors Pty Ltd 173 Boronia Rd, Boronia, Victoria, 3155 Ph. 03 9762 3588, Fax 03 9762 5499 www.jedmicro.com.au January 2006  5 Mailbag: continued the area has only a few houses - none on the “ridge line” - and interference to adjacent properties and services is (and must be) nil. It is an active system, using a UHFonly masthead amplifier (GME is good) of 34dB gain at the four-element phased-array receive antenna with an in-line amplifier of 34dB gain at the re-transmit end. The re-transmit aerial is a Yagi, with about 102 elements for maximum directivity and set so its polarisation is the opposite of the receive aerial. A solar panel can be used so the system runs off 12V and be sure to get the injection point on the correct side of the in-line amp so it powers both amplifiers. Quad-shield lowloss cable helps. The reception at 400 metres from the re-transmit aerial is not perfect but is definitely watchable and could probably be honed for better performance. If someone has a cheap channelspecific translator solution I’d also love to hear about it. They seem to cost in the thousands per channel. I’m sure it shouldn’t cost that much to guarantee frequency stability and a low level of emissions, etc. (Name and address withheld at writer’s request). and no signal whatever just 100 metres away (where the homestead was, of course!). Open wire feedline resolved this situation also. At UHF, this solution may become rather lossy, however “open wire coaxial” feedline (I cannot remember the name of this) may be considered. The feedcones for this are a bit large for VHF but quite practical at UHF. Geoff Syme, via email. Long TV feedlines CO sensor and air-circulation modes A letter in the November issue asked about re-transmitting UHF/VHF signals to a house in a valley. Suggestions offered included two antennas and a masthead amplifier. There are other solutions. Many years ago I saw a similar situation which had been resolved with one antenna at the top of a hill and over 500 metres of telephone line down to the house. I was assured by a local, who was a very competent radio engineer, that it worked extremely well. The 600W pair (two copper wires about 150mm apart with a minimum of insulators and supports) was very low loss and in an electrically quiet location, absorbed little, if any, noise. I have also seen the technique used in a remote area where TV reception was reliable and noise-free in one spot 6  Silicon Chip Restoration of Ferrograph tape recorders Owners of the old 1970s classic Ferrograph tape recorders have mostly discovered that all the rubber rollers and pinch wheels have turned into a gooey mess. Mine went this way recently and I have had the good fortune to locate a company in Tasmania that can recondition such parts using more durable materials. The results are excellent and as most Ferrograph owners would probably read SILICON CHIP, I thought I would pass this information on. The company is Tasroll Engineering Pty Ltd, 373 Brightwater Road, Howden, Tas 7054. Phone (03) 6267 2585. Graham Lil, via email. A couple of items in the December 2005 issue attracted my attention. The letter in Mailbag from Graham Goeby concerning “fresh and recirculate modes” in vehicle ventilation systems is quite correct in saying that the control electronics in modern cars will override recirculate mode to allow fresh air into the cabin, as this prevents the buildup of harmful gases. However, what about the large number of vehicles that do not have electronic control of the fresh/recirc system? My car has air-conditioning but the fresh/recirc system is manual. Now the actuator is electrical over vacuum and the vacuum is supplied via engine manifold vacuum and a small vacuum accumulator which is located inside the left front wheel arch hidden behind the inner arch trim. This ensures very little loss of vacuum when the throttle is opened and the manifold vacuum is lost. When I hit the recirc/fresh switch, a small electric motor operates the diverter flap and changes the fan air intake from either fresh to recirc or visa versa. This motor is also limited by two microswitches which are actuated by a single cam running off the shaft the flap pivots on. Using the CO detector to activate the recirc flap is a very good idea. However, having the air system running on recirc when a high concentration of CO is detected is not such a good idea. Surely, running on fresh air would be better then running on recirc air and keeping the carbon monoxide inside the vehicle. Although, if you were stuck in a traffic jam with the high concentrations of noxious gases present in these situations, having the air system on recirc would seem like a good idea but to be honest, it would only take a small breeze to cut the concentration of gases down dramatically. In my opinion, using the air system on fresh during times of high CO concentrations is vastly better then recirculating the cabin air and only adding to the gases contained within the cabin. High CO concentrations in the cabin when you are not stuck in traffic is a sign of a defective exhaust system and this needs to be addressed and repaired as quickly as possible, if not for the health of the driver, then for the health of the passengers. In the case of small children, even a moderate concentration of carbon monoxide can have a serious or devastating effect on the development of a small child, especially a baby! Secondly, Russell Verdon’s letter about scavenging parts from old scanners drew my attention as I use an old scanner as a light box. Powering up the tube within the scanner was very simple and virtually every member of my family use this light box for one thing or another. My children use it for tracing, my wife uses it for image checking and viewing slides and I use it when I am tracing circuit tracks on double-sided circuit boards, as it allows me to see siliconchip.com.au both sides of the board and both sets of tracks at the same time. I can also see if all the through-board connections are complete and if all the component lead connection holes are free of debris and blockages. All around, it is a very useful piece of gear. Dave Sargent, Howard, Qld. Comment: we take the view that the carbon monoxide sensor is very sensitive and warns the driver that he/she is driving into unsafe air. In practice, if you can smell traffic fumes while driving, you are inevitably exposed to carbon monoxide, as well as all the other noxious combustion products. We think it is preferable to switch over to recirculation mode immediately CO is detected rather than to continue to unknowingly breathe traffic fumes for quite long periods. In fact, many people cannot smell traffic fumes at all and so they are always at risk. Of course, if carbon monoxide from the vehicle’s own exhaust is leaking into the cabin, then the CO sensor will also detect this. If you have a headache after a long drive in traffic, it is a fair bet that you are suffering from carbon monoxide poisoning. Cruise control is very handy I read the lead article on adaptive cruise controls in the September issue. Cruise controls are very handy – we have one on our Volvo. I had a discussion with a Bentley owner recently who said he would never use his as he was concerned he could have a medical seizure and not have time to brake. He is middle-aged and fit but it made me wonder. Maybe your staff have a view on this? Ian McPherson, via email. Comment: our view is that cruise controls work well, except in heavy traffic, winding roads and on steep hills. If a person is so fearful of having a seizure, he should not be driving at all. Flash point and volatility In the Mailbag pages in the 2005 December issue, the letter on flash point and volatility would appear to be incorrect. Diesel has a flash point above 61.5°C, a vapour pressure of siliconchip.com.au Talk about a generation gap. The new Tektronix AFG3000 Series signal generators vs. the competition. Compact fluoros revisited I thought the accompanying photo may be of some interest. I recently opened a dead compact fluoro out of interest and got quite a surprise. The Active and Neutral leads are marked on the photo and you can clearly see that where they enter the discrete diode bridge rectifier; the track spacing is barely 1mm! Even with a conformal coating, this seems to be stretching things to the limit! Graham Lill, via email. <0.5kPa and an auto-ignition temperature above 250°C. Unleaded petrol has a flash point of less than -40°C, a vapour pressure of 35-90(reid)kPa and an auto-ignition temperature above 250°C. Flash point of a flammable substance is the lowest temperature at which it gives off sufficient vapor to form a flammable mixture with air, so that on application of a flame the vapours will flash, but will not continue to burn. I feel that the letter states that diesel will flash at a lower temperature than petrol which is not the case. If there is such a thing as a safer fuel, it would have to be diesel. A look at the Shell website (www. shell.com) will confirm the above temperatures. Bruce Edgar, Rockhampton, Qld. Comment: In practice, to quote from the Shell website, “Volatility characteristics vary on a monthly basis to provide good cold weather starting in winter and to prevent vapour lock in summer. Consequently, petrol should not be stored for long periods”. c 2005 Tektronix, Inc. All rights reserved. Tektronix products are covered by U.S. and foreign patents, issued and pending. TEKTRONIX and the Tektronix logo are registered trademarks of Tektronix, Inc. *Tektronix MSRP subject to change without notice. Starting from around $2600+GST. * Unlike the subtle advancements offered in arbitrary/function generators of past decades, our powerful and broad line of arbitrary/function generators delivers serious advantages. The large display confirms your settings at a glance. Sine waveforms reach as high as 240 MHz. You get a front-loading USB port, twochannel capability, and a remarkably intuitive GUI. Visit www.tek.com/generation_gap to see the next generation of signal generation. The Next Generation. http://www.tektronix.com/4130 Enabling Innovation Tektronix Authorized Distributor N e w Tek Instruments Pty Ltd Address: 3 Byfield Street, North Ryde NSW 2113 Telephone: (02)9888-0100 Email: info<at>newtekinstruments.com January 2006  7 Holden’s EFIJY Show Car Powered by V8, controlled by PICAXE The Holden EFIJY show car was one of the most popular vehicles on display at the 2005 Sydney International Motor Show. While the stunning looks and technology drew the crowds, few people would have been aware that the majority of the electrical systems in the vehicle were controlled by PICAXE microprocessors. By JEFF BROWN* 8  Silicon Chip siliconchip.com.au H OLDEN INNOVATION IS Holden’s research and development centre and one of its functions is to develop and demonstrate new technologies and concepts. Vehicle design is moving more and more into the virtual world but technology still needs to be demonstrated to allow people to decide if they want this in a future vehicle. Invariably, this requires a demonstration or concept vehicle. The concept vehicle may be based on a current production car and have the new technology integrated into it or in the case of EFIJY, it became a completely new vehicle. With the increasing complexity of today’s vehicle electrical systems and the integration of mechanical and electronic control systems, it can be quite difficult to adapt or modify the base vehicle to accept the new technology, even with the benefit of having detailed information about the vehicle’s architecture. Traditionally, first-tier suppliers provide the components and in some cases the technology used in a given subsystem. Typical development of a component for production involves a number of charges from the supplier; including design and development charges, tooling charges and, of course, piece cost. When a prototype is produced, the supplier incurs many of the same costs. It costs almost the same to write software for a one-off prototype as a production system. In the case of the production system, the software may be more complex to increase the robustness of the code but most of the requirements will be the same. A similar issue occurs with hardware. In the case of PC boards, design work still needs to be done, again perhaps not to the same extent as production, but still a significant percentage of the work. This all leads to significant expense to produce a single working prototype. A simple change to add a customer feature may result in charges of $5$10,000. A more complex system can see the cost escalate to $250,000 to demonstrate a new technology. Therefore, significant budgets are required. By developing a low-cost prototyping system in-house, Holden is able to investigate and demonstrate new systems at much lower costs and ensure any intellectual property remains with Holden. Why PICAXE? LCD panels are used for the large instrument panel screen and for the central touch-screen display. siliconchip.com.au Many of the engineers at Holden are readers of SILICON CHIP magazine and recent articles about the PICAXE range of microcontrollers sparked some interest due to our previous experience with the Microchip range. The need arose for a relatively simple project and the PICAXE looked like it might be suitable, while giving us the opportunity to evaluate the product. Our initial selection was the 18X processor and in the target application, it proved to be very competent; the simple interface and relatively January 2006  9 screens are LCD panels, each controlled by compact PCs with embedded Windows XP operating systems. The on-screen images for the touch screens were created by Holden’s Design Department specifically for EFIJY and are running in Macromedia Flash. The touch screens interface with Flash and communicate with the outside world via the PC’s serial port. This results in each “button press” on the touch screen being transferred to the subsystem the driver intends to control. A dedicated module based on an Atmel Mega16 programmed in BASCOM handles all serial traffic with the PCs and sends and receives commands from the modules that control most subsystems. A second Atmel micro handles communications with the engine and transmission CAN (Controller Area Network) networks for data such as RPM and vehicle speed for display on the instrument panel and also controls the ignition and start systems. CM4 control module Developed especially for the EFIJY, the CM4 is a general-purpose control module for use in a variety of applications. It uses a PICAXE 40X running at 16MHz and includes a high-current H-Bridge for controlling motors, high-current FET outputs for switching lights, solenoids etc, analog inputs, and digital inputs with jumper selectable pull-ups or pull-downs. simple BASIC language resulted in very fast prototyping of a concept. Holden Innovation has now used the PICAXE 08, 08M, 18A, 18X and the 40X in numerous applications. Over time the complexity of the projects in which we have utilised the PICAXE for has increased and we now base most projects on the 40X running at 16MHz. The most interesting aspect of the PICAXE is the number of users, some of whom do not have an electrical background. We have found that the simple interface and language has been readily adopted by students 10  Silicon Chip and engineers, and even by hardcore programmers. EFIJY electronics With the exception of the engine and transmission control modules, the electronic systems in the EFIJY are unique and are not based on production components. They use a total of 11 microcontrollers: nine PICAXEs and two Atmel AVRs. The most visible systems when sitting in the vehicle are the large instrument panel screen and the central display, revealed when the centre compartment opens. The two touch Holden Innovation developed the CM4 module as a general purpose control module that could be used for a variety of demonstrator applications. It’s called CM4 because it is the fourth in a family of control modules developed by Holden Innovation. The heart of the CM4 is a PICAXE 40X running at 16MHz. This module has a high-current H-bridge with current measurement for controlling motors, high-current FET outputs for switching lights and solenoids, etc, plus analog inputs and digital inputs with jumper-selectable pull-ups or pull-downs. In addition, a resistor network is employed for resistor-encoded switching to further increase the number of available inputs. This is achieved using one of the 40X’s analog inputs and a resistor ladder; by switching points on the ladder to ground, 10 steps at 0.5V per step is achieved. Therefore, the 40X can process 10 different inputs on the one analog input. The power supply is capable of providing 5V for various sensors and the PICAXE has the ability to control and switch its own power supply off for any house-keeping required before a controlled system shutdown. This is very handy for functions that need to be controlled after the ignition has siliconchip.com.au been turned off. The usual PICAXE features such as serial communications, I2C, etc, are also available. PC board design and fabrication of the CM4 was conducted in-house by Holden’s Instrumentation department. EFIJY uses four CM4 modules for the following subsystems. ePark Brake EFIJY is fitted with an electric park brake which offers a number of features, including removing the need for a large and bulky lever. The pushbutton is pressed to apply and pressed to release the parking brake. In the event the parking brake is required as an emergency brake, the rate of brake application limits the vehicle deceleration to 0.3G. Operation of the system is via an actuator operating on a conventional park brake system located within the rear wheels. This actuator is controlled via the H-bridge and uses both positional feedback and current through the H-bridge. This allows the system to be self-adjusting and provides the control algorithm with a measure of load applied. Entry and exit Entry and exit from the vehicle is interesting, since there are no door handles in or outside the vehicle. Pushbutton switches for the doors and boot use the resistor encoded inputs to the CM4 module to control release solenoids. There is also a custom remote control based on a surface-mount version The driver selects the gear by pushing one of the buttons located on the centre console. These buttons use the resistive encoded inputs on one of the CM4 modules, while the actuator (which controls the transmission) is controlled via the H-bridge output. of the PICAXE 08M. This operates on 433MHz and has three pushbuttons that release the doors and boot in a conventional manner. The vehicle responds to the command from the remote and starts a power-up sequence to ensure all systems are ready for operation when the driver enters the vehicle. The third method of entry is via a passive entry system. The operator walks up to the car, holds out his/her hand and the door pops open to meet it. In this mode, the vehicle detects the presence of a valid remote. This is achieved using a multi-axis motion sensor controlling the power supply in the remote. This allows the remote to power up for brief periods. A unique message is then transmitted but only if the remote is moving. This significantly increases battery life – if the remote is in storage or not in use, the power supply to the 08M is off. When this message is received by the CM4, the door proximity sensors are enabled. These use a capacitance type proximity sensor based on the The central display is revealed when the centre compartment opens. It displays touch-screen images (controlled by compact PCs) to control functions such as the radio and the suspension settings. siliconchip.com.au January 2006  11 The headlamps use 20 high-brightness LEDs in the centre, while the outer rings use 36 pairs of white and amber devices (the latter for turn indication). A 6-litre LS2 V8 fitted with a supercharger sits in the engine bay. It develops 480kW of power and 775Nm of torque. velops 480kW of power and 775Nm of torque. You start the engine with the large pushbutton on the left of the instrument cluster. Starting is controlled by one of the Atmel Mega16 microcontrollers, which provides interface to the power control and engine management systems of the vehicle. When a valid remote transmitter is detected within the passenger compartment, the start button flashes to indicate that the engine can be started. Pushing the button for a brief period then starts the engine. To stop the engine, the start button is pushed again. Various interlocks ensure that the engine is not cranked if it is already running. Alternatively, a key can be used to turn on the ignition and the start button used to crank the engine. ePRNDL When a valid remote transmitter is detected inside the passenger compartment, the engine can be started by briefly pressing the large Start button to the left of the steering column. Pressing it again stops the engine. QT110 IC which provides a digital output when an object is detected. In operation, the device continuously adapts to its environment and only reacts to step changes in capacitance. An output from the proximity sensor is generated by the presence of the driver’s hand at a range of approximately 80-100mm from the top rear edge of each door. The combination of a valid remote in range and the driver’s 12  Silicon Chip hand allow the door to be released. In addition, various interlocks in the code determine if door operation is permitted, based on door position, vehicle speed, ignition status, etc. Naturally, the occupants still need to manually close the doors! Starting EFIJY has a 6-litre LS2 V8 engine fitted with a supercharger. It de­ ePRNDL stands for “electronic Park Reverse Neutral Drive Low” – the electronic transmission selector located in the centre console. EFIJY uses a 4-speed GM automatic transmission, the 4L60E, with the cable control replaced by an actuator. The driver selects the gear by pushing one of the buttons located on the centre console. The buttons use the resistive encoded inputs on one of the CM4 modules, while the actuator is controlled via the H-bridge output and utilises positional feedback from both the actuator and the transmission’s internal controls. The CM4 is also responsible for siliconchip.com.au switch illumination, and selected gear position feedback, both to the driver and to other subsystems. Naturally, a number of interlocks are employed to ensure accidental operation is avoided, to prevent damage to the vehicle. Proportional speed control of the actuator is used to ensure fast response as well as accurate selection of the correct gear position Air suspension The car is fitted with integral airbag and damper assemblies and each wheel has an analog suspension height sensor. Compressed air is supplied via an onboard compressor and storage tank. A manifold with eight solenoid valves, four for lift and four for lower, together with the CM4 module, controls the air supply to each airbag to maintain the desired trim height, regardless of load in the vehicle. There are three settings: show, drive and load and the height can be controlled to within approximately 1mm. The CM4 receives the target height request from the central touch screen. Using the EEPROM in the PICAXE, the last requested suspension height is tracked to allow for system power loss. In a show vehicle, there is usually an isolator switch for the vehicle battery. This is turned off when the vehicle is in storage or on display. But because of the non-volatile memory (EEPROM) in the PICAXE, the control module knows what height it should be at when power is reapplied. The software inhibits control of height when the vehicle is moving and includes error detection and reporting. Steering column lock Setting the suspension to the show position requires the front wheels to be centred inside the front wheel arches. If this does not happen, the wheels will make contact with the fenders and result in body damage. This problem was solved using an analog steering angle sensor, similar to the type used for stability control systems. This allowed the CM4 module to determine if the steering wheel was centred and if not, allow the central display to indicate not only the need to centre the wheel but also the direction the wheel needs to be turned. When the wheel is in the correct position, a locking actuator is engaged to prevent the steering wheel being turned when siliconchip.com.au Eight high-brightness red LEDs are used in the stop indicator housing that’s mounted on the boot lid. the car is in the lowered position. The locking actuator is a rack type and requires an H-bridge to drive it to the lock and unlock positions, while integral position switches provide lock status. Again, various interlocks are employed to ensure the steering column is not allowed to lock when the vehicle is in motion. Lighting The headlamps use Osram Ostar LEDs. These consist of a cluster of five 1W LEDs mounted on a single substrate. With four of these clusters per lamp, there is approximately 20W of LED illumination per side. The outer rings contain 36 pairs of LEDs, one white 50mA device and one amber 150mA device per aperture. The tail lamps consist of 32 dual colour LEDs and a single blue 1W Dragon LED. The dual colours provide stop and tail functions by control of the current through the red elements. When a turn signal is required, the amber LEDs are strobed to provide the flash function. A 40X PICAXE running at 4MHz is used in each tail lamp assembly. LED lighting is also used for interior illumination, as well as for switches and warning lamps. Collaboration The electronic systems in EFIJY were the result of a collaboration of several departments within Holden, The tail lamps use 32 dual-colour (red and amber) LEDs to provide the stop and turn indicators. as well as a number of suppliers who contributed components or assemblies to allow EFIJY to be a fully functioning, fully-drivable demonstration of future vehicle technologies. About the author* Jeff Brown is the Technology Leader – Flexible Architecture at Holden Innovation. During his 19 years with Holden, amongst other duties, he has been responsible for powertrain management systems, vehicle networks and electrical SC systems architecture. January 2006  13 We test-drove the low-end AFG3022 model, which is visually identical to the AFG3252 pictured here. It can generate sinewaves at up to 25MHz and pulse/ square/arbitrary waveforms to 12.5MHz. The arbitrary waveform sample rate is 250MS/s, with internal memory space for four 64kbyte waveforms. Tektronix AFG3000 Series Arbitrary/Function Generators Tektronix has just announced a new range of arbitrary/function generators. Dubbed the AFG3000 Series, the line-up includes six models, ranging from a basic single-channel model to dualchannel models with high bandwidths and fast sample rates. All instruments can generate function (sine, ramp, etc), pulse and arbitrary waveforms and are backed by a stable, low-drift (±1ppm per year) timebase. By PETER SMITH At the bottom end of the range, the AFG3021 can generate sinewaves at up to 25MHz and arbitrary/pulse waveforms to 12.5MHz. The arbitrary waveform sample rate is 250MS/s, with the ability to store four 64kb waveforms on-board. The other major difference with this lower-cost model is that it includes a monochrome rather than colour LCD. The AFG3252 dual-channel model tops the range, with 240MHz sinewave generation and a 120MHz arbitrary/ pulse waveform capability. Naturally, it supports a higher sampling rate of 2GS/s and has enough memory for four 128kb waveforms. All models boast a frequency resolu14  Silicon Chip tion of 1mHz (12 digits) and a vertical resolution of 14 bits. Other important features across the series include amplitude, phase and frequency-modulated signal generation, as well as linear/log sweeps and bursts. Also of note is the pulse generator’s independently programmable rise and fall times – a feature previously unavailable at this price range, according to Tektronix. The ability to independently program waveform and frequency settings for each channel on dual-channel models highlights the flexibility of these instruments. Independent channel control has allowed Tek engineers to add other niceties too – like the ability to tweak phase relationship between channels! It all stacks up To capitalise on bench space, these new instruments can be stacked along with Tek’s TDS1000, TDS2000 and TDS3000 series oscilloscopes, thanks to the now familiar “shoe box” form factor. We reported on the latter two series in the July 2001 and July 2002 issues and remain impressed with Tek’s lightweight, portable instrument designs. Unlike the ’scopes, the AFG3000 series don’t include floppy drives. Instead, they feature an up-front USB socket that accepts standard flash siliconchip.com.au memory drives. This obviously makes it very easy to save and exchange waveform suites and instrument set-ups. Other similarities with Tek’s oscilloscopes are immediately apparent. All models feature a large 5.6-inch LCD, which together with the relatively simple front-panel interface and on-screen menus make these models very easy to use. One particularly nice feature is the ability to see a graphical simulation of the generated waveform on-screen, in many cases eliminating the need to monitor the output with a scope. Waveform editing & creation Generating any of the 12 standard waveform shapes is straightforward and can be achieved in seconds with a few keystrokes. However, using the arbitrary waveform generator to create your own wave shapes can be a different matter. With the aid of “soft” keys, the numeric keypad and the rotary dial, it’s possible to define all of the points necessary for creating a new waveform, using the built-in “edit” memory as your workspace. The result can be viewed on-screen, saved in one of the four memory slots and transferred to a USB memory stick for later retrieval. However, this method of creation could be extremely tedious, particularly if the task involves replication of a complex real-world analog signal. The answer is to install Tek’s ArbExpress software on a PC and use that to create all your waveforms. This highly useful application allows you to create and edit waveforms in a variety of ways. For example, you can manually create a waveform using the straightforward point-and-click interface or define it mathematically and have ArbExpress generate a representative plot. This is significantly easier than creating the waveform on the instrument itself. For direct waveform replication though, there’s an even easier way – just acquire or import it from any of Tek’s digital scopes! Alternatively, you can transfer a waveform directly out of MatLab (no conversion is necessary), or import it in CSV format from a variety of sources. What a timesaver! ArbExpress 2.0 software runs on Windows PCs and makes creating your own waveforms as painless as possible. New waveforms can be created manually, defined mathematically or imported from a Tektronix digital ’scope. MatLab users can also bring in their creations without intermediate conversion. instrument USB connection. A second USB connector is located at the rear of the instrument for this purpose. The AFG3000 series can also be controlled remotely via USB, GPIB and LAN interfaces. In fact, ArbExpress includes a rudimentary control interface. Note, however, that the latter two interface types are not present on the lower-cost AFG3021 and AFG3022 models. ArbExpress 2.0 is a standard part of the instrument package and is included on CD-ROM with all models. Bottom line The AFG3000 Series arbitrary/function generators are easy to operate and offer excellent performance for their price. Tektronix claim that for applications requiring signals with sampling rates of 1GS/s or more, the AFG3000 Series can save purchasers up to 75% of the cost when compared to many other high-performance products. The higher bandwidth models in the series will no doubt appeal to designers developing high-performance computing, communications and video equipment. The more basic models will attract users in educational institutions, as well as designers of consumer electronics and medical and automotive systems. The Tektronix AFG3022 costs $3863 (including GST), while the other models that make up the 3000 Series cost from $2546-$12,160. For further information, contact NewTek Instruments Pty Ltd, 3 Byfield St, North Ryde 2113 – phone (02) 9888 0100. Or go to SC www.newtekinstruments.com Right: plug-in USB flash drives allow instant loading and saving of waveform data and set-ups. A second USB slot is also located at the rear of the instrument, for connection to a PC. Networking & remote control Once created, waveforms can be transferred to the instrument via a USB memory stick or uploaded from within ArbExpress using a direct PC-tosiliconchip.com.au January 2006  15 By John Clarke 16  Silicon ilicon Chip hip siliconchip.com.au TENS – Transcutaneous Electrical Features • Battery pow ered Nerve Stimulation – is pain relief • Adjustable voltage level without drugs. Attach electrodes • Adjustable pulse rate • Adjustable near to the painful area and start pulse width • Intermittent or continuous up the TENS unit for a tingling output sensation that can help to reduce pain. The pocket-sized SILICON CHIP TENS unit has adjustable controls that tailor the levels to suit each patient’s requirement and is battery powered. L IVING IN CONSTANT PAIN is a reality for many people and how well they cope with it depends on the degree of pain and the character of the person. While pain relief can be managed in the short term using analgesics, their long-term use can be detrimental to the user’s health. Side effects of prolonged analgesics use include liver and kidney damage and in some cases irritation to the lining of the stomach. Thankfully, in many cases there is an alternative: TENS or Transcutaneous Electrical Nerve Stimulation. In many cases where pain is constant, a medical practitioner or physiotherapist may recommend the use of a TENS unit. These are not a gimmick or a new-age form of treatment. Tests have shown that TENS is an effective and safe way to manage chronic and acute pain with virtually no side effects. Chronic pain conditions that can be alleviated with TENS include, arthritis, lumbago, neck and back pain, post herpetic neuralgia and sciatica. Acute pain conditions such as fractures, muscular pains, post operative pain and tennis elbow can also be managed with a TENS unit. Warning! This TENS unit (or any other similar device) must not be used on a person who has a Heart Pacemaker. Do not connect the electrodes to the body so that there can be a flow of current through the heart. Electrodes must not be placed on the neck, since this can stimulate nerves which control breathing and blood pressure. Do not use the TENS unit for headaches or attach the electrodes to the head. Do not be tempted to run the TENS unit from a mains adaptor, plugpack or power supply. This could be dangerous if a breakdown occurs in the isolating transformer. If you want to reduce the cost of battery replace­ment, we suggest using a 9V NiMH rechargeable battery. siliconchip.com.au January 2006  17 A TENS unit provides electrical stimulation of the painful area using electrodes attached to the skin. It can cause a tingling sensation in the area where the pads are attached. How the TENS reduces pain is unknown. Some suggest that the nerves are stopped from sending signals to the brain and thus the pain is removed. Alternatively, the stimulation could induce the body to produce natural pain relievFig.1: the block ing substances called endorphins. diagram for the TENS unit. The 9V supply Whatever the reason, a TENS unit can from the battery is give pain relief for many people, with stepped up in the minimal side effects. It does not provide a converter comprising cure for the underlying cause of the pain IC1 and T1. This but has the major benefit that the amount provides a DC output adjustable from 12V up to 80V with VR1 providing of pain killing drugs can be substantially the adjustment. The resulting DC voltage is converted to a pulsed signal reduced. using the switching oscillator. Nor is it addictive. Sometimes there can be skin irritation surrounding the electrodes and this can be reduced or alleviated by changDC voltage is converted to a pulsed signal using switching ing the type of electrode. oscillator IC2. Oscillator IC4 is switched into circuit via Note that a TENS unit must not be used if you have a S2 to gate the switching oscillator to give short bursts of heart pacemaker. A TENS unit also should not be used if the pulsed signal. the cause of the pain has not been established or if you Fig.2 shows how the basic step-up converter circuit operare pregnant. When using the TENS unit do not attach ates. It comprises inductor L1 which is charged from the the electrodes anywhere around the front of the neck, and V+ supply through transistor Q1. The charging current is be sure the TENS unit is kept out of reach of children. It shown as I1. When the transistor is switched off, the stored should be treated like any other medicine, by storing it in energy in L1 is dumped via diode D1 into capacitor C1. a childproof cabinet. The actual voltage across C1 depends on the amount of charge in L1 and the load current between Vout and Features the ground supply. We can maintain a constant Vout for SILICON CHIP previously featured a TENS unit in the August a variety of loads by controlling the amount of time Q1 is 1997 issue. This new version uses a very similar circuit but switched on. housed in a much-more-convenient pocket-sized case. Fig.3 shows the circuit of the switching oscillator, comThree small knobs allow adjustment of the overall output prising IC2, Q1 & Q2. This modulates the output voltage voltage, the width of the voltage pulses and the pulse rate. A of the step-up converter and is based on an IR2155 made continuous/intermittent switch selects whether the pulses by International Rectifier Corporation. It is described as a are provided as a continuous stream or in short bursts. To high-side self-oscillating power Mosfet gate driver. the left of that is a power switch and a LED to indicate when Resistor R1 and capacitor C1 at pins 2 & 3 of IC2 set the the unit is on. Two electrodes connect to the TENS unit via rate at which Mosfets Q1 and Q2 are alternately turned on a lead that plugs into a socket at the top end of the box. The and off. There is a dead time of 1.2ms between each device electrodes are attached to the skin adjacent to the painful switching off and the other switching on. This prevents the area and the controls are adjusted until the tingling effect becomes just a little uncomfortable. The tingling sensation will tend to decrease over the period of treatment and so the controls will need to be further increased as time goes by. The typical treatment period is about 20 minutes. Generally, the continuous setting is selected but for long treatment periods, the intermittent mode can be used. This mode helps to overcome the effect where the patient becomes accustomed to the stimulation. The intermittent mode allows a higher voltage and a faster rate to be selected compared to the continuous mode. Thus the stimulation is greater in short bursts and because there is a break in between pulses, the patient does not adapt too readily to the higher levels. Block diagram The block diagram for the TENS unit is shown in Fig.1. The 9V battery supply is stepped up by the converter comprising IC1 and T1. This provides a DC output from 12V to 80V, with VR1 providing the adjustment. The resulting 18  Silicon Chip This shows the pulse train signal at the electrodes. Here the voltage is set at 80V and the frequency at 108Hz. siliconchip.com.au Fig.2: how the basic step-up converter circuit works. Inductor L1 is charged via transistor Q1 from the V+ supply. When the transistor is switched off, the stored energy in L1 is dumped through diode D1 into capacitor C1. Fig.3: the circuit configura­tion of the switching oscillator. This modulates the output voltage of the step-up converter. D2 and C2 constitute a diode pump to boost the supply voltage to correctly switch Q1. supply from being short circuited at the switchover period when one Mosfet turns off and the other turns on. The full circuit for the TENS unit is shown in Fig.4. Power from the 9V battery comes via switch S1 and diode D6. D6 is included for reverse polarity protection but because we are running from batteries, we have specified a Schottky diode to minimise voltage losses. IC1 is the switchmode controller. It has a switching transistor at pin 1 and a feedback input at pin 5. Its frequency of oscillation is set by the 2.2nF capacitor at pin 3. The peak current through the primary winding of T1 is limited by the 0.22W resistor between pins 6 and 7 of IC1. In operation, the current through the primary winding of T1 is switched off when the voltage drop across the 0.22W resistor exceeds about 300mV. Switching off the current through T1 causes voltage to be induced into T1’s secondary when the primary field collapses. This charges two 470nF capacitors via diode D1. Voltage feedback from the 150kW resistor, VR1 and VR2 into pin 5 maintains the voltage at the desired setting up to 80V. The circuit uses a transformer instead of a step-up inductor, as depicted in Fig.2. This is included to prevent high voltages occurring at pin 1 of IC1, where the maximum allowable voltage is 40V. Since we want up to 80V, the 2.59:1 step-up ratio between primary and secondary of T1 will ensure that the pin 1 voltage will be less than Here are the pulses shown with a faster timebase. It shows the width of each pulse at about 320ms. Finally, this is the intermittent pulse output showing the bursts of pulses at about 1.2Hz. Diode pump Note that the supply voltage for IC2 is around 10V while the voltage to be switched can be up to 80V. The gate voltage for Q1 must be raised above its drain by several volts in order for it to be able to switch the 80V supply. This extra voltage is derived using a diode pump consisting of diode D2 and capacitor C2. Initially, the supply to pin 1 of IC2 is set at about 10V by an external zener diode. When Mosfet Q2 is switched on, capacitor C2 charges to the 10V supply via D2. When Q2 is turned off, pin 7 is connected internally to pin 8 to switch on Q1. Q1 then pulls pin 6 up to Vsupply and pin 8 is level-shifted to Vsupply plus the voltage across C2. So in a few switching cycles, the circuit automatically shifts pin 8 and thereby the gate voltage to Mosfet Q1, to whatever the driving voltage needs to be. Circuit details siliconchip.com.au January 2006  19 Fig.4: the complete Pocket TENS circuit diagram. Its operation can be most easily understood by comparing it with the block diagram of Fig.1. 40V. The primary winding can be used to provide a 10V supply for IC2 and IC4. This supply is derived in two steps. First, diode D3 charges the associated 4.7mF capacitor. Voltage across it is limited to +39V by zener diode ZD1. Diode D3 also clamps the maximum voltage at pin 1 of IC1 to one diode drop above 39V. IC2’s power is then derived via an LM334Z constant current source, IC3. The 27W resistor between the R and V- pins of IC3 sets the constant current to about 2mA. The current source supplies a 10V zener diode (ZD2) that regulates the supply voltage to 10V. This supply also powers IC4. Note that we need to derive the supply for IC2 in this way because the 9V directly Specifications from the battery is just not enough for Output Voltage........... Adjustable from 12V to 80V satisfactory operation. This is because IC2 has an internal voltage shutdown that Pulse Rate................. Adjustable from 4.6Hz to 410Hz operates at below 8.4V. IC2 will therefore Pulse Width................ Adjustable from between 70 and 320ms not operate when its supply drops to this Intermittent................. 24% duty cycle at 1.2Hz level.          (220ms pulse burst with an 800ms off period) If we were powering this IC directly Battery Drain.............. Typically less than 20mA from batteries, we would need at least           (31mA at 80V output, 19mA at 50V output) 8.6V from the battery to ensure operation Battery....................... 9V Alkaline (or a 9V NIMH rechargeable) if we include the drop across D6. This would give an extremely short Battery Voltage........... 7.2V minimum for a 12V to 80V output range, operation time with a 9V battery. By             4V minimum for a 22V to 80V output range. contrast using the power supply system 20  Silicon Chip siliconchip.com.au Fig.5: the PC board component overlay with same-size photo at right. Note how the 10mF capacitor (between VR3 and IC2) is laid parallel to the PC board. described above, the battery can be used down to at least 7.2V and in most cases down to 4V. Q1 and Q2 are 200V Mosfets and are used to switch the high voltage on and off to produce the requisite output pulses on the electrodes. Q1 & Q2 constitute a totem pole output stage with Q1 turning on to charge the 470nF output capacitor via the series 150W resistor and the load resistance (which in this case is the patient). Each time Q1 turns off, Q2 turn turns on to discharge the capacitor via the series 150W resistor. The amount of time Q1 is switched on determines the pulse width of the voltage output. Q2’s on time controls the pulse rate (ie, the frequency). In more detail, Q2 is switched on for the time set by the 330nF capacitor at pin 3 and the resistance between pins 3 and 2 of IC2. VR3 adjusts this time between about 0.22 and 2.4ms, giving a pulse rate between 4.6Hz and 410Hz. Q1 is switched on for the time duration set by potentiometer VR4, the series 12W resistor and diode D4. The pulse width ranges between 70ms and 320ms. Intermittent mode IC4 is a 7555 CMOS timer configured to provide the in- Fig. 6: winding details for the toroidal transformer, T1. siliconchip.com.au termittent mode. It operates as a free running oscillator. The output at pin 3 is used to charge the 10mF capacitor at pins 2 & 6 via the 47kW resistor and diode D5 and discharge it via the parallel 100kW resistor. This gives a pulse waveform at pin 3 with an uneven duty cycle, with the pulses being high for 0.22s and low for 0.7 seconds. We don’t use the pin 3 output to modulate IC2. Instead, we use the capacitor discharge output at pin 7. This pin 7 output is an open drain Mosfet which is open circuit when pin 3 is high and conducts signal to ground when pin 3 is low. Each time pin 7 of IC4 pulls low, it discharges the 330nF capacitor at pin 3 of IC2 to stop IC2 from oscillating. This prevents any output to the electrodes and provides an intermittent modulation for the electrode output. Construction The SILICON CHIP TENS unit is built onto a PC board coded 11101061 and measuring 85 x 64mm. It is housed in a plastic case measuring 134 x 69 x 23mm. An adhesive plastic label measuring 49 x 113mm is fitted to the lid of the case. Fig. 7: here’s how to wire the electrode leads, using a 2.5mm long shaft DC plug. The leads can be as long as you like, within reason! January 2006  21 Three trimpots are used as controls instead of potentiometers. They provide us with suitable sized components for the small box. 10mm long spindles are inserted into each trimpot to allow adjustment and these protrude through the front panel of the box. Note that the trimpots specified are long-life components suitable for potentiometer use. All components must be placed so that they sit no more than 13mm above the top surface of the PC board. This means that one electrolytic capacitor Parts List – Pocket TENS Unit 1 PC board coded 11101061, 85 x 64mm 1 plastic case, 134 x 69 x 23mm, with 9V battery compartment (DSE Cat ZA-4731) 1 front panel label, 49 x 113mm 1 TENS electrode set (available from pharmacy suppliers and chemists) 1 Neosid ferrite core, 25 x 15 x 10mm (28-780-36P) 1 9V battery clip lead 1 9V alkaline or 9V NiMH rechargeable battery 1 2.5mm PC-mount DC socket 1 2.5mm DC line plug with long shaft 2 2mm plugs for electrodes 1 1m length of figure-8 light duty flexible cable 2 PC-mount SPDT slider switches (S1,S2) 2 DIP-8 low-cost IC sockets to mount switches 3 15mm spindles for VR1, VR3 & VR4 2 200mm long cable ties 2 PC stakes 4 M3 x 6mm screws 1 2m length of 0.5mm enamelled copper wire 1 12mm length of 9.5mm heatshrink tubing 1 15mm length of 3.3mm heatshrink tubing Semiconductors 1 MC34063 DC-DC converter (IC1) 1 IR2155 Mosfet driver (IC2) 1 LM334Z current source (IC3) 1 7555 CMOS timer (IC4) 2 STP6N60E N-channel Mosfets or similar rated at 200V 1A minimum (Q1,Q2) 1 39V 1W zener diode (ZD1) 1 10V 1W zener diode (ZD2) 2 1N4936, UF4004 fast diodes (D1,D2) 3 1N4148 switching diodes (D3-D5) 1 1N5819 Schottky 1A diode (D6) Capacitors 1 100mF 16V PC electrolytic 3 10mF 16V PC electrolytic 1 4.7mF 63V PC electrolytic 3 470nF MKT polyester 1 330nF MKT polyester 1 100nF MKT polyester 1 2.2nF MKT polyester Resistors (0.25W 1%) 1 150kW 1 100kW 1 47kW 1 10kW 1 2.2kW 1 1kW 1 180W 1 150W 1 27W 1 12W 1 0.22W 5W 2 1MW horizontal trimpot (Piher PT10MV10 105A 202E) (VR1,VR3) (OR 2MW for VR3 for a 2.3Hz minimum rate) (Farnell 868-437 for 1MW) 1 100kW multi-turn top adjust trimpot (VR2) 1 1kW horizontal trimpot (Piher PT10MV10 102A 202E) (VR4) (Farnell 868-383) 22  Silicon Chip is mounted on its side and the two Mosfets (Q1 & Q2) are bent over at right angles. In contrast, the switches must be raised above the PC board using cut down IC sockets, to make them accessible when the lid is fitted to the case. Begin construction by checking the PC board for any defects such as shorted tracks or breaks in the copper pattern. Repair these before assembly. The component overlay diagram is shown in Fig.5. Insert the two PC stakes at the battery wiring points first. Next, insert and solder in all the resistors. You can use the accompanying resistor colour code table when selecting the resistors and it is also a good idea to check each value using a digital multimeter before it is installed. Next, install the six diodes and two zener diodes, making sure that the correct diodes are used in each place. Each of the ICs is an 8-pin DIP device, so don’t mix them up when installing them. The capacitors can be mounted next. The MKT polyester types have codes stamped on them to indicate their value and we have provided a table of the different codes. The electrolytic types must be oriented as shown and the 10mF capacitor adjacent to VR3 must be laid on its side. The switches are mounted on cutdown IC sockets. The sockets are made by cutting up IC sockets into strips of five contacts using a sharp utility knife. The two unused pin contacts for each switch socket are removed. Insert and solder the sockets in place and then insert the switches. The trimpots are soldered next, taking care to place the correct value of trimpot in each position. The 10mm spindles are inserted with the pointer facing the centre pin of the trimpot. Check that the rotation to the left and right is correct, with the pointer rotation the same from each side of centre. Remove and readjust the spindle orientation if this is incorrect. As mentioned earlier, the leads Capacitor Codes Value 470nF 330nF 100nF 2.2nF mF Code 0.47mF 0.33mF 0.1mF .0022mF IEC Code EIA Code 470n 474 330n 334 100n 104 2n2 222 siliconchip.com.au The PC board is a nice neat fit inside the pocket-sized case. It contains its own 9V battery – don’t be tempted to run this from a mains adaptor! of Q1 and Q2 have their leads bent over at right angles as shown in the photograph above. They must lie over the adjacent components so that their bodies are no higher than 13mm above the PC board. Fig.6 shows the winding details for the toroidal transformer T1. It is wound with 0.5mm enamelled copper wire. It is important to get the winding direction and number of turns correct. Start by winding on 44 turns for the secondary in the direction shown. The primary is also wound in the direction shown, with 17 turns. Strip the enamel insulation from the wire ends before soldering them to the PC pads. Then secure the finished toroid to the PC board with a cable tie, as shown. Indicator LED1 is mounted with the top of its lens 15mm above the PC board. Make sure its orientation is correct. Attach the PC board to the base of the case with the four M3 screws directly into the integral standoffs in the case. The front panel label can be attached to the lid of the case and the holes drilled and filed to shape for the two slide switches, the 3mm LED and the three trimpot spindles. Resistor Colour Codes o o o o o o o o o o No. 1 1 1 1 1 1 1 1 1 1 Value 150kW 100kW 47kW 10kW 2.2kW 1kW 180W 150W 27W 12W siliconchip.com.au 4-band Code (1%) brown green yellow brown brown black yellow brown yellow violet orange brown brown black orange brown red red red brown brown black red brown brown grey brown brown brown green brown brown red violet black brown brown red black brown 5-band Code (1%) brown green black orange brown brown black black orange brown yellow violet black red brown brown black black red brown red red black brown brown brown black black brown brown brown grey black black brown brown green black black brown red violet black gold brown brown red black gold brown Drill a hole in the end panel for the output socket to allow access for the DC plug. The battery clip wires are fed through from the battery compartment side via the holes in the box. Secure these wires with a cable tie and solder them to the PC stakes, then use heatshrink tubing (the small diameter length cut in half) to cover the PC stakes and wire. Note that Mosfet Q2 also has its tab covered in heatshrink tubing to avoid its tab shorting to the tab of Q1. Testing Fit the battery and plug in the DC socket with the backing piece removed. Connect a multimeter (set to the 200V DC range) between the outside terminal of the plug (-) and the tab of Q1. Switch on power and check that LED1 lights and that there is a voltage reading. Set the voltage pot VR1 fully clockwise and adjust trimpot VR2 for a reading of +80V. If you are not able to obtain the correct voltage, check that the transformer is wound correctly. In particular, check the winding directions for each winding. Check that the voltage at pin 1 of January 2006  23 IC2 is around +10V DC. Set the pulse width pot VR4 fully clockwise and select the continuous mode. Connect your multimeter set for AC volts across the DC socket terminals. You should measure about +18V AC, indicating that switching is taking place. Note that this is only an indication of the output, as some multimeters may give different readings. The readings should alter with different control settings. With intermittent mode selected, you should see the voltage changing from 0V to a higher reading. If you have access to an oscilloscope, the output pulses can be observed to verify that the pulse width and frequency are to specification. Using TENS Make up electrode leads using the 2.5mm DC plug and the two 2mm plugs. Now connect to the electrodes. The electrode sockets may need to be slightly crimped with pliers to close up the socket hole. This will hold the 2mm plugs more securely. The electrodes are usually supplied with an adhesive back that allows them to be easily attached to the skin. If the adhesive dries out, a smear of personal lubricant will be helpful. The electrodes can then be attached to the skin using any of the variety of tapes or bandages used to secure wound dressings. Attach the electrodes in position on either side of the pain source. A useful chart showing typical TENS pad locations may be found at www.vitalityweb.com/backstore/tensplacement.htm Before switching on the TENS unit be sure that the output voltage is turned down to the minimum. Wind the voltage up until a tingling sensation can be felt and adjust the pulse rate and width for the desired effect. The voltage will need to be wound up during the period of treatment to compensate for the body’s adaptation to the stimulation. The intermittent selection is used where the treatment period is long (normal treatment sessions are typically for 20 minutes) or where the user finds the continuous effect to be waning. It is possible that the TENS pads will irritate the skin, not (usually) so much from the TENS itself but the adhesive used on the pads. If so, we 24  Silicon Chip TENS pads are normally self-adhesive and, with care, can be used many times. When not in use they should be stuck onto the backing sheet they came with. The most usual position for pads is each side of a painful area, bearing in mind the warnings published on page 17. suggest trying a different brand or type of pad. There is a wealth of information on the internet about TENs units and their use. Like any treatment regimen, we sug- gest you ask your General Practitioner for advice before commencing treatment with the TENS unit. Remember, TENS does not treat any underlying condition; it merely masks the pain SC and makes it more bearable. Figs 8 & 9: same-size artwork for the PC board and front panel. A photocopy of the front panel can also be used as a drilling template for the case. siliconchip.com.au Announcing the Inaugural 2006 SILICON CHIP Excellence in Education Technology Awards SILICON CHIP magazine aims to promote the education, development and application of electronic technology in all fields throughout Australia. As part of that aim, we are announcing the SILICON CHIP Excellence in Education Technology awards, with a prize pool of $10,000. The inaugural awards will be announced in the December 2006 issue of SILICON CHIP. Separate awards will be made to students of secondary schools throughout Australia and to students of universities and TAFE colleges throughout Australia. The secondary school awards will have three categories: (a) Best final year assignment of an individual student involving electronics technology (b) An award to the school sponsoring the winning individual student (c) Best school project involving electronics technology The university and TAFE college awards will have three categories: (a) Best project from a student as part completion of a degree, diploma or certificate in electronics or a related field (ie, mechatronics) (b) Best research project from a post-graduate student working in an area of applied electronics (c) An award to the university faculty or school sponsoring the best research project. Entries and judging The awards will be judged by the editorial staff of SILICON CHIP, convened as a judges panel. The decisions of the judges will be final. Entries for the 2006 awards will open 1st May 2006, with final submissions to be made by September 30th, 2006. All submissions will be confidential, until the winners are announced, in the December 2006 issue of SILICON CHIP. Each award will take the form of a cash prize and a commemorative plaque. All enquiries about these awards should be directed to the editor via email to: awards<at>siliconchip.com.au siliconchip.com.au January 2006  25 SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: dicksmith.com.au A F lea - P o w er The A M Broad Little Jim AM Transmitter Dubbed “Little Jim”, this low-power “baby” AM radio transmitter has a range of just a few metres, to keep it nice and legal. It’s ideal for sending the output of your MP3 player or personal CD player to your car radio, or for feeding recordings of vintage radio shows to vintage radios, so they sound really authentic. By JIM ROWE W HY WOULD YOU want a broadcast band AM transmitter with a power output so low that it can only be received inside a radius of about four metres? Well, let’s say you’ve just finished building a replica of a classic 1940s’ era AM radio, which you’re entering into a club competition. Wouldn’t it be great if you could tune it into an “authentic” old time radio 32  Silicon Chip program, to recreate the way it might have sounded back then? With this little transmitter you’ll be able to do just that, by rebroadcasting historic radio programs like those available on CD from Screensound Australia (see sidebar). Alternatively, you might want to play the music from your personal MP3 or CD player through your car radio when you’re driving to and from work – but the radio lacks direct audio inputs. With this little transmitter, that’s no problem – although you will need to modify it slightly so that it runs from the 12V car battery. In short, the whole idea of this project is allow any line-level audio signal to modulate an RF carrier in the AM broadcast band, so that it can be siliconchip.com.au Un i t F or c as t Ban d Fig.1: this is the block diagram for “Little Jim”. A tunable RF oscillator sets the carrier frequency and this is them amplitude-modulated by the audio signal. The modulator’s output is then amplified and fed to an antenna. transmitter uses just a handful of parts (including two transistors and the modulator IC) and fits inside a standard UB3 sized plastic jiffy box. It’s also low in cost and easy to build, as all the parts fit on a small PC board. And it’s run from either a plugpack power supply or a 12V battery, so safety isn’t a problem, even for beginners. How it works played through a nearby conventional AM radio. The carrier frequency of the transmitter can be tuned to virtually anywhere in the lower half of the broadcast band – ie, from 550kHz to about 980kHz. This allows you to choose a frequency that’s away from any of the broadcasting stations operating in your area, to ensure interference-free reception. The audio quality from the transmitter’s signal is very close to that of the program material you feed into it, because it uses a special balanced modulator IC. There’s also a modulation level control, so you can easily adjust the transmitter for the best balance between audio volume and minimum distortion. But the best part is that the whole siliconchip.com.au Although it’s extremely simple and designed for very low output power, “Little Jim” uses exactly the same “building blocks” as a full-sized AM radio transmitter. Fig.1 shows the details – it consists of an RF (radio frequency) oscillator, a modulator and an RF output amplifier or “buffer”. The job of the RF oscillator is to generate a continuous sinewave signal of constant amplitude and with a frequency in the range from 5501650kHz – ie, in the AM broadcast band. This provides the transmitter’s “RF carrier”, which is the frequency you tune to with your AM radio to receive the signal. In most full-size AM transmitters, the RF oscillator uses a quartz crystal and is fixed in frequency, so the station concerned is always found at exactly the same place on your radio’s tuning dial. However, in this case, the oscillator is tunable over the range from 550kHz to about 980kHz, so you can set the transmitter’s frequency to a part of the band that’s currently unoccupied in your area, for clear reception. The signal produced by the RF oscillator is fed into the modulator, which is the “heart” of the transmitter. As shown in Fig.1, this also receives the audio signals from your MP3 or CD player. In this case, the stereo signals from the player are fed in via a simple mixing circuit, to convert the signals into mono. The resulting mono signal is then fed to the modulator via a modulation (volume) control, which sets the modulation level. In operation, the modulator uses the audio signal to vary the amplitude of the RF signal (ie, it varies the amplitude of the carrier). When the audio signal swings positive, the amplitude Keeping It Legal The AM transmitter described in this article has very low RF power output (a tiny fraction of a watt) and is designed to have a range of no more than about four metres. Do not attempt to modify the circuit with the aim of increasing its power output or to increase its range by feeding its output into a much larger antenna, because this would greatly increase the risk of interfering with the reception of licensed broadcasting stations. It would also make you liable to prosecution by the broadcasting and spectrum management authorities and probable confiscation of your equipment as well. January 2006  33 Fig.2: the final circuit uses a Colpitts oscillator based on transistor Q1 to generate the carrier frequency which is then modulated by the audio signal fed into pin 1 of IC1 (MC1496). The modulated RF signal is then amplified by common-emitter amplifier stage Q2 and fed to the antenna. Potentiometer VR2 sets the modulation depth. of the carrier is increased and when it swings negative, the carrier’s amplitude is reduced. As a result the RF output signal from the modulator is varied up and down in amplitude, directly in step with the audio signals. In other words, the RF carrier is “amplitude modulated”. The waveforms in Fig.1 show the basic idea. Amplitude modulation or “AM” is just one way of using an RF signal to carry audio or other kinds of information from one place to another. Another approach is to frequency modulate the carrier and this transmission standard is called “FM” (for frequency modulation). The amplitude-modulated RF output from the modulator is very weak, so before it can be fed to our transmitting antenna (which is just a short length of wire) we have to increase its level slightly by passing it through the third building block: the RF buffer amplifier. This stage amplifies the modulated RF signal to 34  Silicon Chip a level that’s just high enough to cause weak radio signals to be radiated from the antenna. Circuit details OK, so that’s the basic operational details of the transmitter. Now let’s take a look at the circuit diagram – see Fig.2 The RF oscillator (which generates the carrier signal) is a simple Colpitts circuit, based on transistor Q1. This uses the primary winding of RF transformer T1 as the inductive arm of its resonant circuit, along with fixed 470pF and 100pF capacitors and a miniature tuning capacitor (VC1). T1 is a miniature local oscillator coil from a low-cost AM receiver coil kit. The output of the oscillator is taken from the secondary winding of T1. This is then fed through a 4.7nF DC blocking capacitor and a series 10kW resistor to one of the two carrier inputs (pin 10) of IC1, an MC1496 balanced modulator specially designed for this kind of use. The second carrier input of IC1 is pin 8 and is tied to ground potential as far as RF signals are concerned using a 10nF capacitor. However, the IC needs both its carrier inputs held at a DC bias level of about +6V and that’s the purpose of the voltage divider network involving the 1.5kW, 560W and 1kW resistors between +12V and ground. The 1kW resistor between pins 8 and 10 ensures that both carrier inputs are biased at the +6V level. It also forms a voltage divider with the 10kW resistor from T1, to reduce the unmodulated carrier level at IC1’s inputs to below 60mV RMS – the maximum level which can be applied to its carrier inputs for undistorted output. IC1’s audio modulating signal inputs are at pins 1 and 4 and these have to be biased lower than the carrier inputs, to about +4V DC. This voltage is provided across the lowest 1kW resistor in the main bias divider and fed to the two audio inputs (pins 1 & 4) via two 1.5kW resistors. In addition, siliconchip.com.au the audio inputs are connected via 10kW resistors to trimpot VR1, which allows fine adjustment of their relative bias – and hence the modulator IC’s operation. The stereo audio input signal is fed into the unit via jack socket CON2 and mixed together via two 10kW resistors to form a mono signal. This signal is then fed to modulation depth control VR2. In addition, two 10kW resistors have been connected between the audio inputs of CON2 and ground. These are used to provide suitable loads for your CD or MP3 player line/headphone outputs. If your particular player needs loads of less than 10kW, these two resistors can be reduced in value. As shown in Fig.2, the modulating signal from VR2 is fed to just one of the modulator’s audio input pins – in this case, to pin 1 via a 4.7mF DC blocking capacitor. The second input (pin 4) is tied to ground via a 100mF capacitor, so the full audio (AC) voltage from VR2 is effectively applied between the two input pins. The 1kW resistor connected between pins 2 & 3 of IC1 is used to set the internal gain of the modulator, while the 10kW resistor from pin 5 to +12V sets the IC’s internal bias and operating current level. or four metres, despite its very low RF power output. Modulated carrier outputs Construction The modulated carrier outputs from IC1 appear at pins 6 & 12, which are both connected to the +12V rail via 3.3kW load resistors. In this circuit, we only use the output from pin 12 and this drives the base of RF amplifier transistor Q2 via a 12kW resistor. Transistor Q2 is connected as a simple common-emitter amplifier stage, with an unbypassed emitter resistor to ensure low gain and stability. Its amplified output is developed across the collector load formed by L1, a broadcast-band antenna coil wound on a very small ferrite rod. As well as forming Q2’s collector load, L1 actually forms part of the transmitter’s antenna, because the ferrite rod inevitably radiates some RF energy. However, its very small size makes it a rather poor radiator, so an external wire antenna (about two metres long) is also connected to Q2’s collector via a 10nF coupling capacitor. This “dual antenna” system gives the transmitter a range of about three Construction is easy, with all the parts mounted on a small PC board measuring 122 x 57.5mm. This board has cutouts in each corner, so it can fit snugly inside a standard UB3 size jiffy box. Note that there are actually two slightly different versions of the PC board, to suit the two different 3.5mm stereo jacks sold by kit suppliers. The board coded 06101061 suits the jack sold by Dick Smith Electronics, while the version coded 06101062 suits the jack sold by both Jaycar Electronics and Altronics. There are no other differences – apart from the provisions for mounting the different 3.5mm jacks (CON2), both board versions are identical. Fig.3 shows the assembly details. Begin the by fitting the PC board terminal pin for the antenna wire connection, located just to the right of the antenna rod, then fit DC input connector CON1 and the audio input jack CON2. That done, you can install the re- siliconchip.com.au Power supply The circuit is powered from a regulated 12V rail and this is derived from the mains via a 12V DC plugpack supply, diode D1 and 3-terminal regulator REG1. A 12V DC plugpack supply is specified, since these typically deliver 1516V when only lightly loaded. The transmitter circuitry draws less than 40mA in operation, which means that REG1 has quite enough “head room” to provide a well-regulated +12V output. Diode D1 provides reverse polarity protection, to prevent the circuit from damage if the supply is connected the wrong way around. Alternatively, for use in situations where no mains power is available, the transmitter can be powered from a 12V battery (eg, a car battery). This involves removing REG1 and replacing it with a wire link between its input and output connection pads. More about this later. Finally, LED1 is used to provide power-on indication. It’s connected across the 12V supply in series with a 1kW current-limiting resistor. (ie, the current through the LED is 10mA). Par t s Lis t 1 PC board, code 06101061 (DSE version) or 06101062 (Altronics and Jaycar versions), 122 x 57.5mm 1 UB3-size jiffy box (130 x 67 x 44mm) 4 M3 x 10mm tapped spacers 9 M3 x 6mm machine screws, round head 1 M3 hex nut 1 mini RF oscillator coil in can (T1 – red slug) 1 Ferrite rod, 55mm long, with BC band coil (L1) 1 Mini tuning capacitor 60160pF, with disc-type knob and mounting screws (VC1) 1 2.5mm concentric DC socket, PC-mount (CON1) 1 3.5mm stereo jack, PC-mount (CON2) 1 mini control knob (to suit VR2) 2 cable ties, 100mm 1 PC terminal pin, 1mm diameter 1 2m length of insulated hookup wire 1 50kW horizontal trimpot (VR1) 1 50kW log pot, 16mm PC-mount (VR2) Semiconductors 1 MC1496 balanced modulator (IC1) 1 7812 +12V regulator (REG1) 2 PN100 NPN transistor (Q1,Q2) 1 3mm green LED (LED1) 1 1N4004 silicon diode (D1) Capacitors 1 220mF 25V RB electrolytic 1 100mF 16V RB electrolytic 1 22mF 16V RB electrolytic 1 10mF 16V RB electrolytic 1 4.7mF 16V tantalum 2 100nF monolithic 1 10nF metallised polyester 1 4.7nF metallised polyester 2 470pF NPO disc ceramic 1 100pF NPO disc ceramic Resistors (0.25W 1%) 2 15kW 3 1.5kW 1 12kW 4 1kW 8 10kW 1 560W 2 3.3kW 1 470W sistors. These are not polarised, so you can fit them either way around although it’s best to have their colour codes all running in the same direcJanuary 2006  35 The PC board is mounted on the lid of the case using four M3 x 10mm tapped spacers and eight M3 x 6mm machine screws. Note how the antenna rod is secured using plastic cable ties. tion to aid checking later on. Table 2 shows the resistor colour codes but you should also check each unit with a digital multimeter before installing it, just to make sure. The non-polarised ceramic, monolithic and metallised polyester capacitors can go in next. Again, these can again go either way around but be sure to fit the correct value in each position. Once they’re in, install the larger polarised capacitors. These include the 4.7mF tantalum unit which goes just below VR2 and the four RB electrolytics. Note that these must all be fitted with the correct polarity, as shown on the layout diagram. The final capacitor to fit is tuning capacitor VC1. This fits on the top of the board, with its spindle stub shaft and three connection tabs passing down through matching holes in the board. The board is then turned over and the capacitor body attached to the board using two of the M2.5 x 4mm screws supplied with it. Don’t lose the third screw, though – you’ll need it later to attach the disc knob to VC1’s spindle. Now solder VC1’s three connection tabs to their board pads. The oscillator coil T1 is next on the list. This is effectively polarised, because there are three connection pins on one side of its base and only two on the other – be sure to orient 36  Silicon Chip it correctly before pushing it all the way down onto the board. There are seven solder connections to make in all – five pin connections plus two for the can lugs. Trimpot VR1 and modulation control pot VR2 can now go in, after which you can fit the semiconductors – diode D1, transistors Q1 and Q2, IC1 and LED1. These parts are all polarised so be sure to install them as shown in Fig.3. LED1 should initially be installed with its body about 20mm above the board (this can be done by sliding a 20mm-wide cardboard spacer between its leads and pushing the LED down onto this spacer). Its leads should then be bent down through 90° at a point about 14mm above the board, so that the LED faces away from the board and will later protrude through a matching hole in the side of the case during final assembly. Mains or battery power If you intend running the transmitter from a mains plugpack, install regulator REG1 in the position indicated. As shown in Fig.3, this is mounted horizontally on the board, with its metal tab secured by an M3 x 6mm machine screw and nut. To do this, first bend its leads down by 90° at a point 6mm from its body, then fit it to the board and secure its tab using the screw and nut. That done, its leads can be soldered to their respec- tive pads. Don’t solder its leads before securing the tab. If you do, the solder joints could fracture due to stress as the screw is tightened. Alternatively, if you intend running the transmitter from a 12V battery, REG1 is left out and a small wire link fitted instead. This link should be fashioned from a short piece of tinned copper wire (or a resistor lead offcut), bent in an inverted-U shape with its centre section just over 5mm long. This is then fitted between the two outer connection lead holes for REG1 and soldered to the pads underneath. Antenna rod & coil The final component to fit to the transmitter board is the antenna rod and coil assembly (L1). This is secured using two small cable ties, each of which loops around under the board through the pairs of 3mm holes provided for this purpose. (Note: do not replace the cable ties with wire or any other metal bands. A metal loop would form a “shorted turn” and this would absorb RF energy and seriously degrade the performance). Unfortunately, making the coil’s connections to the board can be a bit tricky. In most cases, there are four leads and it’s not easy to work out which are the correct two to use – ie, the actual start and finish of the coil. In fact, the only reliable way to identify the start and finish leads is to siliconchip.com.au TUNING Fig.3: install the parts on the PC board as shown here, taking care to keep all component leads as short as possible. Note that board has been designed to accept both 16mm and 24mm pots for VR2 (although a 24mm pot would not allow the board to fit inside the specified UB3 case. check all lead combinations with an ohmmeter and go with the combination that gives the highest reading – typically around 11W. Another little trap is that with many of these coils, the intermediate leads actually consist of two fine gauge insulated wires, twisted tightly and soldered together at their outer ends. This means that if you decide to cut these leads short, they must be bared and soldered together again – otherwise you’ll find that the coil has become an open circuit between start and finish. And of course, the transmitter won’t function very well with L1 open circuit, as this prevents Q2 from drawing current! A word of advice: if you do shorten any of the coil leads, it’s a good idea to check the coil continuity with your multimeter before you solder the start and finish leads to the board. The last step in wiring up the board is to solder the end of a 2-metre length of insulated hookup wire to the “ANT WIRE” terminal pin at the end of the antenna rod. That done, it’s time to fit the tuning “disc knob” to VC1’s shaft and fasten it in place using the remaining M2.5 x 4mm screw. The board assembly is now ready to attach to the box lid (used here as the transmitter’s base). Before doing this, however, you may need to drill and cut the various holes in both the lid and the box itself, if you’re building the project from scratch. The location, size and shape of each of the holes is shown in Fig.5. Alternatively, if you’ve purchased a complete kit, the box will probably be supplied predrilled, with screened graphics for the front panel. The PC board assembly is secured to the lid using four M3 x 10mm tapped Table 1: Capacitor Codes Value 100nF 10nF 4.7nF 470pF 100pF μF Code 0.1µF .01µF .0047µF   NA   NA EIA Code   104   103   472   470   100 IEC Code   100n   10n   4n7    470p    100p spacers and eight M3 x 6mm machine screws (see photo). Once that’s been done, it’s time to check the transmitter’s operation. Checkout & adjustment It’s easy to check and adjust the transmitter’s operation using a frequency counter, an oscilloscope and an audio signal generator. However, these are not essential and you can do the Table 2: Resistor Colour Codes o o o o o o o o o siliconchip.com.au No. 2 1 8 2 3 4 1 1 Value 15kW 12kW 10kW 3.3kW 1.5kW 1kW 560W 470W 4-Band Code (1%) brown green orange brown brown red orange brown brown black orange brown orange orange red brown brown green red brown brown black red brown green blue brown brown yellow violet brown brown 5-Band Code (1%) brown green black red brown brown red black red brown brown black black red brown orange orange black brown brown brown green black brown brown brown black black brown brown green blue black black brown yellow violet black black brown January 2006  37 Fig.4: this is the full-size front-panel artwork. It can be cut out and used directly if required and can be protected using wide strips of adhesive tape. job quite well using just a multimeter (preferably a DMM) and a reasonably sensitive AM radio receiver. The step-by-step adjustment procedure is as follows: (1) Switch the radio on and tune it to a convenient frequency in the lower section of the broadcast band, away from any of the local broadcasting stations (in Sydney, you can tune to about 820kHz). (2) Turn the volume up (you’ll just hear static at this stage) and position the radio near the transmitter, orientated so that its internal ferrite rod antenna is roughly parallel to the transmitter’s ferrite rod. (3) Turn the transmitter’s tuning control (VC1) to one end of its range, set trimpot VR1 well away from its centre position (this is important) and set VR2 (modulation depth) to its midrange position. (4) Turn the adjustment slug in T1 anticlockwise a couple of turns using a small screwdriver or alignment tool. (5) Feed a stereo audio signal from your MP3 or CD player into the trans- mitter by plugging the audio cable into CON2. (6) Apply power to the transmitter and check that the power LED (LED1) lights. If it doesn’t, unplug the power lead and look for your wiring mistake. You’ve probably fitted either D1 or LED1 with reversed polarity. (7) Use your DMM to check the supply voltage at the output pin of REG1, relative to board earth; it should be very close to +12V. Check that the voltage at pin 8 of IC1 is close to +6V (if these voltages check out correctly, your transmitter is very likely to be working correctly). (8) Listen carefully to the radio while you turn the transmitter’s tuning knob very slowly towards the other end of its range. At some point, you should start to hear the music from your MP3 or CD player, after which you should be able to tune the transmitter so that its signal is received at a good strength. Troubleshooting Can’t find the signal? The first thing to do is to try tuning the transmitter Vintage Australian Radio Programs On CD If you’d like to rebroadcast genuine old time Aussie radio programs through your “Little” Jim AM Transmitter, you should know that many of the programs are now available on CD from ScreenSound Australia (the National Screen and Sound Archive). Currently they have some 11 different CDs available, with classic “golden age of radio” programs, including quiz shows, serials like Dad & Dave and 38  Silicon Chip Mrs ’Obbs, comedies like The Bunkhouse Show and McCackie Mansion, and so on. All CDs are currently available for $24.95 each, including GST (but not postage). For more information on what’s available, visit the ScreenSound website at shop.screensound.gov. au. You can even buy the CDs direct via their secure online purchasing system. back the other way but even more slowly and carefully than before. If this still doesn’t bring success, try turning the adjustment slug in oscillator coil T1 anticlockwise another half-turn (or even a full turn if this later proves necessary). This will shift the oscillator’s tuning range up in frequency and should allow you to correctly adjust the transmitter when you tune VC1 over its range again. If you still can’t find the transmitter’s signal, it may be that its output is a little too weak to be picked up by the receiver. In that case, try draping the transmitter’s antenna wire over the receiver, or twist it around the receiver’s telescopic FM antenna if it has one, just to couple in a bit more of the transmitter’s output. Once you’ve found the signal and adjusted the transmitter’s tuning con­ trol for the best reception, try turning up the transmitter’s modulation control (VR2). This should make the reception even louder and clearer but if you turn the control up too far, the music will become distorted. Just back it off again until the distortion disappears. You can also try adjusting trimpot VR1, because a small amount of adjustment one way or the other can also improve transmission clarity. That said, you’ll find that its optimum position is about halfway between the centre and one of the end positions of the rotor (on either side). Don’t set this trimpot (VR1) too close to its midway (centre) position, because this balances out the RF carrier altogether and gives double sideband (DSB) suppressed carrier modulation. And that gives and quite high distortion when you’re using a normal AM receiver. Once all the adjustments have been made, your Little Jim AM Transmitter is working correctly and you’re ready for the final assembly. Final assembly If your UB3 box has vertical PC board mounting ribs inside, you’ll also have to cut some of these away. That’s because the transmitter board assembly is a fairly tight fit inside the box and the ribs foul the ferrite rod and its coil. The ribs to remove are mainly those at the rear side of the box, where they interfere with the ferrite rod. However it’s also a good idea to cut away any siliconchip.com.au Fig.5: this diagram shows the drilling and cutout details for the plastic case. siliconchip.com.au January 2006  39 Why Did We Call It “Little Jim”? Now then, perhaps we should explain the “Little Jim” monicker. Why not “Little Harry”, or “Little Jack”, or “Little Curly” or “Little Mary”? Come to think of it, why “Little” anything? The answer to that question can be found in two May 1938 issues of “Wireless Weekly”, the forerunner to “Radio & Hobbies” magazine which itself later evolved into “Radio, TV & Hobbies” and finally “Electronics Australia”. Those 1938 issues of “Wireless Weekly” described the construction of a 1-valve AM radio receiver which they called – you’ve guessed it – “Little Jim”. The headline to the article was “Little Jim – Brings Test Play To Your Bedside!”. Don’t get excited – they were talking about the cricket! “Little Jim” was pretty simple as AM radios go, using just a single 6A6 twin-triode valve as both a regenerative detector and audio amplifier. It generated sufficient output to drive a pair of headphones and the original was built into an old butter box with an aluminium front panel. A 45V B battery generated the high tension (HT), while the 6.3V AC filament supply was derived from the 240V mains via a transformer. You could build “Little Jim” by scrounging the parts yourself but there was also a kit available. Yes, they had kits back in those days and “Little Jim” was available as a kit of parts (without the cabinet) for the princely sum of four pounds from a company called Foxradio (Fox and MacGillicuddy) of 57 York St, Sydney. Of course, we’re not too sure ribs on the end near the holes for CON1 and CON2, because these can make final assembly more difficult. You should also cut away any ribs on the front of the box, around the holes for LED1 and VR2, as this make the final assembly even easier. The ribs are easy to remove. The ABS material used in these boxes is fairly soft and can be cut away using a sharp hobby knife or small wood chisel. Once the ribs are gone, remove the knob from modulation pot VR2 (if you 40  Silicon Chip The original “Little Jim” was a 1-valve AM receiver built into a modified butter box, with an aluminium front panel. Fig.6: the circuit used a single 6A6 twin-triode valve as both a regenerative detector and audio amplifier. It generated sufficient output to drive a pair of headphones (actually, we have no idea) why the “Wireless Weekly” editors called their receiver “Little Jim” but no matter. That was the name it was given and it proved to be very popular – so popular, in fact, that it was republished in the very first issue of “Radio & Hobbies” magazine, in April 1939. That set was followed by a full battery-powered version dubbed “Little Jim’s Mate” in the May 1939 issue. But it didn’t end there, with lot’s more have fitted it for the checkout) and unscrew the nut from VR2’s ferrule. That done, thread the free end of the transmitter’s antenna wire through the small hole in the rear of the box (from the inside) and pull most of it through the hole. You can now introduce the box to front of the lid/board assembly at a suitable angle, passing VC1’s disc knob through its slot and LED1 and VR2’s shaft through their respective holes. Next, swing the box down over the board assembly, pulling the remain- variations published in subsequent years. In short, there were lots of “Little Jims” and his “mates” published during the valve era. So that’s where we got the name from. When Jim Rowe came in with his new flea-powered AM transmitter, we initially struggled to come up with a good name for it. “Why not Little Jim?”, said the office smart-elec and despite the groans all round, the name stuck. ing antenna wire through its hole as you do so. As it comes down, slide it slightly towards the CON1/CON2 end, so that the ferrule of CON2 enters its clearance hole. That done, you can fit the nut to VR2’s threaded ferrule. Tighten it firmly and then refit the knob. Finally, turn the assembled box over and fit the four supplied self-tapping screws supplied to fasten everything together. Your “Little Jim” AM Transmitter is now finished and ready for SC action. siliconchip.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.microbric.com ALL S ILICON C HIP SUBSCRIBERS – PRINT, OR BOTH – AUTOMATICALLY QUALIFY FOR A REFERENCE $ave 10%ONLINE DISCOUNT ON ALL BOOK OR PARTSHOP PURCHASES. CHIP BOOKSHOP 10% (Does not apply to subscriptions) SILICON For the latest titles and information, please refer to our website books page: www.siliconchip.com.au/Shop/Books PIC MICROCONTROLLERS: know it all SELF ON AUDIO Multiple authors $85.00 The best of subjects Newnes authors have written over the past few years, combined in a one-stop maxi reference. Covers introduction to PICs and their programming in Assembly, PICBASIC, MBASIC & C. 900+ pages. PROGRAMMING and CUSTOMIZING THE PICAXE By David Lincoln (2nd Ed, 2011) $65.00* A great aid when wrestling with applications for the PICAXE See series of microcontrollers, at beginner, intermediate and Review April advanced levels. Every electronics class, school and library should have a copy, along with anyone who works with PICAXEs. 300 pages in paperback. 2011 PIC IN PRACTICE by D W Smith. 2nd Edition - published 2006 $60.00* Based on popular short courses on the PIC, for professionals, students and teachers. Can be used at a variety of levels. An ideal introduction to the world of microcontrollers. 255 pages in paperback. PIC MICROCONTROLLER – your personal introductory course By John Morton 3rd edition 2005. $60.00* A unique and practical guide to getting up and running with the PIC. It assumes no knowledge of microcontrollers – ideal introduction for students, teachers, technicians and electronics enthusiasts. Revised 3rd edition focuses entirely on re-programmable flash PICs such as 16F54, 16F84 12F508 and 12F675. 226 pages in paperback. by Douglas Self 2nd Edition 2006 $69.00* A collection of 35 classic magazine articles offering a dependable methodology for designing audio power amplifiers to improve performance at every point without significantly increasing cost. Includes compressors/limiters, hybrid bipolar/FET amps, electronic switching and more. 467 pages in paperback. SMALL SIGNAL AUDIO DESIGN By Douglas Self – First Edition 2010 $95.00* The latest from the Guru of audio. Explains audio concepts in easy-to-understand language with plenty of examples and reasoning. Inspiration for audio designers, superb background for audio enthusiasts and especially where it comes to component peculiarities and limitations. Expensive? Yes. Value for money? YES! Highly recommended. 558 pages in paperback. AUDIO POWER AMPLIFIER DESIGN HANDBOOK by Douglas Self – 5th Edition 2009 $85.00* "The Bible" on audio power amplifiers. Many revisions and updates to the previous edition and now has an extra three chapters covering Class XD, Power Amp Input Systems and Input Processing and Auxiliarly Subsystems. Not cheap and not a book for the beginner but if you want the best reference on Audio Power Amps, you want this one! 463 pages in paperback. DVD PLAYERS AND DRIVES by K.F. Ibrahim. Published 2003. $71.00* OP AMPS FOR EVERYONE By Bruce Carter – 4th Edition 2013 $83.00* This is the bible for anyone designing op amp circuits and you don't have to be an engineer to get the most out of it. It is written in simple language but gives lots of in-depth info, bridging the gap between the theoretical and the practical. 281 pages, A guide to DVD technology and applications, with particular focus on design issues and pitfalls, maintenance and repair. Ideal for engineers, technicians, students of consumer electronics and sales and installation staff. 319 pages in paperback. by Sanjaya Maniktala, Published April 2012. $83.00 Thoroughly revised! The most comprehensive study available of theoretical and practical aspects of controlling and measuring EMI in switching power supplies. Subtitled Exploring the PIC32, a Microchip insider tells all on this powerful PIC! Focuses on examples and exercises that show how to solve common, real-world design problems quickly. Includes handy checklists. FREE CD-ROM includes source code in C, the Microchip C30 compiler, and MPLAB SIM. 400 pages paperback. By Garry Cratt – Latest (7th) Edition 2008 $49.00 Written in Australia, for Australian conditions by one of Australia's foremost satellite TV experts. If there is anything you wanted to know about setting up a satellite TV system, (including what you can't do!) it's sure to be covered in this 176-page paperback book. See Review Feb 2004 SWITCHING POWER SUPPLIES A-Z PROGRAMMING 32-bit MICROCONTROLLERS IN C By Luci di Jasio (2008) $79.00* PRACTICAL GUIDE TO SATELLITE TV See Review March 2010 ELECTRIC MOTORS AND DRIVES By Austin Hughes & Bill Drury - 4th edition 2013 $59.00* This is a very easy to read book with very little mathematics or formulas. It covers the basics of all the main motor types, DC permanent magnet and wound field, AC induction and steppers and gives a very good description of how speed control circuits work with these motors. Soft covers, 444 pages. NEWNES GUIDE TO TV & VIDEO TECHNOLOGY By KF Ibrahim 4th Edition (Published 2007) $49.00 It's back! Provides a full and comprehensive coverage of video and television technology including HDTV and DVD. Starts with fundamentals so is ideal for students but covers in-depth technologies such as Blu-ray, DLP, Digital TV, etc so is also perfect for engineers. 600+ pages in paperback. 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Feb 2003 BUILD YOUR OWN ELECTRIC MOTORCYCLE by Carl Vogel. Published 2009. $40.00* by Ian Hickman. 4th edition 2007 $61.00* Alternative fuel expert Carl Vogel gives you a hands-on guide with A guide to RF design for engineers, technicians, students and enthusiasts. the latest technical information and easy-to-follow instructions Covers key topics in RF: analog design principles, transmission lines, for building a two-wheeled electric vehicle – from a streamlined couplers, transformers, amplifiers, oscillators, modulation, transmitters and scooter to a full-sized motorcycle. 384 pages in soft cover. receivers, propagation and antennas. 279 pages in paperback. *NOTE: ALL PRICES ARE PLUS P&P – AUSTRALIA ONLY: $10.00 per order; NZ – $AU12.00 PER BOOK; REST OF WORLD $AU18.00 PER BOOK To Place Your Order: INTERNET (24/7) PAYPAL (24/7) eMAIL (24/7) www.siliconchip. com.au/Shop/Books Use your PayPal account silicon<at>siliconchip.com.au silicon<at>siliconchip.com.au with order & credit card details FAX (24/7) MAIL (24/7) Your order and card details to Your order to PO Box 139 Collaroy NSW 2097 (02) 9939 2648 with all details PHONE – (9-5, Mon-Fri) Call (02) 9939 3295 with with order & credit card details You can also order and pay for books by cheque/money order (Mail Only). Make cheques payable to Silicon Chip Publications. ALL TITLES SUBJECT TO AVAILABILITY. PRICES VALID FOR MONTH OF MAGAZINE ISSUE ONLY. ALL PRICES INCLUDE GST ALL S ILICON C HIP SUBSCRIBERS – PRINT, OR BOTH – AUTOMATICALLY QUALIFY FOR A REFERENCE $ave 10%ONLINE DISCOUNT ON ALL BOOK OR PARTSHOP PURCHASES. CHIP BOOKSHOP 10% (Does not apply to subscriptions) SILICON For the latest titles and information, please refer to our website books page: www.siliconchip.com.au/Shop/Books PIC MICROCONTROLLERS: know it all SELF ON AUDIO Multiple authors $85.00 The best of subjects Newnes authors have written over the past few years, combined in a one-stop maxi reference. Covers introduction to PICs and their programming in Assembly, PICBASIC, MBASIC & C. 900+ pages. PROGRAMMING and CUSTOMIZING THE PICAXE By David Lincoln (2nd Ed, 2011) $65.00* A great aid when wrestling with applications for the PICAXE See series of microcontrollers, at beginner, intermediate and Review April advanced levels. Every electronics class, school and library should have a copy, along with anyone who works with PICAXEs. 300 pages in paperback. 2011 PIC IN PRACTICE by D W Smith. 2nd Edition - published 2006 $60.00* Based on popular short courses on the PIC, for professionals, students and teachers. Can be used at a variety of levels. An ideal introduction to the world of microcontrollers. 255 pages in paperback. PIC MICROCONTROLLER – your personal introductory course By John Morton 3rd edition 2005. $60.00* A unique and practical guide to getting up and running with the PIC. It assumes no knowledge of microcontrollers – ideal introduction for students, teachers, technicians and electronics enthusiasts. Revised 3rd edition focuses entirely on re-programmable flash PICs such as 16F54, 16F84 12F508 and 12F675. 226 pages in paperback. by Douglas Self 2nd Edition 2006 $69.00* A collection of 35 classic magazine articles offering a dependable methodology for designing audio power amplifiers to improve performance at every point without significantly increasing cost. Includes compressors/limiters, hybrid bipolar/FET amps, electronic switching and more. 467 pages in paperback. SMALL SIGNAL AUDIO DESIGN By Douglas Self – First Edition 2010 $95.00* The latest from the Guru of audio. Explains audio concepts in easy-to-understand language with plenty of examples and reasoning. Inspiration for audio designers, superb background for audio enthusiasts and especially where it comes to component peculiarities and limitations. Expensive? Yes. Value for money? YES! Highly recommended. 558 pages in paperback. AUDIO POWER AMPLIFIER DESIGN HANDBOOK by Douglas Self – 5th Edition 2009 $85.00* "The Bible" on audio power amplifiers. Many revisions and updates to the previous edition and now has an extra three chapters covering Class XD, Power Amp Input Systems and Input Processing and Auxiliarly Subsystems. Not cheap and not a book for the beginner but if you want the best reference on Audio Power Amps, you want this one! 463 pages in paperback. DVD PLAYERS AND DRIVES by K.F. Ibrahim. Published 2003. $71.00* OP AMPS FOR EVERYONE By Bruce Carter – 4th Edition 2013 $83.00* This is the bible for anyone designing op amp circuits and you don't have to be an engineer to get the most out of it. It is written in simple language but gives lots of in-depth info, bridging the gap between the theoretical and the practical. 281 pages, A guide to DVD technology and applications, with particular focus on design issues and pitfalls, maintenance and repair. Ideal for engineers, technicians, students of consumer electronics and sales and installation staff. 319 pages in paperback. by Sanjaya Maniktala, Published April 2012. $83.00 Thoroughly revised! The most comprehensive study available of theoretical and practical aspects of controlling and measuring EMI in switching power supplies. Subtitled Exploring the PIC32, a Microchip insider tells all on this powerful PIC! Focuses on examples and exercises that show how to solve common, real-world design problems quickly. Includes handy checklists. FREE CD-ROM includes source code in C, the Microchip C30 compiler, and MPLAB SIM. 400 pages paperback. By Garry Cratt – Latest (7th) Edition 2008 $49.00 Written in Australia, for Australian conditions by one of Australia's foremost satellite TV experts. If there is anything you wanted to know about setting up a satellite TV system, (including what you can't do!) it's sure to be covered in this 176-page paperback book. See Review Feb 2004 SWITCHING POWER SUPPLIES A-Z PROGRAMMING 32-bit MICROCONTROLLERS IN C By Luci di Jasio (2008) $79.00* PRACTICAL GUIDE TO SATELLITE TV See Review March 2010 ELECTRIC MOTORS AND DRIVES By Austin Hughes & Bill Drury - 4th edition 2013 $59.00* This is a very easy to read book with very little mathematics or formulas. It covers the basics of all the main motor types, DC permanent magnet and wound field, AC induction and steppers and gives a very good description of how speed control circuits work with these motors. Soft covers, 444 pages. NEWNES GUIDE TO TV & VIDEO TECHNOLOGY By KF Ibrahim 4th Edition (Published 2007) $49.00 It's back! Provides a full and comprehensive coverage of video and television technology including HDTV and DVD. Starts with fundamentals so is ideal for students but covers in-depth technologies such as Blu-ray, DLP, Digital TV, etc so is also perfect for engineers. 600+ pages in paperback. RF CIRCUIT DESIGN by Chris Bowick, Second Edition, 2008. $63.00* The classic RF circuit design book. RF circuit design is now more important that ever in the wireless world. In most of the wireless devices that we use there is an RF component – this book tells how to design and integrate in a very practical fashion. 244 pages in paperback. PRACTICAL RF HANDBOOK AC MACHINES By Jim Lowe Published 2006 $66.00* Applicable to Australian trades-level courses including NE10 AC Machines, NE12 Synchronous Machines and the AC part of NE30 Electric Motor Control and Protection. Covering polyphase induction motors, singlephase motors, synchronous machines and polyphase motor starting. 160 pages in paperback. PRACTICAL VARIABLE SPEED DRIVES & POWER ELECTRONICS Se e by Malcolm Barnes. 1st Ed, Feb 2003. $73.00* Review An essential reference for engineers and anyone who wishes to design or use variable speed drives for induction motors. 286 pages in soft cover. Feb 2003 BUILD YOUR OWN ELECTRIC MOTORCYCLE by Carl Vogel. Published 2009. $40.00* by Ian Hickman. 4th edition 2007 $61.00* Alternative fuel expert Carl Vogel gives you a hands-on guide with A guide to RF design for engineers, technicians, students and enthusiasts. the latest technical information and easy-to-follow instructions Covers key topics in RF: analog design principles, transmission lines, for building a two-wheeled electric vehicle – from a streamlined couplers, transformers, amplifiers, oscillators, modulation, transmitters and scooter to a full-sized motorcycle. 384 pages in soft cover. receivers, propagation and antennas. 279 pages in paperback. *NOTE: ALL PRICES ARE PLUS P&P – AUSTRALIA ONLY: $10.00 per order; NZ – $AU12.00 PER BOOK; REST OF WORLD $AU18.00 PER BOOK To Place Your Order: INTERNET (24/7) PAYPAL (24/7) eMAIL (24/7) www.siliconchip. com.au/Shop/Books Use your PayPal account silicon<at>siliconchip.com.au silicon<at>siliconchip.com.au with order & credit card details FAX (24/7) MAIL (24/7) Your order and card details to Your order to PO Box 139 Collaroy NSW 2097 (02) 9939 2648 with all details PHONE – (9-5, Mon-Fri) Call (02) 9939 3295 with with order & credit card details You can also order and pay for books by cheque/money order (Mail Only). Make cheques payable to Silicon Chip Publications. ALL TITLES SUBJECT TO AVAILABILITY. PRICES VALID FOR MONTH OF MAGAZINE ISSUE ONLY. ALL PRICES INCLUDE GST CIRCUIT NOTEBOOK Interesting circuit ideas which we have checked but not built and tested. Contributions from readers are welcome and will be paid for at standard rates. Winch controller for boaties & 4WDers Australia has a high percentage of domestic boat ownership, with over 600,000 registered owners in 2000. Winches are a necessary part of the gear and are typically used with boat trailers and on slipways. They’re also very popular on 4WD vehicles for use in the bush. Here is a companion winch controller that (with its remote control) will make your boat or 4WD ownership even more enjoyable. At the heart of the design is a PICAXE micro, which receives “rope in”, “rope out” and “all stop” commands via pushbutton switches or wireless remote control. In response, it controls the winch motor using two power relays (see Fig.1). The complete circuit diagram for the winch controller appears in Fig.2. Looking first at the microcontroller inputs (P1, P3 & P4), these all originate from the pushbutton switches (S1-S3) and RF decoder (IC1) outputs, as well as the two Fig.1: the block diagram for the system. It controls the winch motor using two power relays. 44  Silicon Chip limit switches (S4 & S5). All inputs are “deglitched” with the aid of identical monostable circuits, comprised of one inverter gate and two NAND gates plus a few resistors and capacitors. The monostable circuits provide a clean, 100ms positive pulse to the associated PICAXE input when their inputs transition from high to low, ignoring subsequent switch contact bounce or spurious noise from the RF receiver outputs. Two port pins of the PICAXE (P0 & P2) are configured as outputs to drive transistors Q1 & Q2, which in turn control two high-power relays. In the relaxed (normally-closed) state, the relay contacts short the motor terminals together; this is the “all stop” position. When the “rope in” switch is pressed, the program sets output0 (P0) high and relay RLY1 is energised, connecting power to one side of the motor to retract the winch cable. Alternatively, when the “rope out” switch is pressed, output2 (P2) goes high and RLY2 is energised, reversing the direction of the motor and therefore releasing the winch cable. Stress limits Bob Ham is this m mond on winner th’s Peak At of a las Instrum Test ent Limit switches are used in this application to (indirectly) switch off the motor when the cable is fully retracted or deployed, to prevent excessive strain being placed on the winching system. Limit switches should be used if the winch design supports them. To illustrate the need for these switches, imagine that the fishing is finished for the day and the boat has been winched into the shed. During winching, the “in” limit switch has opened, removing power to the motor. This switch now forms a kind of “memory”, so that days later, when the winch is switched on again, it cannot be accidentally operated in the wrong direction. Consider the “in” limit switch action, for example. Initially, with RLY1 energised, the winch will be running. When the cable fully retracts, the “in” limit switch (S4) is physically contacted, changing its pole to the alternate position and removing drive current to the base of Q1. This immediately deenergises the relay and switches off the motor. Now in the alternate position, the switch contacts connect output0 of the PICAXE (P0) to diode D11 and the input of a monostable circuit. The result is a clean, positive-going pulse at input3 (P3) of the micro. On detecting the pulse, the BASIC program responds by taking output0 low and then waiting for the next command. The signal path from output0 to transistor Q1 and the relay are now open circuit, preventing the “rope in” command from having any further effect until the “rope out” command is used to play out some slack. This safeguards against overrunning the limit switch. The siliconchip.com.au siliconchip.com.au January 2006  45 Fig.2: the winch controller circuit receives and decodes the commands from the transmitter. These commands are then processed by microcontroller IC4 (PICAXE-08M) which in turn controls the motor relays. Circuit Notebook – Continued Fig.3: the transmitter is based on a pre-built RF module and is simple enough to build into a hand-held instrument case. “out” limit switch functions in the same manner. If limit switches aren’t needed in your application, then all of the associated support circuitry can be omitted. This includes D11, D12, D8, IC3c, IC3d, IC5d, etc. The cathodes of diodes D9 & D10 are then connected directly to Q1 & Q2’s 1.5kW base resistors, respectively. Remote control. Fig.3 shows a 3-channel transmitter suitable for use with the winch controller. Low-cost Laipac (or sim­ ilar) 433MHz RF transmitter and receiver modules are used for the remote control section. Button presses are encoded at the transmitter end using a SM5162 trinary encoder IC and decoded at the receiver end using the complementary SM5172 decoder. The address pins on the encoder and decoder IC (not shown) can be connected to +V, 0V, or left opencircuit to create a trinary-based security code. Both the transmitter and receiver address pins must be wired exactly the same way. However, you should leave all of the address pins open-circuit until you get the transmitter and receiver working properly. At the receiver end, a DVM can be connected between pin 17 of IC1 and ground for faultfinding purposes. On reception of a valid transmission (a button press on the remote), this pin should swing to a logic high (about +4.7V). Once the units have been tested, the address pins should be coded to minimise the possibility of interference with other systems. Note that this remote control scheme operates identically to a number of garage door openers and the like that have been published in SILICON CHIP in recent years – eg, the 4-Channel UHF Remote Control described in the June 2003 issue. Contribute And Choose Your Prize As you can see, we pay good money for each of the “Circuit Notebook” items published in SILICON CHIP. But now there are four more reasons to send in your circuit idea. Each month, the best contri- 46  Silicon Chip bution published will entitle the author to choose the prize: an LCR40 LCR meter, a DCA55 Semiconductor Component Analyser, an ESR60 Equivalent Series Resistance Analyser or an SCR100 Thyristor & Triac Analyser, with the compliments of Peak Electronic Design Ltd www.peakelec.co.uk So now you have even more reasons to send that brilliant circuit in. Send it to SILICON CHIP and you could be a winner. You can either email your idea to silchip<at>siliconchip.com.au or post it to PO Box 139, Collaroy, NSW 2097. siliconchip.com.au Datasheets for the Laipac TLP434 transmitter and RLP-434 receiv­ er modules are available from www. laipac.com. Compatible 433MHz modules are available from all major kit suppliers. Oatley Electronics sells the encoder and decoder ICs (stock codes SM5162RF & SM5172RF). Check ’em out at www. oatleye.com, with datasheets available from www.samhop.com.tw. Antenna choices For operation at 433.92MHz, a quarter-wavelength antenna needs to be 172mm long. If you are using a plastic case for the transmitter, then a 172mm length of wire may be wound into an oblong and glued inside the case. Alternatively, an extendable rod antenna could be used. The receiver requires only a wire cut to 172mm, although it too could use a rod antenna. With a little finetuning, a range of approximately 50-60 metres is easily obtainable. Although greater range is possible by using more elaborate antennae, safety is an overriding factor. You should always be in visual contact with the winch and the load that is being winched, to guard against injury to others. The BASIC program The PICAXE program for this application is self-explanatory. Of note is the use of the ’08M’s interrupt feature to detect positive transitions on input3, which can originate from the “all stop” switch or the limit switches. Once up and running, check that the winch comes to a complete stop before reversing direction when the “rope out” and “rope in” buttons are pressed in quick succession. The length of the pause command in the Init: section of the program can be trimmed to ensure that this occurs. Finally, the author recommends the use of high-quality pushbutton switches to ensure reliable, longterm operation. While the monostable circuits will remove switch contact bounce, they cannot compensate for faulty switch contacts! Bob Hammond, Engadine, NSW. siliconchip.com.au Program Listing ;****************************************** ;* ;* Marine Winch Motor Control V1.7 ;* ;******************************************* ; ; NOTE: pin0 – pin4 are all active high ; ; Initialisation ; setint %00001000, %00001000 b5 = 0 ; ; Main program start ; Init: low output0 low output2 pause 1000 ; b5 = 0 ; Exec: if b5 = 1 then Init pause 10 if Pin4 = 1 then WinchIn pause 10 if Pin1 = 1 then WinchOut goto Exec ; NextSwitch: if b5 = 1 then Init pause 10 if pin4 = 1 then Init pause 10 if pin1 = 1 then Init pause 10 goto NextSwitch ; WinchIn: if b5 = 1 then Init high output0 pause 300 goto NextSwitch ; WinchOut: if b5 = 1 then Init high output2 pause 300 goto NextSwitch end ; Interrupt: low output0 low output2 input3 = 0 b5 = 1 setint %00001000, %00001000 return ;interrupt when IN3 goes high ;interrupt Flag ;turn off IN relay ;turn off OUT relay ;motor pause - set to suit motor, ;must allow motor to stop ;zero the interrupt flag ;primary input ;has interrupted so init ;secondary switch point ;has interrupted so init ;rope in ;has interrupted so init ;pull the rope in ;settle time ;rope out ;has interrupted so init ;let the rope out ;settle time ;should not get here! ;switch off IN relay ;switch off OUT relay ;reset pin3 for next interrupt ;set the interrupt flag ;restore interrupt January 2006  47 Circuit Notebook – Continued Pushbutton relay selector This circuit was designed for use in a hifi showroom, where a choice of speakers could be connected to a stereo amplifier for comparative purposes. It could be used for other similar applications where just one of an array of devices needs to be selected at any one time. A bank of mechanically interlocked DPDT pushbutton switches is the simplest way to perform this kind of selection but these switches aren’t readily available nowadays and are quite expensive. This simple circuit performs exactly the same job. It can be configured with any number of outputs between two and nine, simply by adding pushbutton switches and relay driver circuits to the currently unused outputs of IC2 (O5-O9). Gate IC1a is connected as a relaxation oscillator which runs at about 20kHz. Pulses from the oscillator are fed to IC1b, where they are gated with a control signal from IC1c. The result is inverted by IC1d and fed into the clock input (CP0) of IC2. 48  Silicon Chip Initially, we assume that the reset switch (S1) has been pressed, which forces a logic high at the O0 output (pin 3) of IC2 and logic lows at all other outputs (O1-O9). As the relay driver transistors (Q1-Q4) are switched by these outputs, none of the relays will be energised after a reset and none of the load devices (speakers, etc) will be selected. Now consider what happens if you press one of the selector switches (S2-S5, etc). For example, pressing S5 connects the O4 output (pin 10) of IC2 to the input (pin 9) of IC1c, pulling it low. This causes the output (pin 10) to go high, which in turn pulls the input of IC1b (pin 5) high and allows clock pulses to pass through to decade counter IC2. The 4017B counts up until a high level appears at its O4 output. This high signal is fed via S5 to pin 9 of NAND gate IC1c, which causes its output (pin 10) to go low. This low signal also appears on pin 5 of IC1b, which is then inhibited from passing further clock pulses on its other input (pin 6) through to its output (pin 4), thus halting the counter. So, the counter runs just long enough to make the output connected to the switch that is pressed go high. This sequence repeats regardless of which selector switch you press, so the circuit functions as an electronic interlock system. Each relay driver circuit is a 2N7000 FET switch with its gate driven from one output of IC2 via a 100W resistor. The relay coil is connected from the drain to the +12V supply rail, with a reverse diode spike suppressor across each coil. If you want visual indication of the selected output, an optional indicator LED and series resistor can be connected across each relay coil, as shown. For selecting pairs of stereo speakers, we’d suggest the use of relays like the Jaycar SY-4052. These operate from 12V and have DPDT contacts rated for 5A. Note that although four selector switches are shown in the circuit, only two relay drivers are shown because of limited space. For a 4-way selector, identical relay drivers would be driven from the O2 and O3 outputs of IC2. Jim Rowe, SILICON CHIP. siliconchip.com.au Dual input-combining stereo line amplifier This circuit takes two separate line-level stereo (L & R) signals and combines them into one stereo (L & R) output, thus avoiding the need to switch between two pairs of input signals. In the author’s application, it is used to feed the stereo audio from a TV receiver and a DVD player into an external amplifier. The need for the circuit arose because of a design peculiarity in the TV receiver. The TV has four A/V inputs and one A/V output. AV1AV3 accept composite or S-video plus stereo audio inputs and these feed into the TV’s A/V output. AV4 accepts Component video (Y/Pb/Pr) plus stereo audio but unlike AV1AV3, its audio (and video) signals are not fed to the TV A/V output. The Y/Pb/Pr input was chosen for use with the DVD player because of its superior video quality, while the audio was to be fed to an external amplifier for improved reproduction. However, manual switching was inconvenient, hence the genesis of this design. In use, the DVD player audio is fed in parallel to TV AV4 and to one input pair of the combining amplifier, while the TV audio output feeds the other input pair. The amplifier output goes to the external audio amplifier. There is no conflict between the two audio inputs because when AV4 (DVD player) is selected, there is no TV audio output. In all other modes, the DVD player is off. As shown, the circuit has a voltage gain of 1.5 times (3.5dB) but this can be altered as required by changing the two 15kW resistors. Input impedance is 10kW and the outputs are isolated from cable and amplifier input capacitance with 47W series resistors. The circuit can be powered from a regulated 12V DC plugpack. Garth Jenkinson, Emerald, Vic. ($40) Battery desulphation progress monitor A number of readers have asked how to tell when the Lead-Acid Battery Zapper (SILICON CHIP, July 2005) has done its job and battery desulphation is complete. In the author’s experience, batteries that are going to respond to this treatment will generally show quite a high peak voltage across the terminals at the beginning of the treatment. If this steadily decreases and practically disappears, then the treatment is near to complete. This may take anything from a week to many months, depending on the size and condition of the battery. In the absence of an oscilloscope to monitor the voltage peaks, a simple peak detector can be constructed from a fast diode and 100nF capacitor. Any siliconchip.com.au high-impedance multimeter (eg, most digital types) can then be used to measure the average DC voltage across the capacitor. Graham Lill, Lindisfarne, Tas. ($30) January 2006  49 Circuit Notebook – Continued Nicad charger uses voltage cut-out This circuit charges two NiCad cells with a constant current and features dual charging rates, voltage cutoff and an audible alarm. The circuit is powered by a 12VAC centre-tapped mains transformer, together with two rectifier diodes (D1 & D2) and a 1000mF filter capacitor. A 7806 3-terminal regulator is used to generate a 6V rail for the remainder of the circuit. Transistor Q1 and LED1 constitute a basic constant-current source. The forward voltage of the red LED (about 1.5V) minus Q1’s baseemitter voltage (about 0.6V) appears across the 6.8W or 15W emitter resistors, depending on the position of S1. With a 15W resistance in the emitter circuit, the charging current is about 60mA, whereas with 6.8W it is about 130mA. This is sufficient to charge 600mAH “AA” cells in 14 hours and five hours, respectively. An LM393 voltage comparator (IC1) is used for the voltage cutoff function. Its inverting input is set to 2.9V (nominal) via trimpot VR1, while the non-inverting input senses battery voltage. This means that while the cells are being charged, the output transistor (in the LM393) is switched on, also switching on Q1 and enabling the current source. Once the cells are charged to approximately 80% or more of capacity, their terminal voltages will exceed 1.45V, so the voltage at the non-inverting input (pin 3) of IC1 will exceed the reference voltage on the inverting input (pin 2). This The Latest From SILICON CHIP • • • • causes IC1’s output to switch off, in turn switching Q1 off and disabling the current source. To prevent rapid switching action around the voltage cutoff point, a 100nF capacitor provides feedback between the output and inverting input of the comparator. Four NAND gates are used to build two simple oscillators of different frequencies. When cascaded together, the result is a pulsed tone from the piezo transducer to indicate charge completion. Editors note: absolute terminal voltage is not always a reliable indicator of Nicad battery charge state. Importantly, batteries should never be charged for longer than the manufacturer’s specified period. Ravi Sumithraarachchi, Colombo, Sri Lanka. ($45) 160 PAGES 23 CHAPTE RS Learn how engine management systems work Build projects to control nitrous, fuel injection and turbo boost systems Switch devices on and off on the basis of signal frequency, temperature and voltage Build test instruments to check fuel injector duty cycle, fuel mixtures and brake & temperature Mail order prices: Aust. $A22.50 (incl. GST & P&P); Overseas $A26.00 via airmail. Order by phoning (02) 9979 5644 & quoting your credit card number; or fax the details to (02) 9979 6503; or mail your order with cheque or credit card details to Silicon Chip Publications, PO Box 139, Collaroy, NSW 2097. 50  Silicon Chip From the publishers of Intelligent turbo timer TURBO BOOST & nitrous fuel controllers I SBN 095852294 - 4 9 780958 522946 $19.80 (inc GST) NZ $22.00 (inc GST) How engine management works siliconchip.com.au THEY ARE BACK IN STOCK ELECTRIC MOTORS, BATTERIES AND SPEED CONTROLLERS 100W, 200W, 300W AND NOW A MASSIVE 500W SEE OUR WEB SITE FOR MORE 200W WIND GENERATOR WITH SLIP RINGS!!! NOW ON SALE FOR ONLY $449 Unlike many similar wind generators these have slip rings so as the main cable will not twist off. These are serious 3ph 200W wind generators with blades spanning 2.2M. 12V or 24V. Included is a 6M mast with guy wires and turnbuckles etc. and a three phase shunt / charge controller unit with voltage and amperage metering. 1 X 45kg box (720 x 440 x 230mm), & 1 X 27.5kg box (1540 x 220 x 110mm). For more information and instructions see COIN HOPPER WITH COIN DISPENSING / COUNTING MECHANISM. This mechanism was designed as part of a vending machine, it suits $1AU coins. It has a 24V motor & gearbox (all metal gears) & an optical $12ea switch to count coins. At 1.8V OR the motor will start running, it is 3 for difficult to stop $27 the output shaft with your fingers (HOP) at this voltage. The two 8mm gearbox output shafts turn in opposite directions, they have a flat on each & our SPR300 sprocket fits the shaft. The combination of our SPR300 11 tooth sprocket & our CHAINSP 80 tooth chain and sprocket set would give a slow & powerful output (approx. 15RMP <at> 24V or 0.96 RPM <at> 2V). This motor & gearbox with chains & sprockets could be used to open doors & gates etc. (see our garage door controller kit K023C).Some approx. voltage/current & RPM figures of the motor/gearbox. 2V 80mA 7RPM, 6V 100mA 30RPM, 12V 120mA 60RPM, 18V 140mA 110RPM, Overall dimensions of the hopper assembly: 93mm(W) X 126mm(L) x 126mm(H). DVD QUALITY TV RECEPTION... TERRESTRIAL DIGITAL TV ON YOUR COMPUTER FOR LESS THAN $100 No more analogue TV after 2008? Enjoy the superior sound & picture quality of free to air digital TV. So good you will enjoy watching the ads. Simply load the software. Plug in an antenna & plug this amazing little metal box into your USB port. So small that RX434A SUPERHETERODYNE RECEIVER it's ideal for laptop computers, measuring only 64mm(L) MODULE: Pre-built superheterodyne surface mount receiver module which is crystal locked at 433.92MHz. X 22mm(W) X 9mm(T) (plus connectors 87mm(L)). The It has a high sensitivity, operates from 5V DC supply. It software allows you to record, take snapshots, Time Shift & lots more. Terrestrial Digital TV is available in most is designed for use with TX434A. When used in places where normal free to air TV is available. It is conjunction with TX434A, the pair can give a range of expected that normal analogue free to air TV over 1km when the transmitter is powered by 9VDC. transmissions will end in 2008. Some of the features of Frequency:433.92MHz digital TV that are now or will be available include sports Transmit rate: 9.6KB/S multi-view, Electronic Program Guides (EPGs), Closed Modulation: A.S.K. Captions & digital radio, while SBS & the ABC often Voltage:5VDC <at> 2.6mA broadcast different programs on multiple channels at the Size: 35mm X 17mm same time. Most of these features are available now. (RX434A) $8 Comes with installation software. (DTVM). See our web TX434A SUPER-REGENERATION TRANSMITTER site for more info on this amazing device. MODULE: Pre-built superheterodyne surface mount SPECIAL INTRODUCTORY transmitter module which is crystal locked at 433.92MHz. Operates from 3-12V DC supply. It is designed for use PRICE OF JUST $89 with RX434A. When used in conjunction with RX434A, can give a range of over 1km when K229 AUDIO / VIDEO TRANSMITTER / RECEIVER KIT the transmitter is powered by 12V DC. This kit (K229T and K229R) are designed to transmit Frequency:433.92MHz and receive video and stereo audio. The TX has Transmit power: 10mW <at> 12V been designed to be as small as practical. (TX kit) Modulation: AM 13mm(H) X 30mm(W) X 30mm(D). Voltage:3-12VDC <at> 15mA (RX kit) 17mm(H) X 50mm(W) X Size: 14mm X 14mm (TX434A) $6 62mm(D) with connectors). K224 3 CHANNEL TO 7 CHANEL INFRA-RED Construction is simple and the preREMOTE CONTROL KIT built modules mean minimal work is Up to three kits can be used together to make a 21 Ch. required and there is no tuning to be system to operate from one remote control. The basic kit done. The antenna can be as simple includes the PCB & all onboard components to build a 3 Ch. IR remote control including relays and screw as a 31mm length of un-shielded stiff wire or another terminals. The additional components required to antenna can be connected remotely via co-ax cable. An expand to 7 Ch. are available in the K224E kit. If not used antenna such as our K198 2.4GHz TX / RX ANTENNA the remaining 4Ch. section of the PCB can be snapped KIT can be added. This antenna kit will increase the range of the K229. off to reduce the overall size of the kit. The K198 is a 3 channel kit $25 (K224R) 2.4Ghz antenna 4 channel expansion kit $11(K224E) printed on a Remote control (pre-built)$6 (K224T) circuit board, it Complete package 7 channel has been tested kit with remote control $39 (K224P) with our previous A/V TX/RX kit and gave good a good image at over 100M. These kits are designed to operate from a 9VDC supply, **NEW**NEW**NEW** We have new replacement UHF434 TX and RX modules. These give equal or better range than our previous modules. (K229T) $17 (K229R) $33 12-24V Dual Battery Adapter for a vehicle. FANTASTIC NEW PRODUCT 1W LED WITH THREE MODES OF OPERATION This LED will simply turn on when connected to power or with the addition of a pushbutton it can be set to full power, half power or flash. This LED is so bright and so fast that it looks almost like a strobe. It would be ideal for use as a safety light or a headlight for a bike. Full specs. on our web site. (3ML)$9.90 9Ch UHF REMOTE CONTROL TRANSMITTER KIT. This kit simply switches an Auxiliary battery across the main battery only when the main battery is fully charged. It will only then charge the second battery. When the battery voltage drops the k227 will isolate the batteries to stop overdischarging of the primary battery. The kit includes all o n b o a r d components, PCB and an 80A single coil Latching relay. (K227) $19 Now with new TX modules The prebuilt UHF module used in this kit requires no tuning or alignment. This kit includes PCB, all onboard components, prebuilt UHF module, 9V battery clip, suitable case & membrane type keypad / label. Requires a 9V battery (not supplied). K226T $27. 4-CHANNEL UHF RECEIVER KIT WITH LIMIT/RESET 9Ch UHF REMOTE CONTROL RECEIVER KIT. INPUTS: This kit is an updated & cheaper version of the This Kit uses our K226T kit to control 9 relays that original K180 kit. It is still a 4-channel UHF remote control can be set in any combination to momentary or with individual limit / reset input for each channel but latching at the flick of a switch. It can be used to without the "code hopping". Uses a pre-built and preswitch just about anything on or off, lights, motors aligned 433MHz UHF receiver module (RX7) (sold separately $11). Combined with our Series V Transmitter etc. This kit can also be used with our TX7. 24 SECOND VOICE / SOUND (TX7), this kit can control 4 output relays in either The pre-built UHF module used in this kit has momentary or latching RECORDER MODULE security encoding and requires no tuning or o p e r a t i o n . F e a t u r e s This small pre-built module will alignment. include high security, range record up to 24 seconds of sound Kit inc. all of ~100m, on-board high at the push of a button, then play current relays with onboard it back at the push of a second indicator LEDs, and screw components, button. Requires 6VDC to terminals for easy PCB and operate. Measures 34mm X connection. Receiver kit prebuilt UHF 22mm Comes with a Now with new RX modules includes PCB and all onmodule. 29mm speaker VRM1$10 board components. $55 K226R (K180B) $33 www.oatleyelectronics.com Suppliers of kits and surplus electronics to hobbyists, experimenters, industry & professionals. Orders: Ph ( 02 ) 9584 3563, Fax 9584 3561, sales<at>oatleyelectronics.com, POJanuary Box 89 Oatley NSW 2223 OR www.oatleye.com siliconchip.com.au 2006  51 major credit cards accepted, Post & Pack typically $7 Prices subject to change without notice ACN 068 740 081 ABN18068 740 081 + $9.90 $19 - SC_JAN_06 SERVICEMAN'S LOG I hate servicing rear-projection sets I have rather a mixed bag this month, ranging from rear-projection TV sets to a surround sound receiver. There’s also a story on what happens if you lose the PIN to your car radio. I hate servicing rear projection TVs. It’s not because they aren’t interesting. Rather, it’s because 90% of the repair is spent in the logistics of handling their enormous bulk and because, until recently, their performance was rather “ho hum” (although that’s changed in the last few years), their main advantage being their large picture. I positively refuse to do in-house service unless it is only a fuse or installation problem. After all, the chassis is at the very bottom of these monoliths and access is usually quite difficult. What’s more, there are usually about one million screws holding the chassis so it won’t fall the few centimetres it is above the ground and smash into a thousand pieces all over the floor. To make matters even more difficult, the PC board tracks are on the underside of the chassis – at least in a car you can lie on a trolley and wheel yourself underneath or raise it on a hoist! An ailing Sony Anyway, Mr Hodges 1996 Sony KPE41SN11 rear projection set (RG-1 chassis) was in the process of failing to proceed. Intermittently, the picture Items Covered This Month • • • • • Sony KPE41SN11 rear projection TV set (RG-1 chassis) Toshiba 43N9UXE rear projection TV set (S99SS chassis) Panasonic TX43P250 rear projection TV set (EURO-7VP chassis) Pioneer VSX-D503S 110W Surround Sound AV receiver Lost PIN For A Car Radio 52  Silicon Chip was slowly getting duller and now there was no vertical deflection. This latter fault can often be extremely serious because if the protection circuit doesn’t cut in, screen burn will result in just a few seconds and ruin the expensive picture tube. This time, we were saved because the picture was so dull. Because of the possible danger to the individual tubes, I decide to tackle the vertical deflection problem first. On normal TV sets, the vertical output IC is usually located not far from the line output stage and flyback transformer. And because the service manual for this set was on order, I thought I would have a crack at it blind. I began by “wedging” the projector between the ceiling and the top of my work bench (it’s possible I might be exaggerating just a little here – but you get my drift!). And because it took up so much space, my soldering iron and all other tools had to be moved onto nearby stools. Even after removing the million or so screws (again, I might be exaggerating a little), it was extremely difficult to edge the chassis out, as the cable harness is tied down tightly to the cabinet in several places. In the end, I gave up and instead decided to remove the board with the flyback transformer (I later discovered that this is the E Board). This was a bad choice as it didn’t really have anything to do with the vertical output. However, having removed it, I resoldered a few potential dry joints and checked the fusible resistors and anything else that looked as though it might throw a spanner into the works. I then refitted the board and moved along to the next on the right – the A board. In fact, on later models, this is the board with the vertical output IC. Removing this board wasn’t easy. First, another one million screws had to be removed and I also had to dissect and remove the AV-inputs board (U) and unplug the processor board B which fits across the A Board. This was tricky for two reasons: (1) there was no headroom; and (2) it was fastened to a sub-frame that had to be unscrewed, not to mention that the main plug had a child-proof lock on it which I couldn’t work out. Eventually, however, with the aid of a lot of muttered words like “bother” and “drat”, I managed to force the boards out, only to discover that what I thought was the vertical IC was in fact the sound output IC. Again, I resoldered everything and then spent a large part of what was left of the rest of my life putting it all back together again. By now, the 140-page Service Manual had arrived and I soon discovered on page 79 that the vertical IC (IC1501, STV9379) was on Board D, somewhere near the front of the set. And so I stuffed the main chassis back into the case and turned the workshop around to get to the front of the set. The D Board turned out to be on the floor pan, behind the HA Board and just in front of the three CRTs. Fortunately, this board is quite easy to move. Once again, I checked for dry joints and also fuses F1601 and F1602 and fusible resistors R1519 and R1520 which supply the ±15V to the IC. Unfortunately, nothing looked crook, although that was the way I was starting to feel. Anyway, I replaced the board and switched the set on to find that it was now dead, with just the front LED flashing. So what had I done? It was time for a new tack – when in doubt, measure the B+ but honestly, why don’t I follow my own advice sooner rather than later! This was a good move because the ±135V rails were way down to just over ±100V. siliconchip.com.au perfectly OK from the main +330V rail from the bridge rectifier. However, this biases the drive to Q6009 and the drive control to IC6009 via optocoupler IC6005. Anyway, this actually fixed all the symptoms this set had and the picture and sound were pretty good. I really earned my money on this one! As a postscript, when I got the manual, I also received a Sony Service Bulletin (AVS167 – 1998) about a fault with this symptom: the “top screen has a brighter band effect noticeable on dark screens”. It suggested changing C289 at pin 1 of IC208 on the dreaded B Board from 4.7mF to 22mF (Part No: 1-128-551-11), so at great risk to what was left of my sanity I replaced that component as well. I do hope that Mr Hodges appreciated my efforts. Other rear projection sets There was a good chance this was where the fault lay. I removed the board and worked on it separately on the kitchen table. Next, I removed plugs CN6011 and CN6009 on the power supply board (board G) to eliminate any possible loading effects and hung a 100W globe across the positive rail. It was still low, however, and even the ±15V rails were low, which probably accounted for the set’s lack of vertical deflection. A few checks showed that the cor- siliconchip.com.au rect voltages were being fed into the board and the “sub power supply” (STBY) was OK too. I then checked the +135V feedback via IC6008 (SE135N) and optocoupler IC6006 and this was also OK. It took another eon of time for me to finally discover that the culprit was 270kW (4W) resistor R6010, which had gone high to the base of Q6001 (RECT OUIT SENC SW). This was surprising, as it is in series with another 270kW resistor (R6009) which was Other similar dramas I have had recently with rear projection TV sets mostly concern the same logistics problems. However, the faults were different. One of the sets involved was a 1999 Toshiba 43N9UXE (S9SS chassis). When the “on” button was pressed, the set would try to come on and you could even hear the rush of static from the EHT. However, that was as far as it would get, the set then shutting down again. This was eventually isolated to R347 (180kW), which had gone high on the January 2006  53 Serviceman’s Log – continued Deflection Board and which feeds a protection circuit involving Q340 and Q341. This circuit monitors the 200V LVP line from the CRTs. In addition, a 36V zener diode (D878) in the 30V power supply for the protection circuit was leaky. The other set was a 2001 Panasonic TX43P250 (EURO-7VP chassis) with an unusual North-South pincushion correction fault (as opposed to EastWest), plus intermittent lack of horizontal synchronisation. Fortunately, we had another identical set in at the time and were able to substitute boards. This second set had a burn spot on the green tube. A possibility here is that the vertical output IC (IC451) and the two convergence amplifiers (IC7001 & IC7002) had spat the dummy on the D Board but if so, why hadn’t the other two tubes been affected? A more likely explanation was that someone had left both the vertical and horizontal deflection yoke outputs disconnected on the green CRT. I have my suspicions. Getting back to the first Panasonic set, I started with the vertical output and convergence boards, which are the most common areas for failure, but no luck there. Next, I tried the A Board and it wasn’t that either, nor was it the DG Digital Module. 54  Silicon Chip Eventually, I found that the problem was on the U Board (TNPA2042AU) which carries microprocessor IC1101, flash ROM (IC1102) and SDRAM (IC1106). The EEPROM (IC1104) is on the A Board which was OK. I really should have guessed sooner as there was no on-screen display (OSD) and the data was being corrupted. Unfortunately, this expensive little module is no longer available, however hopefully it was only the flash ROM that was at fault. Being a Panasonic agent, our technical officer told us we could either replace the 8M-Flash ROM IC1102 (marked TV RJ646-4 on a white label), or he could come around and upgrade the firmware. We settled on the latter. The firm­ ware upgrade deletes the flash settings (which are the non-specific model information such as aspect ratio, progressive scan, SD/HD options, etc) and then reloads the default values. The geometry and convergence settings and levels are kept in the EEPROM. Anyway, to do this, the set has to be put in the service mode and a special interface from a notebook computer connected to composite video inputs AV2 and AV4 on the rear of the set. To get the set ready, we had to perform a number of functions blind as we had no on-screen display. After switching the set on, the SETUP mode has to be selected on the remote control and the OFF TIMER set ON to 15 minutes. You then exit SETUP and press FUNCTION on the TV. Finally, you press and hold VOL- on the TV and RECALL on the remote, then press STR (store) on the remote until you can hear the relay click in. This relay switch­ es the AV2 and AV4 inputs to allow serial DATA directly into the main microprocessor on the U Board. That done, we ran the upgrade utility on the computer which at least tells you what’s going on. This took about five minutes, after which we switched the set off and then on again. It came back on with a perfect picture and sound, so the upgrade fixed the problem – well, nearly. Ten minutes later, the picture began tearing again but we audibly traced this back to the flyback transformer which was intermittent and probably the cause of the whole problem. A new one finally fixed it. A cow of a fault Sometimes you just can’t do anything right! Dave, our ace audio technician, had a cow of a fault just the other day. He was given a 1994 Pioneer VSXD503S 110W surround sound AV receiver with an intermittent crackle in the left channel to repair. Now, our Dave is normally a very cautious sort of guy but he reckoned he knew what the fault was straight away. In particular, he suspected the differential input transistor pair Q01 & Q03 in the power amplifier stage. After all, the fault was independent of the volume control setting, which ruled out the preamp stages. Being a caring type, he usually uses a cotton bud which he sprays with freezer and then just touches the suspect component. However, on this occasion, he must have been having a bad hair day – not that he has much left! Anyway, he hit the transistors directly with the freezer. Well, oops – output transistors Q1 and Q3 lost their bottle and failed instantly. He replaced them and the differential input transistors and when he switched it back on, it was fixed. However, when he turned it off and then back on again, it wouldn’t come on. Would you believe that the microprocessor had failed? Apparently, this can happen due to transient pulses when the power transistors fail. Data was going in but nothing was coming out. And so a new IC801 costing in excess of $200 was back-ordered (ETA four weeks). When it finally came, Dave fitted it but now found that the protection circuit was cutting in. After spending yet more time, he found that Q608 was short circuit but the set still refused to fire up after it was replaced. However, he could turn it on by shorting Q604’s base to its emitter. Feeling somewhat cheesed off by now, Dave replaced Q602, Q603, Q604, Q605, Q606 and Q608 to save time and switched on again. However, it wasn’t siliconchip.com.au Dave’s day – or even his fortnight! The sound was OK at low volume but at high volume, was distorted in the left channel. He checked this with the CRO and after a lot more time than he would care to admit, he located the little !<at>#$% – it was R525, a 100W resistor which had gone high. This finally fixed the last problem. The annoying thing was that these were all unrelated different faults, occurring one after the other. I guess the good thing was that at least they happened while he was still fixing it – it would have been much more difficult had they failed during the warranty period. No wonder the poor bloke is losing his hair! The next story comes from a mate who works in the automotive industry. I’ll let him tell it in his own words. Lost the PIN? One of the most annoying features of modern car audio systems is the use of the “PIN” number. Actually, this is a tautology – it really is just “PIN” of course, otherwise you would have a “Personal Identification Number Number”. Anyway, there was a time in the 80s when the high-end model cars from some manufacturers were fitted with the very best audio technology. Some units were very elaborate affairs, with Dolby, 4-channel outputs, graphic equalisers, digital displays and more buttons than the control console on the Space Shuttle. Remember, this was 20 years ago! Problem was, because they were so good, they attracted low-life car thieves with amazing regularity. The security systems on cars back then were almost non-existent and most vehicles could be entered using a comb or a piece of plastic tie-strap. And quite often, the thieves did more damage to the car, especially to the dash facia, while removing the audio gear than the gear itself was worth. In many cases, the gear was literally hacked (or even chopped) out. To prevent this, the manufacturers introduced the idea of a security PIN for their top-line audio units. This was very effective – as soon as the 12V (memory) supply was removed, the unit was transformed into an expensive paperweight – unless you had the PIN, that is. If you didn’t know the PIN, it was impossible to get the unit working again. This proved very effective and dramatically reduced the theft of high-end car audio equipment almost overnight. As a result, all the makers jumped on the same bandwagon and PIN systems are now used on even the most basic audio system head units. This and the fact that good-quality new systems can be had for a portion of one week’s wages have made car audio theft a redundant industry. Anyway, this is all background to a problem faced by the writer following the purchase of a secondhand car, a Daewoo Nubira wagon. The car itself suits our situation perfectly – the right size, good performance, equipment, economy, etc – but most importantly of all, the purchase price was too good to pass up. The standard fare in the audio department was an indash AM/FM CD player but unfortunately, the PIN had been misplaced. The reason was quite simple – early siliconchip.com.au January 2006  55 Serviceman’s Log – continued than to justify their job status within their company! Anyway, the wiring was straightforward for the most part, with the speaker wiring arranged in four pairs utilising standard colours. Unfortunately, though, we ran into problems with the wiring format for the display dimming. In the original factory unit, display dimming is achieved with an earth return through a rheostat, with the 12V supplied by the same accessory supply rail that powers the unit. However, without access to the factory wiring schematics, the job was just too difficult. In the end, we had to do away with the dimming feature, as the new unit did not allow for this strange set-up. With the task now complete, we could sit back and admire both our handiwork and how well the new unit’s easy-to-read, large, green display almost perfectly matched the Daewoo’s instruments. All this for the princely sum of $150.00, including the plug adaptor kit. The stacker in the car’s life, the CD player gave up the ghost, during the warranty period, so an attempt was made to repair it. However, as with many such units nowadays, the necessary parts were either unavailable or too costly (or both), so a replacement factory unit was fitted and everyone was happy. Well not quite, the PIN was not recorded by either the dealer or the previous owner, so when we fitted a new battery several years later, we were greeted with deafening silence and the word “Code” flashing on the audio unit’s display. Unfortunately, despite a thorough search of the dealer’s records and other material, no PIN was to be found – a task made doubly difficult by the fact that the car was originally sold new in WA. So that was it – the existing unit was literally junk. The only solution was to buy a new head unit, an easy task I hear you say. Well, not so! We needed a new unit to not only receive AM & FM and play the occasional CD but also to suit the dashboard. It also had to be user-friendly. Many units have multi-coloured, hard-todecipher fluorescent displays and buttons so small that they cannot be read or easily pressed. The most common facia colour is 56  Silicon Chip now silver, whereas the most common look five years ago was black – not a good look. Without being too oldfashioned, it would also be nice to have a rotary volume knob and large easy-to-find controls for the major functions. Swapping, as I do, from car to car, it is quite often near impossible to turn some unfamiliar units on or off, or tune to a different radio station. To cut a long story short, a suitable unit (at a suitable price) was eventually found. The next step was the installation. Without going into detail, the dashmounting method was very well designed – much better than some of my previous setups where you had to be both a double-jointed contortionist and adept at plastic welding repairs in order to fit a simple car audio head unit. Wiring is another area where things have improved immensely with time. It’s now possible to purchase plug kits that are compatible with the dash harness plugs but some are so unique that they fit only one manufacturer’s models and then only from one particular year! It seems that some automotive designers go to great lengths to make otherwise simple tasks overly complex, perhaps for no other reason Being even more adventurous, we found that the maker of our new system also had available a magazinestyle 10-CD stacker that mated perfectly with it. This is where sadness enters our tale. We ordered the stacker but when it arrived, we found that its packing had been tampered with and that the transit screws were missing. The reason given for this by the retailer was that there weren’t many of these units left and this one had been “pre-tested”. What they didn’t tell us was that this unit did not pass the test – the CD stacker failed to “stack” or do anything else bar emit some very odd noises. We also found that the number of such units left in Australia was just one – this one! Anyway, we now look forward to a 6-week wait, while their “service department” investigates the matter. Why is it always a long wait when the item in question was needed yesterday as a surprise for Mrs Serviceman’s birthday? There’s no point investigating this in our own workshop, since we lack the necessary parts and service information – not to mention voiding the warranty. All we can do is wait and see what SC happens. siliconchip.com.au Ω PRODUCT SHOWCASE Low cost tower speakers from Dick Smith Electronics China is certainly causing drastic changes in consumer electronics items. Products that only recently cost hundreds of dollars are now available at a fraction of the old prices. These tower speakers from Dick Smith Electronics are a case in point at just $99 for the pair. When we first saw these speakers and the price, we thought, “Nah, can’t be any good”. Then we had a listen and have had to think again and the conclusion is that they are, in dinkum Aussie-speak: not bad at all! OK, so they will not put the local hifi speaker manufacturers out of business; far from it but they sound really quite good for average listening to music or as part of a low-cost home theatre system. The first clue as to how the cost has been kept down comes when you pick them up – the enclosures are very light at around 10.6kg each. Typical hifi speakers of the same height can easily be three or four times that figure, made up of a much heavier cabinet and heavy drivers. These tower speakers are made from what appears to be 12mm MDF (medium density fibreboard) finished in black vinyl simulated wood veneer. They have two 200mm woofers with roll surround and quite reasonably large ferrite magnets. The midrange driver is a closed-back nominal 4-inch unit, again with roll surround while the tweeter is a 1-inch dome unit. The cabinet is ported at the back and the gold-plated speaker terminals can take large speaker leads. Overall dimensions are 970mm high, 235mm wide and 235mm deep. Nominal impedance is 8W. siliconchip.com.au become quite evident if you turn up the wick. Overall efficiency is about average; on a par with the 90dB/1w/1m rating our reference speakers. We think the rating is a little ambitious though; coupled to a 100W per channel amplifier, they were clearly being over-driven at maximum unclipped powers. We would say they’re fine up to about 70W or so but don’t expect them to handle much more without being “found out”. In summary though, they are outstanding value for the money: well-finished and able to give a good account of themselves. They are available from all Dick Smith Electronics and Powerhouse stores at $99.94 for the pair (Cat. A-3099). Contact: Dick Smith Electronics (all stores) PO Box 500, Regents Park DC NSW 2143. Tel: 1300 366 644 Fax: (02) 9642 9155 Website: www.dse.com.au Frequency response is quoted as 48Hz to 20kHz, with no tolerance (dB) range, while power handling is rated at 20W to 120W. Finally, sensitivity is quoted at 88dB ±2dB, presumably at 1W and with the microphone at 1 metre. We set the speakers up next to our reference hifi speakers (costing many thousands of dollars – not a fair test really) for a general listening test. Our first reaction was that they sounded quite good on a variety of program material ranging from classic to rock. Overall frequency balance was good and the response over the whole range was commendably smooth, with the qualifying remark that those thin panels do have a number of resonances which AUDIO MODULES broadcast quality Manufactured in Australia Harbuch Electronics Pty Ltd 9/40 Leighton Pl. HORNSBY 2077 Ph (02) 9476-5854 Fx (02) 9476-3231 January 2006  65 SpacePort Evaluation Board from RF Modules The Radiometrix Spaceport Modem Evaluation Kit, available in Australia & NZ from RF Modules Australia, enables SPM/RFM to be transformed into a complete radio modem with direct interface to an RS232 serial port. Setup and configuration uses HyperTerminal, which also gives access to internal diagnostic/test modes. Each data and control pin is accessible for external interface or testing. An on-board regulator can supply 5V <at> 1A to power up DTE. More information on this, and all Radiometrix products from RF Modules, is available from their website. Contact: RF Modules Australia PO Box 1957, Launceston Tas 7250 Tel: (03) 6331 6789 Fax: (03) 6331 1243 Website: www.rfmodules.com.au Jaycar’s trio of Weather Stations Is it going to rain on your sporting event, picnic or BBQ? Should you wear a jacket or a T-shirt to the football? Should you water your garden before you go away for the weekend or is it going to rain? These and many more questions will be answered for you with one of Jaycar Electronics’ Weather Stations. Charting and monitoring the weather is a great project to undertake with the grandchildren, or a healthy and educative school holiday pastime. This is a fantastic way to take an interest in the local environment and learn more about the natural world. First of the three Jaycar Weather Stations is a stand-alone unit which monitors inside and outside temperature, air pressure, rainfall, humidity, wind speed, wind direction and wind chill factor. The forecast is displayed on the system’s screen in an icon style and the barometric pressure trend is displayed as a bar graph so you can see at a glance how fast the pressure is rising or falling. It has a recommended retail price of $249.00 (XC-0293) The other two models are designed to be connected to a computer (one wirelessly). They include software which will enable you to keep accurate records, almost without limit. The top-of-the-range model has an LCD touch screen. These two models have recommended retail prices of $399 (XC-0291) and $499 (XC-0292) For more information, visit any Jaycar Electronics store or their website. Contact: Jaycar Electronics PO Box 6424, Silverwater NSW 1811. Tel: 1800 022 888 Fax: (02) 9741 8500 Website: www.jaycar.com.au Educational/commercial software from 555 Whether you are looking for electronics-related software for education, for commercial applications or for hobbyist use, there’s certain to be something for you in the “New Wave Concepts” range from 555Electronics. And the best part is that they are priced way under what many other packages cost – yet lose nothing in either application, ease of use or features. The “flagship” product is Circuit Wizard, combining cicuit design, PC board design, simulations (based on Berkeley SPICE) and CAD/CAM manu- facture in one complete package. If you wish, Circuit Wizard will create your PC board pattern for you automatically from the circuits you have designed and simulated! Other packages in the range include Bright Spark (theory teaching software which combines on-screen animation with realistic simulation); Control Studio 2 (systems modelling software); Livewire (a powerful package for designing and simulating circuits); and PCB Wizard 3.5, an ultrafriendly PC board design package. One of the biggest advantages of the range is that, once purchased, updates are free during the typical life cycle of 3-5 years (there is no annual fee). Contact: 555 Electronics 15 Field St. McLaren Vale, SA 5171. Tel: (08) 0323 8442 Fax: (08) 8323 0033 Website: www.555electronics.com.au SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCspecialise WEBLINK in SCproviding WEBLINK SC WEBLINK WEBLINK WEBLINK SC WEBLINK JEDSCdesigns andSCmanufactures a range ofSC WEBLINK We a range of SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK single board computers (based on WilkeSC WEBLINK LowSC Power Radio to SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SCsolutions WEBLINKfor SCOEM’s WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SC WEBLINK SCAVR), WEBLINK SC WEBLINK Tiger and Atmel as well as LCD SC WEBLINK incorporate in their wireless SC technology SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK displays and analog and digital I/O for based products.SCThe innovative range SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK PCsSC and controllers. JED also a PC SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SCmakes WEBLINK SC WEBLINK includes products from MK Consultants, theSC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK PROM programmer and RS232/RS485 world-renowned specialist manufacturer. SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK converters. SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK Tel:(07) 4934 0413 Fax: (07) 0311 Tel: (03) 9762 3588 Fax: (03) 9762 5499 SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC4934 WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK ilicon hip SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SILICON CHIP WebLINK Want your product or service featured both here and on the SILICON CHIP website for the one low price? Contact Phil Benedictus or Lawrence Smith on (02) 9211 9792 for all the details! 66  S C TeleLink Communications Jed Microprocessors Pty Ltd WebLINK: telelink.com.au WebLINK: jedmicro.com.au siliconchip.com.au SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC Altronics Melbourne new paint job . . . PICAXE goes colour! Altronics Melbourne store has been open for a few months now but they were so tickled pink about their newly painted exterior they asked us if we could show everyone who reads SILICON CHIP as well . . . Contact: Altronics (Melbourne) 891 Princes Hwy, Springvale Order Hotline: 1300 797007 Website: www.altronics.com.au Users of the popular PICAXE Programming Editor software will be interested to know that the latest version automatically ‘colour codes’ your BASIC programs as it is typed! This makes it much clearer when you have, for instance, typed a correct command as the individual word will change colour instantly. Descriptive ‘comments’ are also coloured to clearly distinguish them from actual commands. Other new features include drag & drop editing, automatic indentation for neat program layouts, line number display, and an optional ‘split-screen’ view to look at two different parts of a program simultaneously. The new software also features a line number ‘bookmark’ feature - simply right-click to add a ‘bookmark’ to any line. You can then very quickly jump directly back to this bookmark at any time - very useful when working with long files. The software update is available to download free of charge from the software page at www.picaxe.co.uk $60+ off AV Sender – just for joining Radio Parts’ Free VIP Club! Elsewhere in this issue is an invitation from Radio Parts Group to become a VIP member. Membership is free and members are entited to discounted products in the entire product range. An excellent example of the VIP Member’s discount is this very high spec AVS500 /DOSS 2.4GHz Multisource Wireless AV Sender. Normal retail price is $188.72; VIP Member’s price is just $125.81. With the Multi-Source capabilities of the AVS500, you can watch your cable TV in your living room and a DVD movie in your bedroom. Line-ofsight range is said to be up to 100m. The dedicated remote control allows you to change the source with the push of the button. Infrared remote range is up to 40m line-of-sight. There are four AV-in sources and two AV-out connections. Other features include: • Built-in RF modulator on receiver [connect to your TVs aerial terminal] • 4 selectable channels • 4x independent inputs • 2x outputs • 2x IR remote controls • Built-in remote extender Setup and operation are said to be extremely easy. Radio Parts will list all VIP Member’s prices (as well as recommended retail) in their advertising. Contact: Radio Parts Group 562 Spencer St, Melbourne Vic 3001. Tel: (03) 9321 8300 Fax: (03) 9321 8333 Website: www.radioparts.com.au C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK We supply Radiometrix & UHF radio SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC VHF WEBLINK SCOEM WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCFor WEBLINK SC WEBLINK WEBLINK WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK WEBLINK everything in radioSCcontrol forSC aircraft, modulesSC forWEBLINK wireless SC data comms,SC control and SC WEBLINK Our website is updated daily, with over C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK monitoring. We also stock low cost easy to model boats and planes, etc. We also carry 5,500SC products available through our C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK use Bluetooth modules and the new rfBASIC SC WEBLINK extensive range of model flight SC control C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCan WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK secure online ordering facility. C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCmodules WEBLINKincluding SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK programmable radio SC modules as well as other SC WEBLINK GPS, altitude and speed, SC WEBLINK Features include semiconductor data C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK RF accesssories. autopilot and sheets, media releases, software C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCinterfaces, WEBLINK SC WEBLINK SC groundstation WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCcontrollers. WEBLINK SCMore WEBLINK SC WEBLINK SC WEBLINKdownloads, SC WEBLINKand SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK infoSC onWEBLINK our website! Radiometrix - Engineers preferredSCchoice for SC WEBLINK much more C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK VHF SC & UHF Low Power Radio SC Modules C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK Tel: 1800SC022 888 SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SCTel:(07) WEBLINK4639 SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK 1100 Fax: (07)4639 1275 SC WEBLINK SC WEBLINK Tel: 1800 888 SC WEBLINK SC WEBLINK Tel/Fax: (02)SC 9533 3517SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK WEBLINK SC WEBLINK SC WEBLINK SC022 WEBLINK SC WEBLINK SC WEBLINK WEBLINK Tel: (03) 6331 6789 Fax: (03) SC 6331 1243 SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK anuary C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK C WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK SC WEBLINK siliconchip.com.au Silvertone Silvertone Electronics Electronics JAYCAR JAYCAR ELECTRONICS ELECTRONICS RF Modules Australia WebLINK: www.silvertone.com.au WebLINK: silvertone.com.au WebLINK: WebLINK: www.jaycar.com.au www.jaycar.com.au WebLINK: www.rfmodules.com.au J 2006  67 SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC SC High-Energy Electronic Ignition System; Pt.2 Six Versions To Build To Suit Your Car’s Trigger Input! Pt.2: By JOHN CLARKE Last month, we introduced our new HighEnergy Electronic Ignition System and gave the circuit details. This month, we give the assembly details and describe how to convert a points distributor to Hall effect pickup. T HE ELECTRONIC IGNITION is constructed on a PC board that measures 102 x 81mm and is coded 05112051. It is housed in a diecast metal box measuring 119 x 93 x 57mm. Before installing the parts, check the PC board against the published patterns and make sure that all the holes 68  Silicon Chip have been drilled. There should not be any shorts or breaks in the copper tracks. Make repairs if necessary. Depending on the type of trigger input, there are six different component layouts for the PC board – choose the one that is applicable to your car’s trigger sensor. For example, if your car has reluctor distributor, follow the component layout of Fig.9. If it has a Hall Effect device or Lumenition distributor (same thing), use the layout of Fig.10. Starting construction Start construction by installing PC stakes at the external wiring points and also insert and solder in the links. The three linking options use 3-way pin headers that are soldered in place. Next, install the resistors, using your multimeter to measure the values. The zener diodes can go in next. Be sure to install them with the correct orientation. Similarly, make sure that IC1’s socket is oriented correctly. Don’t insert the IC at this stage, however. siliconchip.com.au Fig.9: follow this parts layout diagram if your car’s distributor has a reluctor pickup. Fig.10: this is the layout to follow if the distributor uses a Hall Effect device or a Lumenition module. Take care with component orientation during assembly. The transistors are next on the list. Again, make sure they are oriented correctly. Q1 is mounted at full lead length, with its metal flange toward the edge of the PC board. siliconchip.com.au The capacitors can be installed next. Each electrolytic type must be installed with the polarity indicated. That done, install the crystal and trimpot(s). Once the board assembly is complete, position it in the case and mark out the four mounting holes. That done, remove the PC board and drill the mounting holes to 3mm. Deburr January 2006  69 Fig.11: this is the points version. Secure the 100W 5W resistors to the board using silicone, to prevent them from vibrating and fracturing their leads and/or the solder joints. Fig.12: the engine management trigger version requires no additional input conditioning circuitry. In this case, the ECU trigger signal goes straight to pin 6 of IC1 via a 2.2kW resistor. each hole using an oversize drill bit, then fit a 9mm standoff to each mounting position with an M3 x 15mm screw passing through it from outside the 70  Silicon Chip case. The PC board is then fitted in place and temporarily secured using M3 washers and nuts. That done, mark out the position for Q1’s mounting hole, the earth connection on the side of the case and the cordgrip grommets at each end of the case, then remove the board siliconchip.com.au Fig.13: build this version if your distributor has been fitted with a Crane optical pickup. Fig.14: the Piranha optical pickup version is similar to the Crane version but note the different locations for the 22kW and 120W resistors. and drill these holes. Note that the cordgrip grommets need elongated holes and these can be shaped using a rat-tailed file. siliconchip.com.au The inside of the mounting hole for Q1 must be carefully deburred to remove any sharp edges that may puncture the insulating washer. A large diameter drill can be used by hand to do this. That done, you can then install the PC board and secure it using the star washers and nuts. January 2006  71 Converting From Points To A Hall Effect Sensor You can replace your existing points with a Hall Effect sensor – but be warned, it takes quite a lot of precision work! All the details are shown in Fig.12. First, rotate your engine so that the rotor button in the distributor is facing the high-tension outlet for cylinder number 1. Also note the direction that the rotor button moves when the engine is turned in its correct direction. Set the timing mark on the flywheel to the number of degrees before Top Dead Centre specified in the workshop manual and indicated by the engine block timing marks. Now place a mark on the edge of the distributor body to show where the timing mark on the rotor button arm is positioned. This sets the alignment for the Hall Effect modification. The distributor can now be removed from the engine. The Hall Effect sensor is designed to be used with a rotating vane that passes through the gap incorporated in its housing. The Hall sensor is mounted on the distributor advance plate and secured using the rivets incorporated on its housing. The rotating vane needs to be made so that it spins with the distributor shaft The rotor button assembly fits over the distributor’s camshaft, with the vanes passing through the Hall Effect sensor. and its vanes pass through the sensor gap. For this to happen, the rotating vane needs to be cup-shaped. The horizontal face has a hole to allow it to be placed on the distributor shaft and locate with the rotor button. The vertical section needs to have slots cut in it to appropriately trigger the sensor. The number of slots on the vane equals the number of spark-plugs for which the distributor caters. So a 4-cylinder car with four spark plugs will use four slots. These slots need to be evenly spaced around the circumference of the rotating vane. It is essential to be accurate here, as a 1° difference between slots represents 2° on the engine. A 4-cylinder engine will have each slot positioned 90° apart. 6-cyclinder and V8 cars will require slots spaced 60° and 45° apart, respectively. Making The Disk Making the disk is easier if you can start off with something that is already preformed. We used the tinplated backing from a high power potentiometer. A suitable one is the Jaycar RP-3975 15W potentiometer. This photo shows how the slotted Hall Effect sensor is rivetted to the vacuum advance plate inside the distributor. This provides us with a cup that is 40mm in diameter. All that is required is to drill out a hole in the top for the distributor shaft and cut the slots in the side. Mounting The Sensor When this has been done, the Hall sensor can be mounted on the distributor advance plate. The sensor needs to be located so that the centre of its slot is 20mm away from the centre of the distributor shaft. This will allow the 40mm diameter cup to spin without fouling the Hall sensor. Drill the two holes in the distributor advance plate and countersink the holes on the underside of the plate. This will allow space for the rivets in the Hall sensor to be peened over. Before riveting, check that the Hall Effect wires do not foul against the points cam (this happened in the distributor we were modifying!). To prevent this, the wires were passed under the Hall sensor by filing a small channel beneath the sensor, so that the wires could be fed through to the other side. The wires were then fed through a grommet in the distributor’s body. Rotating Vane The rotating vane should be placed over the distributor shaft and should sit on the top of the points camshaft. Check that there is sufficient clearance between the vanes and Hall sensor gap. If the cup needs to be higher than this, it can be placed over the rotor button shaft. In this case, the rotating vane must be electrically connected to the dis72  Silicon Chip siliconchip.com.au Fig.15: these diagrams and the accompanying photos show how to replace the points with a Hall Effect sensor and make the rotating vane assembly. Note that the slots in the vane must be accurately positioned – see text. tributor shaft to prevent static build up which may damage the Hall sensor. A small piece of tinplate soldered to the vane and bent so it passes up inside the rotor button to make contact with the distributor shaft is suitable. When the Hall Effect sensor has been mounted, place the rotating cup over the distributor shaft and hold it in place with the rotor button. Check that the vane spins freely through the Hall sensor slot. Now you are ready to align the disk. Rotate the rotor button to the alignment marks set previously. Remember, these indicate the centre position of the rotor button at Number 1 cylinder timing. Move the rotating siliconchip.com.au vane relative to the rotor button so that the gap is just leaving the centre of the Hall Effect sensor. Note that you must be turning the distributor in the direction that it travels when installed in the car. Mark the position on the rotating vane and rotor button using a marking pen (do not use a scriber on the rotor button or the high tension voltage may travel down this). We soldered in a couple of PC stakes inserted into holes drilled in the top of the vane, to align the vane position – these keyed into the locating slot in the rotor button. Gluing The Vane Finally, the rotating vane can be glued to the bottom of the rotor button using high-temperature epoxy resin. We used JB Weld epoxy steel resin, a 2-part epoxy. This is suitable for temperatures of up to 260°C. The quick-setting version can be used for temperatrures up to 150°C. January 2006  73 Fig.16: the metal tab of the Darlington transistor (Q1) must be insulated from the case using an insulating washer and bush. After mounting, use a multi­meter (set to a low ohms range) to confirm that the tab is properly isolated – ie, it must not be shorted to the case. Above: once your unit has been assembled, secure the wiring connections using blobs of silicone, to prevent breakages at the PC stakes. The 5W resistor(s) should also be secured using silicone, as can the LK1-LK3 pin headers (once you’ve selected the desired options). Cable ties should also help secure the leads, both inside and outside the case. Table 2: Capacitor Codes Value 100nF 10nF 1nF 2.2nF 470pF 33pF μF Code 0.1µF .01µF .001µF .0022µF   NA   NA EIA Code IEC Code   104 100nF   103 10nF   102 1nF   222 2n2   471 470p    33 33p The Darlington power transistor Q1 is secured to the case with an insulating bush and washer as shown in Fig.16. Next, attach the leads required for power, coil and input triggers. Note that the coil wire is the only wire passing through the end cord-grip grommet. The remaining wires pass through the other grommet (ignore the photos) – see Fig.17. The earth connection from the PC board goes to an eyelet lug that is secured using a screw, nut and two star washers, as shown in Fig.17. The various leads should all be secured using cable ties, along with beads of silicone at the solder stakes. This is necessary to prevent the leads from vibrating and coming adrift. Similarly, use silicone to secure the 5W resistor(s) to the PC board. Finally, install the links for LK1, Table 1: Resistor Colour Codes o o o o o o o o o o o No.   1   3   1   2   2   1   1   1   1   1 74  Silicon Chip Value 100kW 47kW 22kW 10kW 2.2kW 1.8kW 1kW 470W 120W 100W 4-Band Code (1%) brown black yellow brown yellow violet orange brown red red orange brown brown black orange brown red red red brown brown grey red brown brown black red brown yellow violet brown brown brown red brown brown brown black brown brown 5-Band Code (1%) brown black black orange brown yellow violet black red brown red red black red brown brown black black red brown red red black brown brown brown grey black brown brown brown black black brown brown yellow violet black black brown brown red black black brown brown black black black brown siliconchip.com.au Fig.17: this diagram shows the final assembly and external wiring details for the unit. Note how the 0V (ground) rail on the PC board is connected to one side of the case, with a lead then run from this point to the vehicle’s chassis. LK2 and LK3. Initially, you can place these in the standard, 0.5ms debounce and normal positions, respectively. Installation The Electronic Ignition box goes in your car’s engine bay, on the same side as the distributor. Make sure that the box is shielded from the heat of the exhaust manifold or catalytic converter (the internal components are rated to a maximum temperature of 125°C). Use brackets and screws to secure the box to the chassis. That done, wire the positive supply lead to the +12V ignition supply, the negative earth lead to the car’s chassis and the inputs to the trigger unit. Do not connect to the coil negative yet, however. Next, set VR1 fully anti-clockwise, then switch on the ignition and check that there is 5V between pins 5 & 14 on the IC socket. If this is correct, switch the ignition off and install IC1. Make sure that it is oriented correctly, with its notch matching the notch at one end of the socket. If you do this incorrectly, siliconchip.com.au you will blow the chip. Now connect your meter between the 0V PC stake near VR1 and the TP1 PC stake. Switch on and adjust VR1 for a reading of about 4V. This should set the dwell at around 6ms. Reluctor settings If you are using the reluctor circuit, adjust VR2 fully clockwise and measure the voltage at pin 6 of IC1. If the voltage is close to 0V, wind VR2 anti-clockwise several turns until the voltage goes to 5V. That done, wind it about two turns more anti-clockwise and leave VR2 at this setting. If the voltage is 5V when VR2 is fully clockwise, rotate VR2 fully anticlockwise and start to wind it clockwise until the voltage goes to 5V again. Then wind it two more turns clockwise. That done, switch off the ignition and connect Q1’s collector wire to the ignition coil’s negative. Starting Now try to start the engine. If it Darlington transistor Q1 is secured to the case using an M3 screw and nut. Make sure its tab is correctly isolated from the case metal – see Fig.16 doesn’t want to start, the sensor signal may be inverted. This can happen with Hall Effect sensors and optical sensors if the output voltage goes low at the point of firing. In this case, change link LK1 to the “invert” position. The reluctor circuit is designed to fire the coil when its output voltage swings negative. If the engine doesn’t start and you are using a reluctor, try swapping the reluctor connections. If you are using points and the engine does not run smoothly, try the 2ms debounce link setting. If the engine is January 2006  75 This is the view inside the prototype (reluctor version shown). Be sure to build it for good reliability by securing all leads and using star lockwashers at the positions indicated in the diagrams. still erratic, change to the points mode using LK3. Dwell adjust The amount of dwell required depends on the ignition coil used in your vehicle. To adjust this, set your multimeter to DC volts and connect the probes between the chassis and the negative terminal on the coil. Danger: you must use a multimeter Corrections There are several errors in the parts list published in Pt.1. In the main section, there should be three (not two) 100mF capacitors, the LM2940CT-5 regulator should be designated REG1 and there should be three (not two) crimp eyelets. In addition, the 22W resistor listed under the “Optical Pickup Version” heading should in fact be 22kW. rated for at least 300V and take great care not to make contact with the negative terminal of the coil! Set the idle so that the engine runs smoothly and adjust VR1 anti-clockwise until the engine begins to falter or until the voltage reading shown on the meter drops. Now slowly turn VR1 clockwise until the voltage rises and then remains at the same voltage, even though the dwell is increased slightly. Stop turning the trimpot at this voltage plateau. This setting provides the optimum dwell for your coil. If you wish, you can in fact set the dwell to a slightly greater value than this, to cater for resistance changes at the coil connections due to varying temperatures. So what did adjusting the pot act­ual­ ly do? What we are doing is measuring the average primary coil voltage. When the coil is charging, the voltage will Where To Buy Programmed PICs The programming code (ignition.hex) for the PIC16F88-E/P microcontroller used in this project will not be released or be made available on our website. Authorised kitsellers will supply pro­grammed micros as part of their kits. For people who do not wish to build the project from a kit, programmed micros will be available from SILICON CHIP for $25.00 including postage anywhere within Australia, or $30.00 by airmail elsewhere. 76  Silicon Chip be about 1.5V due to the drop across the ignition transistor (Q1). When the transistor switches off, there is a high voltage produced that is limited by the zener diodes to 300V. After the coil has discharged, the voltage will be at about 12V (or the battery supply) until transistor Q1 again switches on to recharge the coil. The coil will deliver its full energy if the dwell period is set so that the coil can charge fully. At this point, the average measured voltage will be at its highest. Increasing the dwell time further will not increase the coil’s energy but it may decrease the average measured voltage. This is because the extra dwell will have the coil negative terminal at 1.5V for longer, thus reducing the average measured voltage. Setting more dwell time than necessary will only heat up the coil without improving spark energy. Once the ignition is set up and running well, fit the lid onto the box. Conclusion Depending on the car to which you’re fitting the electronic ignition system, you can expect reduced points wear, a stronger spark, a cooler running coil and slightly better fuel economy and power. And that’s pretty darn good SC for the money and time spent! siliconchip.com.au PC Oscilloscopes & Analyzers Get the full picture with BitScope Mixed Signal Oscilloscopes 100MHz Digital Oscilloscope  Dual Channel Digital Scope using industry standard BNC probes or analog inputs on the POD. 40MS/s Logic Analyzer  8 logic, External Trigger and special purpose inputs to capture digital signals down to 25nS. Mixed Signal Oscilloscope  True MSO to capture analog waveforms time-aligned with logic using sophisticated cross-triggering on any input. Turn your PC into a powerful Digital Storage Oscilloscope! 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BitScope Smart POD probe connector 8 logic channels, cross-triggering Dual channel analog inputs Async serial I/O for external control Supports active probes USB 2.0 or Ethernet Connectivity Single cable to PC or switch Compressed data transmission Ethernet option uses UDP/IP Internet addressable device Expandable and Programmable Simple ASCII Protocol BitScope Scripting Language Add active probes and devices Supplies up to 500mA via POD BitScope DSO software for Windows and Linux BitScope's integrated design uses standard oscilloscope probes and a growing range of custom probes to provide functionality equal to instruments many times the price. BitScope plugs into third party software tools and has an open API for user programming and custom data acquisition. BitScope Designs siliconchip.com.au Ph: (02) 9436 2955 Fax: (02) 9436 3764 www.bitscope.com January 2006  77 Building the ULTIMATE Last month we looked at what we wanted in the Ultimate Jukebox. Now let’s start building it . . . A s we explained, the Ultimate Jukebox is actually a powered speaker with a built-in computer running the Ultimate Jukebox software. So all we need to do is come up with a speaker box that will fit an amplifier/power supply and the computer? That’s true – but as the proverb says, there’s many a slip twixt cup and lip. For example, we want to make sure our jukebox makes the most economic use of timber. It also needs to be both stable and sturdy enough to take the punishment of its likely environment (let’s party!) and it needs to be light enough to move around. Those last two requirements are actually rather contradictory. To make it stable and sturdy, it needs to be quite heavy duty. Heavy duty also translates as heavy! The final design had over 32kg of timber in it – before anything was added. We decided on 18mm craftwood (or MDF) for most of the construction. Part of the reason for this is our local timber merchant had a special on 18mm craftwood but we had already decided anything thinner would be too thin while anything thicker would be too heavy. Having said that, we also used a couple of pieces of 32mm craftwood – one for the jukebox base and one for the computer spacer. More on this anon. We used two sheets of 1200 x 2500mm 18mm craftwood (as I said, they were cheap!) but one sheet of 2400 x 1200mm will work quite nicely with the sizes we’ve shown – and leave 78  Silicon Chip some change. It’s also possible to buy 1200 x 1200mm sheets which are easier to work with (and transport). Also, ask your timber supplier if they offer a cutting service. If they do, take advantage of it: their cuts are likely to be smoother and squarer than yours (certainly squarer than mine!) and you’ll end up with pieces that fit together beautifully. Even if they charge for the cuts (and most do, with the average charge about $2.00 per cut plus GST), you’re going to pay not much more than about $15 for cuts – pretty good value in my humble opinion. Changes since last month The Ultimate Jukebox has been a work-in-progress for many months – right up until this issue went to press. One thing we did find was that some notebook computers have more output than others – indeed, some cannot fully drive the SC480 amplifier. To solve this little problem, we added a little (and cheap!) preamplifier into the signal line. Again, we used an existing design, the PreCHAMP from SILICON CHIP July 1994 issue. We made a slight adjustment to allow it to run from the +15V supply we already had on the power supply board and we also throttled the gain back somewhat – as originally published, it was simply too much. Kits for this preamp are still available – in fact, it’s a very popular little kit and one to keep in mind if you ever need a general-purpose preamp. Best of all, it sells for just $6.95. Another change we made was in the port, or vent – and we’ll explain this in just a moment. And finally, we thought that the box lacked something that the “real thing” would have – flashing coloured lights. So we took the easy way out and got some ropelight: presto, instant flashing coloured lights! The speaker “box” While the Ultimate Jukebox is all one piece, it’s possibly a bit easier to look at it as three components. We’ll start with the speaker enclosure. This is a vented (ported) type with an internal measurement of 600 x 440 x 321mm. That gives it a volume of around 84.5 litres; slightly larger than our “Bass Box” calculations dictated but this can be taken care of by adjusting the port size. The reason for this larger size, by the way, was twofold: the extra space is basically width and depth, giving better stability, and the dimensions chosen make for the minimum number of cuts in a standard 1200mm craftwood sheet or sheets. The front, or baffle, is inset 18mm in from the front edge to give some measure of protection to the speaker drivers, even though the woofer is later covered with a metal grille. The baffle slides into a 5mm rebate routed into both sides and the base before the speaker top and notebook spacer are placed. The woofer mounts on the rear of the baffle while the compression horn tweeter mounts from the front, in a siliconchip.com.au JUKEBOX Part 2 by Ross Tester suitably sized rebate (sizes are shown on the cutting diagrams). Screwed to the inside of the enclosure is the crossover, with wiring secured to the timber with electrical staples or cable clamps. Don’t be tempted to use ordinary staples because they have this nasty little habit of cutting straight through wiring insulation! Small holes are drilled through the top and bottom of the enclosure to enable cabling to pass through: power to, and audio from, the laptop and of course the output from amplifier to speakers. When the cables are installed, the holes are made airtight with silicon sealant or similar. The two sides are mirror-image and are 1200 x 375mm. The top of the sides was shaped with a jigsaw into a curve to give a less stark (boxy) appearance. Three 5mm rebates are cut into the sides – these house the bottom (32mm rebate), enclosure bottom (18mm) and finally a 50mm rebate for the enclosure top and notebook spacer. Larger port The 900mm x 450mm back of the speaker also mounts into 18mm rebates in the sides and is the last piece of timber placed. It doesn’t cover the entire back of the Jukebox because we left a 50mm air gap in the bottom to act as the port. This is significantly larger than Bass Box suggested would be optimum for the woofer we used but trial and (ear)or said that we ended up with the best sound. Most jukebox users (ie, party goers!) want thumping bass and this large horizontal back-panel port gave us a great sound – far better than tuning for a flat response. Similarly to the sides, a rebate is cut siliconchip.com.au January 2006  79 into the back to house the enclosure top and the notebook spacer. The amplifier enclosure The amplifier “enclosure” at the bottom of the Jukebox contains the amplifier, power supply and notebook/ laptop power supply, along with the fused IEC mains inlet, on/off switch and USB disk drive. There is no covering over the amplifier section; the back is open to the air for cooling. It is significantly larger than necessary – our amplifier heatsink is only 80mm high and we’ve made the space 200mm high. The reason (and also the reason for being open to the back) is for ventilation/air circulation – while the amplifier heatsink itself is mounted right at the rear, there is still the transformer giving off heat, not to mention the notebook/laptop power supply which also generates heat. Also, we said last month that the jukebox was capable of handling a much larger amplifier, so if you want to go this route there is plenty of space to do so. We mounted our amplifier and power supplies on an aluminium “tray” for ease of assembly (and later service if needed). you may need to make the well a little deeper. Conversely, some modern notebooks are very thin, so you might not need 32mm depth. The other consideration for the computer is heat. Notebooks are not designed to be operated in an enclosed space (hence making the well “U” shaped, allowing air to flow out the back). With the computer we used, the cooling fan is also at the rear, making a “best case” scenario. If you have trouble with heat, some form of forced air cooling may be necessary (you can buy notebook coolers which could be an answer, albeit at the cost of a deeper “well”). The notebook screen is designed to swing up against the back panel with enough angle to ensure that viewers of normal height don’t have to bend down to view it. That pretty well covers the various parts of the Ultimate Jukebox. We added a few “extras” which we’ll get to later (eg, the speaker carpet) but The notebook enclosure Above the speaker enclosure is the space for the notebook/laptop computer. Because we didn’t want to allow any access to the keyboard, this is set into a “well” made from a piece of 32mm craftwood, fixed to the outer surface of the speaker box top. Above this again is fixed a sheet of 2mm aluminium which completely covers the keyboard. The aluminium sheet has a cutout the width of the screen and a depth suitable to allow it to clear. We actually made ours slightly wider than necessary to give somewhat hidden access to the notebook’s power switch. This is something that you might not have to do if your noteboook’s BIOS will allow you to boot after power interruption. Then you can simply run the notebook without a battery and allow it to boot whenever the Jukebox is turned on at the mains. Each laptop/notebook computer will be slightly different and you need to decide if 32mm is enough height to clear the top of the keys – if not, 80  Silicon Chip This cutting diagram, to scale, shows how to get all the jukebox panels (the two 32mm thick pieces excepted!) from a 1200 x 2400 sheet with some left over for other projects. The numbers on the blue saws are the order of cuts (the red dotted lines) – you only need to make seven (plus, of course, the rounded tops which can be done later). If your timber merchant offers a cutting service (about $2.20 per cut at most places), we reckon that’s $15 well spent! siliconchip.com.au now we move on to assembly. Putting it together If you’ve taken our advice and had the pieces sawn by the supplier, you’re going to have an easy assembly. If not, and your cuts aren’t quite true or perhaps not quite even, it’s going to be a bit more difficult. We found the fit was so good as we assembled the pieces that we didn’t even need to cramp the box together as it was glued’n’screwed. Even the rebates (which I will admit I had never done before) came up a treat! Start by cutting the rounded corners on the top of the sides. We simply used a garbage tin lid to get the curve and then cut them with a jigsaw. A bit of rough sanding removed any blade marks – fine sanding isn’t necessary. As long as the curve is true, don’t worry too much about getting it absolutely smooth. We’re going to cover the box with speaker carpet later and this hides a multitude of “oopses!”. (Trust me – I made some). The carpet also hides the majority of the screws used in construction. The next step, rebating, is probably the most important because it will determine just how well the box fits together. We used a router with a 19mm blade (we couldn’t buy an 18mm but the extra millimetre doesn’t really matter) and first cut the rebates which went from front to back on the sides (three each side). Of course, the 32mm and 50mm rebates require more than one cut; the 50mm rebate needs two outside cuts then the “meat” removed from the middle. If it is at all possible, the sides should be clamped side-by-side and the rebates cut across both pieces in one action. That way, you know they are going to line up. With these cut, we were able to get the right places for the vertical rebates on the sides. The front rebate is inset 18mm while the rear is right on the back. Remember that neither of these rebates goes from top to bottom – the front rebate goes from bottom up to the 50mm horizontal rebate; the back rebate goes from the top down to the 18mm rebate. A 5mm x 18mm rebate also needs to be cut across the front of the base to match the rebates on the sides (ie, inset 18mm). Because the back panel doesn’t come down to the base, no rebate is necessary there. siliconchip.com.au And here’s how all those cut-out bits fit together. Compare this drawing with the pics overleaf . . . While you’re in the rebate mood, you might as well cut the two holes for the speaker drivers in the baffle. We used the router mounted on a home-made jig to cut the 280mm circular hole for the woofer and a jig saw to cut the 115 x 160mm hole for the compression driver. We then used the router once more to cut a rebate in the front side of the baffle for the compression driver so its front finished flush with the baffle front. If you think this is a bit of overkill, don’t worry about doing it – there won’t be any difference in performance one way or the other. It makes sense at this point to mark and drill the eight holes for the woofer and six holes for the tweeter. The woofer has 4mm holes which go right through the baffle (it’s held in with bolts and nuts) while the tweeter has 2mm pilot holes for the woodscrews which hold it in. There are two other cuts necessary. One is to make the notebook “well” in the 32mm craftwood – we simply made this as large as we thought would be needed to suit the notebook. In retrospect, we realise this could be just January 2006  81 but whatever you do, don’t glue it in place yet! After checking that everything is still where it should be and that the box is still square, start placing the rest of the screws. You’ll find a power screwdriver or cordless drill is almost a necessity here – we used 30 screws in each side. You’ll probably find some of the glue has been forced out of the joins as the panels are tightened up. That’s fine – simply use your finger to run a bead of the glue back into the join. Once all screws are in and tight, put the box aside for a few hours to dry. Then we come to one of the fun parts – applying the carpet! Speaker carpet Fore and aft views of the assembled box, as yet without the back – for obvious reasons. The amplifier tray slides into the void at the bottom of the unit. as easily done with three appropriate lengths of 32mm craftwood instead of the large U-shaped piece we cut. The other cut is in the back of the box for the air vent/access to the notebook. This is the same width and depth as the notebook well. Again, we cut this with the router but a jigsaw would also handle this quite nicely. That’s all the rebates and cuts completed – now you need to drill holes in the sides for the screws which will hold it all together. Somewhere around 4-5mm holes should be fine. Drill the holes along the centre lines of all rebates – we placed screws 50mm in from each edge and then around 150170mm apart, depending on the length to be covered. Following the rebates means you should end up with holes that are dead centre and will not split when screws are placed. When all the holes are drilled, turn the sides over and countersink each hole so that all screw heads will end up flush with (or even slightly below) the surface. Dummy run Loosely assemble the box (ie, without glue or screws) just to ensure everything goes together as it should. You may need a second pair of hands 82  Silicon Chip here – and if you need to nip a couple of screws to hold it together, that’s fine. Just don’t do them up all the way If everything looks correct, it’s time to start with the glue and screws. We used garden-variety PVA glue and TEK screws specifically intended for chipboard. For box assembly, we used 50mm screws. As we said before, our box fitted together so well it didn’t need cramping – the screws held it securely while the glue dried. If you need to cramp it, so be it. Starting with the sides, run a healthy line of glue in the rebates for the baffle, base and enclosure bottom, stand the sides up, fit the base and enclosure bottom and nip in enough screws (four corners?) to stop it all collapsing. Place the baffle in place in its rebates (make sure the glue hasn’t oozed away) and tighten up the loose screws. Now run a line of glue in the rebate in the speaker top, turn it over and slide it in from the back. Make sure the baffle mates with the rebate and place say four screws to hold the speaker top in position. At this stage, we also fitted the back to make sure the box stayed square. We didn’t bother with all the screws – four hold it sufficiently in place – As well as hiding any sins, speaker carpet is also pretty flexible stuff in its own right. It can be pushed, pulled, prodded and stretched to make it cover just about any shape. We didn’t have any problems at all fitting it to the curved tops to the Ultimate Jukebox (and curves are the hardest part). The whole outside of the box is covered in the carpet, with the exception of the notebook well. The only reason I didn’t cover this was that the thickness of the carpet would have meant that the 32mm craftwood was just too thin and the notebook keys would be starting to compress. The aluminium covering above the notebook was covered in speaker carpet on the top (you could cover both sides if you wish). Contact adhesive secures the speaker carpet to the box. Don’t underestimate the amount of glue you will need: I did! I thought a 1-litre tin would be ample – I went through over two litres (the speaker carpet really soaks it up!). With a bit more care, I could have just scraped through with two. You’re also going to need a notched spreader to apply the glue. These are commonly available where contact adhesive is sold – usually right next to it on the shelf! The easiest way to use contact is to coat the hard surface to be glued, place the carpet on while wet, then separate the two again until they are both just dry (“tacky” is an expression often used). Then carefully place the carpet back onto the surface, stretching it tight as you go. Remember that with contact adhesive, you get just one go! Plan the covering so that you have siliconchip.com.au minimum cuts – it just looks better that way. The simplest surfaces to be covered are the sides and back – so if you haven’t glued speaker carpet before, this is a fairly risk-free area to develop your skills Cut a piece of carpet that will do both sides and the back – allow say 10cm for safety. Do each surface in turn – ie, glue one side, attach the carpet, then the back, then the other side. Finally, do the front edges of the sides. You’ll find as you do the curved surface at the top that the carpet can be stretched tight as you go and it should follow the curve without puckering. You need a very sharp knife to cut the carpet “in situ” – a “Stanley” knife is normally not sharp enough unless you’ve sharpened it on a whetstone. A craft knife is a much better proposition because they have snap-off blades – as the cutting edge dulls you can snap that bit off and get a new, sharp blade. Cutting the carpet is as simple as running the blade down the surface where you want to cut. Remember though that the box is timber and your knife is very sharp – sharp enough to cut into the wood. I generally cut using a thin metal rule following the cut under the knife blade to prevent it knicking or slicing into the wood and cutting the carpet off line. Cut the carpet as you go, so you don’t end up with a whole lot of pieces flapping about. This also means you can perhaps extend another piece to cover any “oopses”. Because the carpet has a grainy finish, slight imperfections are easy to hide. Once you have the sides and back finished, you can do the baffle. Remember that this is inset – you need to turn the carpet up at the edges to meet the piece already fitted. You’ll find that the carpet can be pressed into the corners easily – I used the back of the craft knife to make a nice, neat corner. You can now carefully cut out the speaker holes. A long (~880mm) thin (18mm) strip (precut for convenience) can be glued around the woofer cutout. All that’s left of the box itself is the inside top sides and back – this should be quite easy because by now, you’re getting pretty skilled in gluing speaker carpet! Cutting the back out The back is currently held in place with four screws . . . and the speaker siliconchip.com.au carpet. And, of course, you need to get the back off so that you can wire the speakers and crossover. With the craft knife, cut along the seam between the back and rebated sides, then cut a small slit across each of the four screws. That way you can get a screwdriver in and remove the screws – and the back. If the back is such a tight fit that there is no seam to get the knife into, use a long straight edge to cut along where the seam would be. With 18mm timber and a 5mm rebate, that means 13mm in from the edge. If you get it “pretty” enough, once the back is screwed permanently on you won’t even know there’s a seam there. If your cut is a bit onky, don’t worry too much: it’s at the back! Moving it At 32kg for the timber alone, the Ultimate Jukebox takes a bit of dragging around. To assist this, we fitted a pair of 40mm castors on the base, at the back. Actual height of these from top to bottom is 85mm. At the front, we screwed in a length of 100 x 50mm framing timber, planed down to 85mm high, as a “foot” and covered it with speaker carpet. That way, when let off the wheels, much of the jukebox weight transferred to the timber foot and gives extra stability. The handle We’ll show this in a lot more detail next month but here is the Ultimate Jukebox from the back, without back of course! At top is the notebook computer, centre is the actual speaker box and at the bottom, the electronics. To help move the box, we wanted a pair of handles at the back so that it could be leant back onto the castors and rolled along. But when we priced handles at the hardware shop, we found they were about $4 each and worse, were puny (after all, they were intended for drawers). As we said earlier, the jukebox has significant weight and we were worried about the handles taking the load. So instead of handles, we used bathroom towel rail and rail ends. It cost less than two handles and is a lot stronger. And if you’re all sweaty after moving the Ultimate Jukebox around, you can always hang your wet towel over the rail . . . We positioned the rail/handle immediately under the air vent on the rear of the box. Don’t use the little woodscrews that came with the rail ends; we substituted countersunk head 5mm bolts and nuts which really anchored the thing in place. The box is finito! Now you can fit the speakers, woofer mesh grille, crossover . . . and start the wiring. The grille comes with four bolts and nuts – we discarded these and used the bolts that hold the woofer in place to also hold the grille. A piece of plastic surround comes with the grille – cut appropriate January 2006  83 1 SC480 50W RMS amplifier module [Altronics K5120, Jaycar KC-5345, DSE K3431] 1 power supply to suit [Altronics K5122, Jaycar KC-5347, DSE K3432] 1 28-0-28VAC Toroidal transformer to suit [Altronics KM5120, Jaycar MM1095, DSE M-0144] 1 PreCHAMP Preamplifier (with modifications – see text) [Altronics K2112, Jaycar KC5166, DSE K5608] 1 120kW 1/2W resistor (for PreCHAMP mods) 1 560W 1/2W resistor (for PreCHAMP mods) 1 3.5mm stereo plug 2 5.6kW 1/8W resistors 1 IEC mains input socket with integral fuseholder [Altronics P8324, Jaycar PP4004] 1 IEC mains lead 1 mains-rated SPST rocker switch with neon 1 10kW log potentiometer 1 4-way mains terminal block 1 50 x 50mm piece blank PC board (or used copper-side down) Scraps of aluminium for power supply and hard disk clamps, mains connections safety cover, etc. 1.5m length shielded cable, various lengths mains-rated connection cables, heatshrink tubing, cable clamps, cable ties notches out of its back so that it clears the mounting bolts. Because it’s very flexible, you can simply lift the front out of the way while tightening the mounting bolts. The woofer mounts inside the box while the compression horn for the tweeter mounts in the rebate from outside the box. You can use either wood screws or nuts and bolts to hold the horn in position. Wiring from the crossover to the speakers is self-explanatory – the crossover is clearly marked woofer and tweeter. The figure-8 wiring from the crossover to the amplifier needs to go through one of two holes drilled in the bottom of the speaker box. Only drill a hole as large as you need to get this wire and the audio input wire (from the notebook) through. Later, you’ll need to re-seal this hole with silicone sealant. One point you will note from our photos is the 10W resistor in series with the tweeter. We included this because we thought the system sounded just a little “bright” – ie, too much treble. This is purely a matter of choice – you can include this if you wish (we used an 8W resistor) or not. If you want to experiment with the sound, anything from zero to say 20W would seem appropriate. Obviously, a hole needs to be drilled through the top of the box to allow the audio input cable through. Choose a place where it doesn’t interfere with the computer or its 32mm timber surround (we made the timber surround slightly undersize to achieve this. A second pair of holes need to be drilled in both the enclosure top and bottom to allow the computer power cable and the USB cable between computer and hard disk to pass through. The USB plug will determine how big this hole needs to be. Again, once the project is basically completed, these holes will need to be sealed. You might need a small piece of timber glued over the hole as well as silicone sealant to ensure the hole is plugged! Computer section Oh no! We’re out of room! Parts List – Ultimate Jukebox “Hardware” 1 2400 x 1200 x 18mm sheet craftwood (MDF) (or 2 1200 x 1200 x 18mm) 1 450 x 900 x 32mm sheet craftwood (MDF) (base and notebook spacer) 2 435 x 350 x 2mm aluminium sheets 2m speaker carpet (1.8m wide) 1 380mm length 20mm diameter chromed towel rail 2 20mm towel rail ends 2 40mm swivel castors 1 380mm length 80 x 50mm timber (for front stand, carpet covered) 4 speaker corner protectors 50 50mm TEK woodscrews 8 40-50mm x 4mm (3/16”) csk head bolts with nuts (for speaker and grille) 8 20mm x 8g woodscrews (for horn mounting) 4 30mm x 4mm csk head bolts with nuts (for handle mounting) 8 10mm spacers, tapped 3mm, 62 5mm x 3mm screws and nuts 4 10mm x 3mm screws and nuts 2 20mm x 3mm screws and nuts (for terminal block mounting) 3 solder lugs 2 3mm shakeproof washers (for common earth point) 2 fibre washers (for PreCHAMP PC board mounting insulation) Around 2 litres contact adhesive (for speaker carpet) PVA wood glue (for box assembly) Speaker Section 1 high sensitivity, high power 300mm woofer [Altronics C3212] 1 compression horn driver [Altronics C6110] 1 horn flare to suit driver [Altronics C6130] 1 2-way 150W crossover [Altronics C4007] 1 300mm metal grille [Altronics C3712, Jaycar AX-3524] 1m medium-heavy duty figure-8 cable 1 8W 10W wirewound resistor (if required to attenuate tweeter) Amplifier/Electronics Section 1 Notebook computer with mains power supply (Pentium 100 or better) running “Ultimate Jukebox” and “Winamp” software 1 External USB hard disk drive, if required due to inadequate hard disk space in computer 1 USB extension cable (if needed) 1 Trackball (or optical mouse), preferably USB 84  Silicon Chip We had hoped to complete the Ultimate Jukebox this month but space has once again beaten us. So next month we will cover the electronics assembly, testing and finally, blasting the neighbours. . . SC siliconchip.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.batterybook.com www.elexol.com SILICON CHIP MIDI DRUM KIT by JOHN CLARKE PART 3 – building the sensors and stand As mentioned last month, there are two basic pad sensor types: those based around a piezo transducer and those based around the optical sensing circuitry. Which one you use is up to you. The piezo-based pads require tapping with drum sticks or similar items in the conventional “drum” manner. The optical pads can be tapped by hand, making them easier to use. We also use an optical pickup for foot-activated sensors. This is because the system is more robust. A piezo transducer that can be attacked with a foot pedal may well be destroyed rather quickly. Each pad type is described in the separate sections following. Building The Optical PC Board Circuit details were shown in Part 1 but are repeated here for convenience along with the PC board overlay for the optical sensor (there is no PC board for the piezo sensor). The optical sensor PC board is coded 01211053 and measures 52 x 31mm. Once again, before assembly check the underside for any possible shorts between tracks or breaks in the copper. As you did for the other boards, install the resistors and diode (as shown), the PC stakes and the capacitor (which is mounted on its side to allow clearance above the PC board). Finally, the optical sensor is mounted directly onto the PC board, making sure it is oriented correctly. 86  Silicon Chip siliconchip.com.au The Simplest Piezo Sensor The simple piezo sensor is based around a length of 20mm (27mm OD) PVC water pipe. The piezo transducer attaches to the end of the pipe with the shielded cable connected to the transducer and the other end to an RCA plug. To use, the pipe is held in the hand at the opposite end to the piezo and the pipe is then tapped with a stick. Note that the two red and black wires that are supplied connected to the piezo transducer need to be unsoldered and Parts List – Piezo Sensor 1 piezo transducer 1 300mm length of 20mm PVC water pipe (27mm OD) 1 2m length of single- cored shielded cable 1 RCA line plug 2 No.4 self-tapping screws Percussive (Piezo) Sensor Pad This sensor pad needs to be mounted onto a frame using 25mm tubing (see separate diagram). The sensor is played with a drumstick or similar item. Note that the front edge is shown curved to ensure that there is a consistent response from the sensor when the pad is tapped around its circumference. Do not be tempted to use a rectangular edge. This will give dead spots in several positions on the pad where the sensor will not detect a strike on the plate. In addition, do not use metal in preference to the MDF since this will resonate for too long after it is struck. The sensor pad is constructed as shown at right. Cut out the circular section of the MDF panel with a jigsaw and paint the pad with gloss black paint. The piezo replaced with the shielded wire. You must carefully prise off the back of the piezo case to gain access to the wiring. transducer needs to be rewired to have the shielded cable soldered to its piezo and brass sections. The rear of the piezo housing can be carefully prised off to gain access to this wiring. We used an epoxy resin smeared around the edge of the back of the piezo housing before securing with the M2.5 screws into the MDF. This ensures a good physical contact with the MDF plate. The top of the MDF sensor plate can be painted black or covered with a thin sheet of vinyl using contact adhesive. The vinyl can deaden the sound produced by striking it with a stick. Alternatively, the stick can be rubberised. In most cases, the sound of the stick directly onto the painted MDF will not cause any concern. Parts List – Piezo Pad 1 piezo transducer 1 140 x 140mm piece of 3mm MDF 1 120mm length of 20mm PVC water pipe (27mm OD) 2 25mm cable cleats (Farnell NP10 pro-power Cat 725-7399) 2 M4 x 12mm screws 4 M4 nuts 1 ¼” x 4” bolt and nut 1 6.35mm ID x 9mm OD x 22mm long plastic spacer (electrical lamp fitting) 2 M2.5 x 4mm long screws Miscellaneous Gloss black paint, vinyl (optional), epoxy resin, contact adhesive This upsidedown view of a piezo sensor pad is mainly to show the method of mounting the transducer. It also shows the method of mounting to the stand via a clamp and length of PVC pipe (also see diagram below). siliconchip.com.au January 2006  87 Bongo Drums The bongo drums are made using 12mm MDF and 18g (1mm) aluminium sheeting. The MDF makes up the top and bottom dual semi-circular sections while the aluminium sheet is wrapped around the sides of the MDF and secured in place with 6g x 20mm countersunk wood screws. Cutouts in the top are blocked off using MDF timber glued on the underside. These provide the mounting base for the optical sensor PC board to be secured using the 4g self-tapping screws. The MDF cut-outs and the semicircular shape can be cut using a jig saw. Glue the timber to the underside of the top panel cutouts and paint the timber. Wiring the PC boards involves following the overlay diagram for the optical pad sensor and wiring. Note that only two DC sockets are necessary – the second PC board derives its power from the first using hookup wire between the + and + power terminals and the - and - terminals. The DC sockets mount on the aluminium sides of the drums. The signal leads pass through the aluminium via a rubber grommet. A cable tie holding the two signal leads behind the grommet will help prevent the leads pulling out. An alternative arrangement is to attach two RCA panel sockets to the drum and use RCA-to-RCA leads for the signal connections. Make up a DC socket to DC socket lead and terminate the signal leads with‑ RCA plugs. The pressure plate is secured to the top of the drum using 4g screws. The screw that passes through into the optical sensor must be exactly located so that it fits neatly into the optical slot. The plate is bent as shown. Adjustment The slight upward bend allows the screw to have clearance inside the optical slot. This screw needs to be adjusted carefully so that there is a change in voltage at the signal output when the plate is moved. The completed bongo drums. In the photo below left the drums are partially disassembled, showing the optical sensors and plates. The easiest way to adjust this is to firstly make up an RCA socket to RCA plug test connector as shown below and insert this in line between the signal output lead and the MIDI Drum Kit. Alternatively, access the rear of the RCA socket inside the MIDI Drum Kit. Plug into one of the RCA input sockets for the MIDI Drum Kit. Apply power to the drum kit and also connect the DC power lead between the drum kit’s DC output socket and one of the DC input sockets on the bongo drums. Connect a multimeter set to read DC volts to the test connector. The voltage reading should be either small (< 0.1V) if the screw is too far out of the sensor gap or up to 5V is the screw is too far into the slot. Adjust the plate angle and screw setting so that the normal voltage is very close to 200mV. This voltage should rise to close to 5V when the plate is pressed. Ensure the plate is free to move without scraping the sides of the MDF and without the screw scraping the inside of the optical sensor. With the arrangement shown having a nut on top and on the bottom of the plate, the screw can be turned in or out to make the adjustment. An alternative method is to cut the screw to length so that it does not need adjusting. If you have cut too much from the screw, the length can be built up with some solder. This makes it easy to file down so that the length is just right when the plate is secured down with the screws into the MDF panel. Finishing We finished the drums by covering with loudspeaker carpet. This is attached with contact adhesive. The covering is optional. This easy-to-make jig will allow you to adjust the Bongo Drums (and other optical sensors) very easily, by connecting to your multimeter and adjusting the screw to give maximum voltage change. 88  Silicon Chip siliconchip.com.au Parts List – Bongo Drums Plan and elevation of the bongo drums. Top right shows how the pressure plate fixes onto the surface of the drums, with the PC board underneath in the “well”. Speaking of the well, here’s how to make it. This diagram is half the size of the finished drum – so if you have an enlarging photocopier, 200% is the magic number! siliconchip.com.au 2 PC boards coded 01211053, 52 x 31mm 2 photo-interrupters 2 1N4004 diodes 2 470mF 16V PC electrolytic capacitors 4 470W 0.25W 1% resistors 2 panel-mount DC sockets 2 line DC plugs 8 PC stakes 1 50mm long cable tie 4 metres single core shielded cable 2 RCA line plugs 2 135 x 245mm pieces of 12mm MDF 2 30 x 220mm pieces of 12mm MDF 2 120 x 707mm sheets of 18g (1mm) aluminium 2 61 x 108mm sheets of 18g (1mm) aluminium 2 20 x 58mm sheets of 18g (1mm) aluminium 8 4g x 12mm self-tapping screws 12 6g x 20mm csk wood screws 1 M3 x 12mm screw 1 3mm star washer 2 M3 nuts 1 6mm ID rubber grommet Miscellaneous Black paint, contact adhesive, speaker carpet (optional), PVA glue January 2006  89 Optical Sensor In many ways, the optical sensor is similar to the Bongo drums in construction. Most of the construction for this applies to the optical sensor. The sensor is designed to mount onto a frame described on the next page. When used as a foot controller it can be placed on the floor rung of the stand. The current design is not suitable for use on the higher rungs of the stand. This is because there will be too much stand movement when the sensor is pressed. A heavy-duty stand made from tubular steel could be used to support several optical pad sensors. The optical pad sensors would also need to be held in position with steel clamps instead of plastic ones. In addition, use two DC sockets for the power input and output as shown in the main optical sensor wiring. The second DC socket allows for interconnecting power between sensors. The 12mm MDF will require trimming back in thickness by 3mm where the two plastic clamps attach at the rear of the pad. Use a chisel to do this. The reduction in thickness is so that the clamp will close up sufficiently to mount tightly onto the 25mm frame. The MDF material for the sensor is painted using gloss black paint before assembly. A rubber stick-on foot is placed at the front edge of the cut-out to provide a stopper for the pressure plate. The sensor PC board is attached using M3 screws and nuts. You may need to use some Nylon washers to space the PC board slightly above the 3mm MDF baseplate. Note that the pressure plate needs the centre screw to be adjusted correctly as described in the bongo drum section. PIC T/C Note These optical pads are not ideal for hitting with a drumstick since it sets up resonance in the aluminium plate. This causes the drum sound to be played more than once for each strike. If you need to use the optical pads with sticks, then the setting-up procedure where the DC voltage is set to around 200mV needs to be changed. The initial voltage is set to the saturation voltage of the output transistor in the optical sensor. This is about 100mV and is observed to be the voltage that does not change until the pressure plate is moved by a millimetre or two. Best adjustment is found by trial and error, but the plate needs to be set so that it needs some movement before any voltage change is found at the sensor output. Parts List 1 PC board coded 01211053, 52 x 31mm 1 Photo interrupter 1 1N4004 diode 1 470mF 16V PC electrolytic capacitor 2 470W 1/4W 1% resistors 1 line DC plug 4 PC stakes 1 2-metre length of single core shielded cable 1 RCA line plug 1 140 x 142mm piece of 12mm MDF 1 140 x 120mm piece of 3mm MDF 1 61 x 108mm sheet of 18g (1mm) aluminium 1 20 x 58mm sheet of 18g (1mm) aluminium 2 25mm cable cleats (Farnell NP10 pro-power Cat 725-7399) 4 M3 x 12mm screws and M3 nuts 4 4g x 12mm self tapping screws 1 M3 x 12mm screw 1 3mm star washer 2 M3 nuts 2 4” x ¼” bolts 2 ¼” nuts 4 3mm Nylon washers 2 50mm cable ties Again reproduced half size, this diagram shows how the optical sensor unit is constructed. 90  Silicon Chip Miscellaneous Black paint, PVA glue siliconchip.com.au Building A Playing Stand One or two sensors alone are fine sitting on a bench, etc, (or even the floor!) but when a number of sensors are used, some form of frame or stand is necessary so they can mount in their correct positions for playing. We made up a stand using conventional hardware components. Broomsticks were used instead of dowell because they’re usually a lot cheaper! The stand was glued together with builders’ adhesive for the Tee joins and PVA glue for the MDF bracket to the 25mm rod. It was painted in a gloss black. Note that the design allows the top rung to be removed. This is for easy transport of the frame on the back seat of a car. The broomstick pieces are cut to length, noting that the stick is passed right through the T-piece rather than cutting it at this point. Each T-junction is made stronger by making a 25mm hole part way into the side of the straight through broomstick. Note that the Vinidex T-pieces allow the broomstick to pass easily through it. Other brands may need drilling or filing out to allow the stick to enter right through the piece. The MDF right angle bracket is included to give extra support in the forward and backward direction. The wires for the sensors can be made tidy along the frame using cable clips. The percussive sensor is designed to be able to be adjusted to any angle, making it very suited for stand mounting. However, if using the optical sensor on the stand, it must be mounted on the floor rung of the frame, so the front edge of the pad rests on the floor to add extra support. As mentioned, the stand and optical sensor pad mounting must be of heavier construction than the one shown here if you intend to use optical pad sensors throughout. Parts List 6 broom sticks, 25mm in diameter 6 20mm PVC water pipe Tee pieces (Vinidex) 2 20mm PVC water pipe joiners 1 150 x 150mm x 12mm MDF sheet 4 25mm rubber pipe ends Miscellaneous Black gloss paint, PVA glue, builders adhesive This is the stand we put together from bedknobs and broomsticks (OK, not too many bedknobs). It’s just one possible arrangement for mounting the controller and various sensors, giving room for foot pedals underneath. siliconchip.com.au January 2006  91 Foot Controller The foot controller is generally used to control a bass drum sound. We show how to build a foot controller for this purpose using an optical sensor. An alternative foot controller is shown under the Optical pad heading. The optical pad is made into a plastic box and secured to the upright MDF piece with M4 screws and nuts. This also sandwiches the pressure plate in between the box and MDF. The PC board for the optical pickup is supported on M3 tapped standoffs (9mm long) and held using M3 x 10mm screws. The screw mounted in the pressure plate to interrupt the optical sensor must be adjusted as described in the Bongo Drums set-up. The DC sockets are mounted at each end of the box. The signal output is wired to the 6.35mm jack socket that is mounted on an aluminium bracket. You will need to make up a 6.35mm jack plug to RCA plug lead for the connection between the foot controller and the MIDI Drum Kit. The footswitch is made using the MDF panelling as shown. We painted the assembly with black paint and covered the foot areas with speaker carpet. If you want to build your own foot controller, here is how to do it. The alternative is to use the information in this diagram to modify a commercial foot pedal. 92  Silicon Chip siliconchip.com.au Footswitch The footswitch is a commercially made unit – all it really needs is to have an RCA plug wired to its end. However, the wiring supplied with the switch is a little too thick for the RCA plug so is best replaced with a single core shielded cable instead. Connect the wire between the normally open and common connections on the microswitch. Parts List 1 PC board coded 01211053, 52 x 31mm 1 bulkhead plastic box, 65 x 38 x 25mm 1 Photo interrupter 1 1N4004 diode 1 470mF 16V PC electrolytic capacitor 2 470W 1/4W 1% resistors 1 6.35mm mono jack socket 2 line DC plugs 4 PC stakes 1 2-metre length of single core shielded cable 1 6.35mm mono plug 1 RCA line plug 1 65 x 120mm length of 1mm aluminium 1 20 x 40mm length of 1mm aluminium 1 60 x 20mm 1mm aluminium 1 100 x 35mm sheet of 1mm aluminium 1 85mm but hinge 6 8g csk wood screws cut to 12mm 7 6g csk wood screws cut to 12mm 1 5g x 20mm screw 1 M3 x 15mm screw 1 3mm star washer 2 M3 nuts 2 M4 x 15mm screws 2 M4 nuts 4 M3 tapped x 9mm spacers 8 M3 x 6 screws 1 20mm long by 6mm OD compression spring (from clothes peg) 3 15mm OD x 6mm ID rubber grommets 1 100 x 320mm length of 12mm MDF 1 100 x 80mm length of 12mm MDF 1 100 x 220mm length of 12mm MDF 1 65 x 47mm length of 12mm MDF Parts List 1 footswitch (eg, Jaycar SP-0760) 1 1m length of single core shielded wire 1 RCA line plug NEXT MONTH: The final part – software – and how to drive it! Miscellaneous Black paint, PVA glue, speaker carpet, contact adhesive siliconchip.com.au January 2006  93 SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.altronics.com.au/ SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.altronics.com.au/ SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.altronics.com.au/ SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.altronics.com.au/ 433MHz + Picaxe = Magic! You’ve no doubt heard of Murphy’s, Ohm’s and Moore’s Laws . . . but how about Swan’s Law – “You can never have too many thermometers”? by Stan Swan* H ere’s a Picaxe-controlled wireless version that should suit many needs and YES! – it’s legal, as the only Australian/NZ 433.92MHz LIPD ISM regulatory restriction is that the transmitter should not exceed 25mW EIRP (Effective Isotropic Radiated Power). Since Picaxe-08M microcontrollers work so well with 433MHz UHF data modules (see last month), it’s tempting to further link the pair to industrystandard DS18B20 Dallas Semiconductor (Maxim) digital temperature ICs and make a simple Picaxe-08M driven wireless thermometer. Direct Celsius temperature data can be then transmitted some 50 metres and shown on a PC attached to the 433MHz receiver (with perhaps further treatment under Excel). A simple antenna extends this range to more like 300m, while a Picaxecontrolled data repeater can even push ranges to perhaps 500m and may allow coverage when obstacles otherwise block weak signals. What’s involved As initially mentioned in the December 2005 SILICON CHIP article, we’ve now migrated to the Mk.2 PICNIK box layout approach (see the The first of Stan’s breadboard circuits for this month: both use the wireless techniques explained last month but now they’ve taken on Picaxe control. Aaaaah – Stan’s two loves in one circuit? He’s in rapture . . . 98  Silicon Chip siliconchip.com.au The DS18B20 digital temperature IC is, confusingly, a look-alike to cheap BC547 transistors and mixups may arise unless it’s boldly marked – here whiteout and a red felt tip dot has been used to avoid any possible circuit confusion. As outlined last month, the various LIPD modules are usually pin-for-pin compatible, so most of the common 433.92MHz transmitters can be used, although the antenna position may vary on some. One I found even had its antenna pre-wound and bonded to the module. The receiver assembly may need more consideration, since the Jaycar version needs a nominal 5V supply and may be less tolerant of three 1.5V AAs (ie, 4.5V) for the supply unless the cells are fresh. Consider perhaps four NiCd/NiMHs (4 x 1.2 = 4.8V) instead, or even 4 x 1.5V cells (thus 6V) and a series silicon diode to drop that back to around 5.4V (as outlined later). The Mk.2 PICNIK box has room for either a three or four AA-cell switched battery box anyway Once the Tx and Rx boards are assembled and powered up, simply port over the correct code (www.picaxe. orcon.net.nz/434tx.bas and www. picaxe.orcon.net.nz/434rx.bas) from the Picaxe Editor PC to the matching setup. Following the energy saving SLEEP command (initially set to about one minute – modify to suit), the DS18B20 Here’s the Picaxecontrolled wireless thermometer – the circuit at top and the breadboard layout at right. There are subtle differences between this layout and the photo at left – neither is “wrong” but the one at right is a little easier to follow in printed form. www.picaxe.orcon.net.nz/picnik2.gif “slide show”), which conveniently has room enough for a Picaxe-08M and the 434MHz Tx/Rx units. It’s again strongly recommended that you first lay out the circuit on such solderless breadboards (as we’ve shown here), allowing things to be better understood and tweaked. The final soldered versions should be the last stage in your design– not the first! However, for eager constructors “more confident in their abilities” and wanting to build just the final version, it’s suggested that Dick Smith Prototype Board (DSE H-5605) be used. Its 0.1-inch-spaced solder pads siliconchip.com.au are laid out exactly the same as the breadboards, allowing almost a “paint by number” approach to board stuffing. Rather than soldering the Picaxe and 433 units directly onto this board, use 8-pin IC sockets. The same can be said for the transmitter and receiver modules – cut the IC sockets in half lengthways. The DS18B20 can of course be extended away from the board with three wires but ensure their solder joints are waterproofed with epoxy or neutral silicone sealant for measurements in damp areas. See a possible approach at www.picaxe.orcon.net. nz/pvdemo.jpg The alternative construction methods: our familiar breadboard and above it, a DSE Prototype Board. It’s easy to transfer circuits from one to another because both use the grid system. January 2006  99 Want cheap, really bright LEDs? We have the best value, brightest LEDs available in Australia! Check these out: Luxeon 1, 3 and 5 watt All colours available, with or without attached optics, as low as $10 each Low-cost 1 watt Like the Luxeons, but much lower cost. •Red, amber, green, blue and white: Just $6 each! Lumileds Superflux These are 7.6mm square and can be driven at up to 50mA continuously. •Red and amber: $2 each •Blue, green and cyan: $3 each Asian Superflux Same as above, but much lower cost. •Red and amber: Just 50 cents each! •Blue, green, aqua and white: $1 each. Go to www.ata.org.au or call us on (03)9419 2440. Select your microcontroller kit and get started... From $295* Fax a copy of this ad and receive a 5% discount on your order! Feature rich, compiler, editor & debugger with royalty free TCP/IP stack RCM3400 • Prices exclude GST and delivery charges. Tel: + 61 2 9906 6988 Fax: + 61 2 9906 7145 www.dominion.net.au 100  Silicon Chip 4007 Here’s the matching receiver module – again, there are differences between this and the photos. Virtually any of the commonly available (and cheap!) 433MHz wireless modules can be used in this circuit as most are pin-for-pin interchangeable. will power up to read the temperature, which is then transmitted as a variable (b1) before shut down again. A red LED winks to indicate outgoing data, which has been reduced in speed to just 300 bps for reliability. There’s little point in sending faster when the unit will spend considerable time idling between readings and the Picaxes could even be under-clocked to further slow data rates if superior reception is needed – this may also prolong battery life. At the receiver (if in range) the unit first has to be given a preamble to ensure it’s listening carefully – experimentation showed that a good burst of ASCII 85s (“U” being 01010101) ensured it was suitably responsive. A further “ABC” qualifier is then added to the transmitted serial string, with a similar sequence at the receiver, to ensure that data will only be re- sponded to if this preceding ABC is present. Naturally, with numerous wireless garage door openers, door bells and the like now abounding, you don’t want false triggering every time the place next door has visitors – or vice versa. There’s a parallel here with WW2 coded BBC messages of course – only if a pre-determined phrase such “My hovercraft is full of eels” was broadcast would the listening partisan group blow up the rail bridge, etc. Being 2006 rather than 1945, instead of bridges the alerted SERIN command takes the b1 temperature variable and directs it via the Picaxe programming cable to the PC for editor “F8” 4800bps terminal window display. Other readouts, perhaps an LCD module or old organiser suitably driven by SEROUT, could easily be used instead. siliconchip.com.au idle capacity to “store and forward” the temperature data. The technique is akin to LEO (Low Earth Orbital) “flying mailbox” satellites which take in weak ground signals, when over a remote area, for resending as they pass over a base station perhaps 20 minutes later. When placed in an elevated RF sweet spot (and perhaps solar-powered), enhanced signal broadcasting results, allowing data gathering from areas that may otherwise be UHF black holes – a cave or well perhaps. The small 230 hole (+ 40 supply Put a receiver and transmitter module together and what do you get? A repeater, of course! The code for the Picaxe control can be found on Stan’s website (address at end of this article). With the use of the Picaxe WRITE and READ commands, quite a stack of these variables could be stashed in EEPROM for later retrieval as well of course, effectively making a wireless temperature data logger. Every school should make one to explore and experiment ! A simple quarter-wave antenna (~165mm at 433-4MHz), perhaps spiraled somewhat for compactness, should give a range through wooden walls of about 50m. For coverage beyond this, consider antennas such as the Yagi “cotanga” or magnetic pickup version described last month (www.picaxe.orcon.net.nz/ yagi433.jpg) and if used at both ends siliconchip.com.au perhaps 300m range may result. In situations where the transmitter signal is well shielded from the receiver behind metalwork, buildings, hills or extensive vegetation you’ll need a bit more ingenuity. A repeater! Taraaaa! You saw it here first – a dead simple but effective Picaxe controlled 433MHz data repeater. The Picaxe driving code is a breeze, but keep in mind it’s only set up to “store and forward “ a single variable, so don’t expect WiFi bandwidth! Since the baby 08M has spare I/O channels and memory, it was tempting (and indeed proved feasible) to use its And here’s the breadboard layout of the repeater. The long black object is also an antenna – just a different type than our curly wire version. January 2006  101 rail) breadboards we used nicely fit both a 433 Rx and Tx module alongside the Picaxe, and following simple hookup wiring the repeater can be programmed with www.picaxe.orcon. net.nz/434rpt.bas To show its action, green and red LEDs (for awaiting receiving then retransmitting) connect via 1kW dropping resistors – much larger than really needed but reducing battery drain to just a few milliamps. 433MHz transmitters only come on when data is fed to them but naturally the sensitive receiver must be switched off before the transmitter comes on, otherwise it will be overloaded. Such needs can again be easily handled via our Picaxe, since each output has the ability to provide (“source”) ~ 20mA current when high. Somewhat annoyingly, the Picaxe SERIN command can’t be interrupted or timed out but completely stops processing until a suitable signal arrives, meaning the receiver can only be switched off (and the program able to continue) after such prescribed data is received. There’s a parallel here with fishing and the discard of any less worthy catches, as you’ll only go home when a desirable barramundi (?) is in the bag. Note: the temperature data handling here is a simplex in nature, and similar to a radio station sending out programs. Extensive data massaging, using CRC error detection or even half duplex confirmation is rather beyond this initial article so has not been considered, although is mentioned in the references. If the receiver is close to both the sender and the repeater, a double set of data will show up on the screen as the two signals are received. Although you’ll obviously not need the resending in such a strong signal arrangement, normally position the repeater where it can just reliably hear the sender and the receiver can further hear the repeater’s outgoing signal. Perhaps initially reduce the SLEEP to just a few seconds to speed up the process, as the informative switching LED patterns will greatly help positioning. Solar power? With hardware and gift/bargain stores now displaying racks of solar powered garden lamps at near throw102  Silicon Chip Just to prove the point, here’s a version of the circuits on the DSE prototype board. Ignore the 2 extra LEDs in the repeater circuit. Note the IC sockets supporting the Rx module – they can also be trimmed for the programming lead. away prices (often under A$5 each), it’s tempting to power our modules from the sun via parts salvaged from such lamps. Since each lamp usually has an epoxy-covered four-wafer PC cell (delivering ~2V at 30mA) and a 600mAh NiCd, a 3-PV array will be sufficient to drive a module (probably the repeater) and charge four NiCds. Average current demands of the Picaxe controlled units are around 10mA (much less when sleeping), meaning ~eight hours of daylight will be sufficient to run a setup and keep the batteries at full charge. To avoid oversupplying the Picaxe08M (which normally needs under 6V) and prevent battery discharge via the panel at night, a blocking diode should also be fitted. Although cheap, silicon diodes waste 0.6V but conveniently the solar garden lamps again come to the party and provide a superior Schottky version (1N5817 etc) which drops only 0.2V. Amazingly for the lamp price, further useful parts like an ultra-bright white LED lurk in the device for later projects – how can these things be made so cheaply? Footnote for sunbelt regions: just as the photovoltaic (PV) panels need sunlight, you need to ensure that the repeater electronics aren’t cooked by strong sun. It can happen! Don’t mount the repeater in too inconvenient a place either, as you’ll no doubt need to access it for software upgrades and occasional dirt removal from the panels. Birds naturally appreciate elevated roosts but their droppings (especially from seagulls) may be the weak point in a pico PV-powered system like this! References: For convenience these are hosted, along with mentioned URLs and project software, at www.picaxe.orcon. SC net.nz/434rpt.htm * s.t.swan<at>massey.ac.nz siliconchip.com.au SILICON CHIP Order Form/Tax Invoice Silicon Chip Publications Pty Ltd ABN 49 003 205 490 www.siliconchip.com.au PRICE GUIDE: SUBSCRIPTIONS YOUR DETAILS (Note: all subscription prices include P&P). 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SUBSCRIBERS QUALIFY FOR 10% DISCOUNT ON ALL SILICON CHIP PRODUCTS* * except subscriptions/renewals Qty Item Price Item Description Subscribe to SILICON CHIP on-line at: www.siliconchip.com.au Both printed and on-line versions available Total TO PLACE YOUR ORDER siliconchip.com.au P&P if extra Total Price BUY MOR 10 OR ISSU E BACK ES A 1 0 & G ET DISC % OUN T $A Phone (02) 9939 3295 9am-5pm Mon-Fri Please have your credit card details ready OR Fax this form to (02) 9939 2648 with your credit card details 24 hours 7 days a week OR Mail this form, with your cheque/money order, to: Silicon Chip Publications Pty Ltd, PO Box 139, Collaroy, NSW, January2097 2006  103 Australia 01/06 Vintage Radio By RODNEY CHAMPNESS, VK3UG The AWA B25/6 Stereogram Towards the end of the valve era, the local radio industry began producing stereo versions of what used to be (mono) radiograms. These usually had a power output of several watts per channel and their bass response was often curtailed to stop acoustic feedback via the cabinet to the stereo pickup cartridge. T HIS AWA STEREOGRAM is similar in concept to most others of the era. Normal AM radio reception was in mono, with a standard converter and one stage of intermediate frequency (IF) amplification and detection. From here on, the difference between a mono radiogram and a stereo radiogram is apparent. The audio system is split into two identical amplifiers feeding speakers at the left and 104  Silicon Chip righthand ends of the cabinet to give the stereo effect. Some stereograms used the normal mono radiogram cabinet and put the second speaker into a satellite speaker box. This meant that a better stereo effect could be achieved. The AWA B25/6 is a single-cabinet stereogram which stands on four splayed legs. There is a 6 x 9-inch oval speaker at either end of the cabinet. The radio and amplifier chassis is in the lefthand end and the controls are accessed under the lift-up lid above the 4-speed record changer. To the right of the changer is a small area for storing a few 12-inch records. The righthand end is largely empty space with the second oval speaker situated in it. This was a relatively simple stereogram, designed to cater for the middle to low end of the market. Removing the chassis We all hope that the removal and reinstallation of the “works” from a cabinet will be easy and straightforward. While cleaning the dirt and muck off the cabinet, I looked carefully to see how the receiver chassis could be removed from the cabinet. It looked like it could be a challenge. I’d seen the data on how to dismantle some of the slightly earlier models that appeared to be the same, as shown on the technical data sheets. However, close inspection revealed that the layout inside the record changer section was quite different to the ones in the data sheets. I removed the knobs and could see that the chassis would drop down inside the cabinet if two mounting screws were removed. Before doing this, I placed the cabinet on its lefthand end and looked underneath again to see if access was available from the underside of the cabinet. Well it was. I removed three screws and the cover came off. I looked more carefully to see why only three screws were used on the underside of the cabinet to secure the cover. The reason soon became quite obvious. The cover originally had been stapled to the underside of the siliconchip.com.au Despite the age of the unit, the chassis was in quite good condition. Note the mounting method for the pots, selector switch and tuning gang. cabinet and when it had to be serviced in the past, the serviceman had to lever the staples out to remove the base. I could now see the chassis and observed that if I removed the two retaining screws, the chassis would fall into the cabinet and probably break some valves. I then got the bright idea that if I removed the record changer I could gain access through the changer cutout and be able to remove the screws and support the chassis at the same time. It was still a menace to disconnect the cables, as the connections were tight on some miniature spade connectors. With some difficulty, I managed to get the chassis out without damaging anything. After I had overhauled it, there was the job of putting the chassis back into the cabinet. I had to get extra help to do this but I got it back together. Thinking there had to be a better way of doing this, I noticed four screw heads on the front of the cabinet I hadn’t seen before – part of a decorative trim. I removed these and the front baffle with the two speakers on it came away from the cabinet. This would make it much easier to remove the chassis. Further investigation showed an even better method: lay the cabinet on its right hand end and remove the base panel and the front speaker baffle. Once this is done, the chassis is reasonably easy to get at. The moral of the story is to explore all possibilities of how to remove the siliconchip.com.au innards of a set before jumping to the conclusion that the manufacturers had a fiendish delight in making it extremely difficult for servicemen or restorers. I still believe most manufacturers could have used more lateral thinking and come up with a much better means to gain access to the works. While the chassis and record changer were out of the cabinet, the inside of the cabinet, the chassis and the record changer were cleaned with a brush and later with a kerosene-dampened rag. Mouse dung had to be cleaned out but the only damage was some corrosion on one edge of the chassis. The valves were taken out and cleaned with soapy water, taking care not to rub the valve type numbers off. B25/6 circuit details I’m not sure if the set is a B25 or a B26 as the chassis has no markings on it to indicate the model. However, the circuit appears to be similar to the AWA B20 which is shown as Fig.1 of this article. The B25/6 is a 6-valve set and is quite conventional. The AM tuner section uses a 6BE6 as a converter and a 6N8 as the 455 kHz IF amplifier/AGC and detector. Each power amplifier uses one half of a 12AX7 twin triode and a 6AQ5 pentode as a single-ended This view shows how the chassis is mounted vertically inside the cabinet (front speaker panel removed). January 2006  105 Fig.1: the circuit of the AWA B25/6 is similar to that for the AWA B20 shown above. It’s a 6-valve superhet design with a 455kHz IF stage. class-A output stage. A 6X4 acts as the power supply rectifier. Before I switch a set on, I always do a number of things to make sure that it is safe to do so. First, I checked that the earth pin of the mains plug was connected via the earth wire to the chassis, which it was. That done, I used my 1000V tester to check that there were no insulation breakdowns between the mains wiring to the chassis and to the secondary winding of the power transformer – all was well. The speaker transformers were then checked for continuity of the primary winding and once again they were in good order. The next job was to check the resistors and capacitors. The resistors all tested within tolerance or if not, they were only a small amount out. The capacitors were a different matter. Tested at 500V, I found that all the AEE capacitors were much too leaky at 1MW to 5MW resistance and most of the UCC capacitors were no better. The other capacitors were all in good condition. Where their leakage resistance would have affected the 106  Silicon Chip circuit’s operation, defective capacitors were replaced. Close inspection of the chassis also revealed a blue lead going through an eyelet on a soldering tag strip. Why this was done I don’t know but it means that extreme care is needed to solder anything to the top lug so that the insulation on the blue wire doesn’t melt. The valve sockets and the gram/ radio selector switch were given a squirt of Inox cleaner and the control shafts were oiled. With the valves installed, it was time to test the set. With an outside antenna connected and power applied, the set came up very nicely with full high tension voltage and a radio station playing in the background. Good reception was obtained right across the band. The performance was so good that I decided that the alignment was near enough and didn’t need any tweaking. The knobs were all in good condition except for one with a white pointer, which has cracks in the plastic. It appears to be a replacement and, unlike the others, lacks a metal collar. To strengthen it, I wound three turns of 24-gauge tinned copper wire around it in the same position as the collars on the other knobs. I then twisted the two ends together, quickly soldered them and laid the soldered join down along the knob so that the repaired knob would fit down its escutcheon and onto the control. It worked well and the knob is now much stronger. The record changer The BSR Monarch record changer is one of the simplest around but for service it is necessary to remove it from the cabinet. This is done by removing the audio and power leads, then twisting the toggles on the two screws holding the changer in the cabinet so that they will slip through the mounting holes. I’ve found this brand of record changer very reliable, requiring little in the way of fault-finding. This unit was no exception. However, as it is between 35 and 40 years old, the lubricants had dried out and needed to be replaced. I mounted the changer onto my servicing jig and then commenced siliconchip.com.au Photo Gallery: AWA Radiola 240 (1934) VALVES AUDIO HI-FI AMATEUR RADIO GUITAR AMPS INDUSTRIAL VINTAGE RADIO We can supply your valve needs, including high voltage capacitors, Hammond transformers, chassis, sockets and valve books. WE BUY, SELL and TRADE SSAE DL size for CATALOGUE ELECTRONIC VALVE & TUBE COMPANY PO Box 487 Drysdale, Vic 3222 76 Bluff Rd, St Leonards, 3223 Tel: (03) 5257 2297; Fax: (03) 5257 1773 Email: evatco<at>pacific.net.au www.evatco.com.au Released by AWA in 1934, the Radiola 240 is a 7-valve superheterodyne console that tunes the medium-wave band and two shortwave bands. An interesting feature of the circuit was the use of two RF amplifier stages ahead of the mixer, with the first stage switched into use only when the higherfrequency shortwave range was selected. The valve line-up was as follows: 6D6 1st RF amplifier; 6D6 2nd RF amplifier; 6A7 frequency changer, 6D6 IF amplifier (460kHz); 6B7 audio amplifier/detector/AVC rectifier; 42 audio output; and 80 rectifier. Photo: Historical Radio Society of Australia, Inc. removing the platter. This is achieved by removing the circlip in the centre but first the turntable switch should be in the off position (to disengage the idler wheel) and the turntable should rotate easily in a clockwise direction. It should then be possible siliconchip.com.au to ease the platter off its central shaft but in this case, it was reluctant to move upwards. Fortunately, I had some fine harddrawn steel wire from which I cut two lengths about 150 mm long. I put a hook in one end of both pieces and used them as a puller on the platter, twisting until it came free. Like the rest of the mechanism, it needed lubrication. I oiled the central shaft and the idler pulley. The motor is mounted on rubber grommet resilient mounts. Three circlips were removed from the mounts and the motor dropped down under the platform. Most of these motors can be dismantled by removing two screws. I did this but found that the bearings were not as accessible as in some other models. With some types, you can either lever a cover off the bearings or gain direct access to them. Usually alongside the bronze bearing is a felt wick which can be filled with oil to lubricate the bearing for many years. In this case, I just flooded the bearing and hoped that enough oil got to the wicks. Oil is used on bearings and shafts and grease is used on many of the sliding surfaces of the changer. The old congealed grease can be cleaned off with a kerosene-soaked rag and general purpose grease applied in its place. This isn’t an easy task and it may not always be possible to clean and replace all of the grease. It is just January 2006  107 Parts access under the chassis is good and the only faults found were the defective UCC and AEE capacitors. No valves required replacement. a matter of doing your best without dismantling the changer. There are three adjustments on these mechanisms but they seldom require attention. The first is the set-down position of the stylus onto the record and this is accessed under the tone-arm near the pivot (a horizontal screw). The second adjustment is the height of the tone-arm lift, accessed from the top of the tone-arm at the pivot point. This is adjusted so that the arm lifts high enough to clear a stack of six records. Mind you, it is not advisable to play a stack of six records on the changer. The weight of the stack on the spindle can easily damage the record centre holes, apart from any damage to the record surfaces from being in contact. Take my advice and play only one record at a time, to minimise any wear and tear. The third adjustment sets the stylus tracking weight – normally around five or six grams for a piezoelectric cartridge of this type. This involves This simple jig makes it much easier to service record turntables. 108  Silicon Chip adjusting a spring on the underside of the tone-arm and is easily done. The only other maintenance job is the replacement of the pick-up styli (78 and LP), as they have a fairly short life before becoming worn. A likely source of a suitable stylus for this and other radiograms is WES Components in Ashfield, NSW (phone 02 9797 9866). Purchase a diamond stylus rather than a sapphire one if possible, as they last considerably longer. Summary The B25/6 is a fairly basic single unit stereogram. It suited Mr and Mrs Average’s lounge-room decor of the era and did a creditable job of reproducing stereo records with pleasing audio quality. The radio performance is better than many receivers and the handspan dial is sufficiently large for accurate tuning. The set is reliable except for the use of the troublesome UCC and AEE capacitors. There was no other fault found and no valves required replacement. Despite its age the receiver still had its instruction manual. The original instruction books, licences, repair dockets and original carton can all add to the value of a set, historically as well as monetarily. I question the use of a 6X4 valve as the rectifier, as it is rated at a maximum of 70mA and a single 6AQ5 can draw around 45mA, although the 6AQ5s are drawing well under 45mA each in this set. Even so, I would have used a 6V4 rectifier which is rated at 90mA. In summary, a nice set and worthy SC of a place in any collection. siliconchip.com.au Salvage It! BY JULIAN EDGAR Building a human-powered LED torch for next to nothing Would you like to have a torch where you wind a knob just a few times and a white LED stays on brightly for two minutes and then remains visible for hours? Well you can and the only parts that you’ll have to buy new are the LED and the box to mount everything in. Y OU’LL NEED A VARIETY of components from different salvaged goods to make this design, so it’s one to keep in mind as you collect bits and pieces over a period. First, you need the turntable motor from a microwave oven. This is an AC synchronous motor that’s about 20mm high and 50mm in diameter. In addition to the motor, inside the package is a system of plastic reduction gears that normally gives an output shaft speed of just 5 RPM (or thereabouts). By turning this shaft with a knob, it’s possible to easily generate up to several hundred volts AC output! There’s our power source. WARNING! Exercise extreme caution when salvaging parts from a microwave oven. The large capacitors in the EHT (extra high tension) power supply can retain a lethal charge, even after the power has been switched off. Although these capacitors should be discharged by bleeder resistors when power is removed, don’t take it for granted. Older microwave ovens may not be fitted with bleeder resistors, or the resistors may have gone open circuit. For this reason, always make sure that the capacitors in the EHT supply have been discharged before removing parts from a microwave oven. Plugpack bits Next, a small transformer is need to step that voltage down to something that can be rectified (ie, converted to DC) and used to drive a LED. This can be done using one or more diodes or a bridge rectifier. And guess what – inside any older plugpack you’ll find just those components, already wired up and ready to go! Don’t pick a recent lightweight plugpack, though – these use switchmode circuits that don’t work in this application. You can also recognise a switchmode design by the large number of internal components. We tried a variety of older 240V plugpacks with transformers and those with nominal outputs in the range of 6-12V DC all worked well. Energy storage The primary components needed are the turntable motor from a microwave oven, an old plugpack and some high-value, low-voltage capacitors. These salvaged parts shouldn’t total more than a few dollars but be careful when salvaging the turntable motor – the bite from the EHT circuitry in a microwave oven can be lethal, even with the power off (see warning in article). siliconchip.com.au To store the power you’ve generated, you need lots of capacitors. In addition to being small enough to fit inside your chosen box, these should have as much capacitance as possible, while having a voltage rating of about 10-16V. Several 10,000uF 10V capacitors are ideal, for example, but it doesn’t matter if you use 10,000uF 16V caps instead. Electrolytic capacitors are January 2006  109 While it looks as though the parts might cost a fortune, all you need to buy are the high-brightness LED, the box and possibly the trimpot. The alternator and gearbox come from a discarded microwave oven, the transformer and rectifier diode from a salvaged plugpack and the capacitors from a wide range of junked electronic equipment. This “optioned-up” version also includes a neon lamp (salvaged from a cook-top) and a lens from a discarded video camera. used in nearly every piece of discarded electronics equipment – always keep an eye out for large-value low-voltage units to salvage. A 10-100kW trimpot (preferably multi-turn) will make it easy to set the LED current. Again, these can be salvaged from lots of gear but failing that, are cheap to buy new. Another essential item is a suitable knob, so that the shaft of the motor/ gearbox can be turned by hand. This knob will need to fit a D-shaped shaft and if you can’t salvage one for nothing, you’re not really trying! White LED You also need a white LED and this will probably have to be purchased. A 5mm high-brightness white LED works well. However, if you want more light output and are prepared to turn the knob more often, higher-rated units can be used. For example, with this design, a 1W Luxeon LED can be strongly il- luminated, although not to full brightness. However, the more powerful the LED, the shorter the time the capacitor pack will keep it on after you’ve stopped turning the knob. With the 1W Luxeon, the capacitor pack will drive the LED for less than a second, so in many ways a lower rated LED is more practical. (Note: if you use a powerful LED, you should uprate the power rating of the current limiting resistor.) Finally, if you want to build the “optioned-up” model, you’ll need a lens (one salvaged from an old video camera is perfect) and a neon indicator from an old stove or cook-top. Building it To allow testing, roughly assemble the electronic circuitry for the torch on the bench before building the final version into a box. The first step is fit the knob to the shaft. In my case, I used a knob taken from the dashboard heater controls of an old car. That done, connect a multimeter set to “AC Volts” to the output of the motor (now working as an alternator!). Now turn the knob but make sure that you’re not touching the output terminals. You should get a no-load output of 100–200V, depending on how fast you turn the knob. If you come in contact with the output when you are turning the knob, you will give yourself a shock, so be careful! Note that you should never try to wind the knob flat out – you’ll strip the gears inside if you do. Instead, just turn the knob progressively and evenly at a slow speed (the optioned-up model has this aspect covered)! Before pulling the plugpack apart, follow this simple procedure to check that it is suitable. First, connect the plugpack’s mains input terminals to the alternator outputs (polarity doesn’t matter). That done, connect the plugpack’s output to the capacitor pack, Fig.1: a salvaged microwave turntable motor is used as an alternator to generate high-voltage AC. This is then fed to a plugpack transformer and rectified to produce 6-12V DC by the innards of a plugpack. The capacitors are used for energy storage, while the trimpot allows the current through the LED to be adjusted to its rated value (or less). 110  Silicon Chip siliconchip.com.au Here’s the non-optioned version. It’s pretty simple to look at but by turning the knob a few times, you can have the LED shining brightly for about two minutes and then remaining visible for hours. taking care to connect negative output lead (usually black or non-striped) to the negative side of the pack. Now connect your multimeter (set to Volts DC) across the capacitor pack and turn the knob. You should be able to read a voltage that gradually rises as you keep on turning. Any voltage from about 6-12V is fine. The trimpot (wired as a variable resistor) and the LED can now be added to the circuit. The circuit will look like Fig.1, except you have to add your multimeter to measure the LED current. To do this, simply wire the multimeter (set to milliamps DC) in series with the LED. Next, set the trimpot to its highest resistance and turn the alternator knob 10 times. It’s then just a matter of slowly adjusting the trimpot until the maximum current rating of the LED is reached. For example, if the maximum current rating of the LED is 100mA, set the trimpot to provide this current flow. Check that further turning the alternator knob doesn’t cause the required value to be exceeded. Alternatively, you may want to set the trimpot so that the LED operates at less than full brightness, so that it stays on longer after you stop turning the knob. Final assembly The plugpack can be opened to retrieve the parts by crushing the case slowly in a bench vice until it cracks. That done, you can build the unit into an off-the-shelf jiffy box. Seal the box siliconchip.com.au (eg, with silicone sealant) if the torch is to be used in the rain or in wet areas. And the optioned-up model? Well, it includes a neon lamp wired straight across the alternator. This lights at any voltage over 70-100V (the voltage depends on the neon lamp) and so it’s a good guide as to when the knob is being turned quickly enough to generate sufficient power. In practice, it should only just light. Neon indicators salvaged from stoves and cook-tops already have a series resistor built into their bodies, in which case you can just wire it straight in. The second option is to add a lens. Our prototype used a video camera lens, supported by a cut-down section from a Portaflood light. This is ideal if you want a long narrow beam – the prototype has a beam range of at least SC 100 metres! This is the “optioned” version. Again, it’s just a matter of turning the knob a few times to get the LED shining. Other Versions In the February 2004 issue of SILICON CHIP we covered a different design of human-powered torch. That approach used a direct-drive stepper motor as the power source. So what are the advantages of taking the approach shown here? Because of the built-in gearing of the microwave oven motor, you can generate much more power in a shorter time – just a few turns of the knob will keep the LED brightly lit for a reasonable period. However, the use of a gearbox also has downsides – when being wound, the torch is noisier than a stepper motor design and the plastic gears have a finite life. Rat It Before You Chuck It! Whenever you throw away an old TV (or VCR or washing machine or dishwasher or printer) do you always think that surely there must be some good salvageable components inside? Well, this column is for you! (And it’s also for people without a lot of dough.) Each month we’ll use bits and pieces sourced from discards, sometimes in mini-projects and other times as an ideas smorgasbord. And you can contribute as well. If you have a use for specific parts which can easily be salvaged from goods commonly being thrown away, we’d love to hear from you. Perhaps you use the pressure switch from a washing machine to control a pump. Or maybe you have a use for the highquality bearings from VCR heads. Or perhaps you’ve found how the guts of a cassette player can be easily turned into a metal detector. (Well, we made the last one up but you get the idea . . .) If you have some practical ideas, write in and tell us! January 2006  111 Silicon Chip Back Issues May 1995: Guitar Headphone Amplifier; FM Radio Trainer, Pt.2; Transistor/Mosfet Tester For DMMs; A 16-Channel Decoder For Radio Remote Control; Introduction To Satellite TV. April 1989: Auxiliary Brake Light Flasher; What You Need to Know About Capacitors; 32-Band Graphic Equaliser, Pt.2. March 1993: Solar Charger For 12V Batteries; Reaction Trainer; Audio Mixer for Camcorders; A 24-Hour Sidereal Clock For Astronomers. May 1989: Build A Synthesised Tom-Tom; Biofeedback Monitor For Your PC; Simple Stub Filter For Suppressing TV Interference. April 1993: Solar-Powered Electric Fence; Audio Power Meter; ThreeFunction Home Weather Station; 12VDC To 70VDC Converter. June 1995: Build A Satellite TV Receiver; Train Detector For Model Railways; 1W Audio Amplifier Trainer; Low-Cost Video Security System; Multi-Channel Radio Control Transmitter For Models, Pt.1. July 1989: Exhaust Gas Monitor; Experimental Mains Hum Sniffers; Compact Ultrasonic Car Alarm; The NSW 86 Class Electrics. June 1993: AM Radio Trainer, Pt.1; Remote Control For The Woofer Stopper; Digital Voltmeter For Cars. September 1989: 2-Chip Portable AM Stereo Radio Pt.1; High Or Low Fluid Level Detector; Studio Series 20-Band Stereo Equaliser, Pt.2. July 1993: Single Chip Message Recorder; Light Beam Relay Extender; AM Radio Trainer, Pt.2; Quiz Game Adjudicator; Antenna Tuners – Why They Are Useful. July 1995: Electric Fence Controller; How To Run Two Trains On A Single Track (Incl. Lights & Sound); Setting Up A Satellite TV Ground Station; Build A Reliable Door Minder. October 1989: FM Radio Intercom For Motorbikes Pt.1; GaAsFet Preamplifier For Amateur TV; 2-Chip Portable AM Stereo Radio, Pt.2. November 1989: Radfax Decoder For Your PC (Displays Fax, RTTY & Morse); FM Radio Intercom For Motorbikes, Pt.2; 2-Chip Portable AM Stereo Radio, Pt.3; Floppy Disk Drive Formats & Options. January 1990: High Quality Sine/Square Oscillator; Service Tips For Your VCR; Active Antenna Kit; Designing UHF Transmitter Stages. February 1990: A 16-Channel Mixing Desk; Build A High Quality Audio Oscillator, Pt.2; The Incredible Hot Canaries; Random Wire Antenna Tuner For 6 Metres; Phone Patch For Radio Amateurs, Pt.2. March 1990: Delay Unit For Automatic Antennas; Workout Timer For Aerobics Classes; 16-Channel Mixing Desk, Pt.2; Using The UC3906 SLA Battery Charger IC. April 1990: Dual Tracking ±50V Power Supply; Voice-Operated Switch With Delayed Audio; 16-Channel Mixing Desk, Pt.3; Active CW Filter. August 1995: Fuel Injector Monitor For Cars; Gain Controlled Microphone Preamp; How To Identify IDE Hard Disk Drive Parameters. August 1993: Low-Cost Colour Video Fader; 60-LED Brake Light Array; Microprocessor-Based Sidereal Clock; Satellites & Their Orbits. September 1995: Railpower Mk.2 Walkaround Throttle For Model Railways, Pt.1; Keypad Combination Lock; Jacob’s Ladder Display. September 1993: Automatic Nicad Battery Charger/Discharger; Stereo Preamplifier With IR Remote Control, Pt.1; In-Circuit Transistor Tester; +5V to ±15V DC Converter; Remote-Controlled Cockroach. October 1995: 3-Way Loudspeaker System; Railpower Mk.2 Walkaround Throttle For Model Railways, Pt.2; Nicad Fast Charger. October 1993: Courtesy Light Switch-Off Timer For Cars; Wireless Microphone For Musicians; Stereo Preamplifier With IR Remote Control, Pt.2; Electronic Engine Management, Pt.1. November 1993: High Efficiency Inverter For Fluorescent Tubes; Stereo Preamplifier With IR Remote Control, Pt.3; Siren Sound Generator; Engine Management, Pt.2; Experiments For Games Cards. December 1993: Remote Controller For Garage Doors; LED Stroboscope; 25W Audio Amplifier Module; A 1-Chip Melody Generator; Engine Management, Pt.3; Index To Volume 6. January 1994: 3A 40V Variable Power Supply; Solar Panel Switching Regulator; Printer Status Indicator; Mini Drill Speed Controller; Stepper Motor Controller; Active Filter Design; Engine Management, Pt.4. July 1990: Digital Sine/Square Generator, Pt.1 (0-500kHz); Burglar Alarm Keypad & Combination Lock; Build A Simple Electronic Die; February 1994:90-Second Message Recorder; 12-240VAC 200W Inverter; 0.5W Audio Amplifier; 3A 40V Adjustable Power Supply; Engine Management, Pt.5; Airbags In Cars – How They Work. September 1990: 3-Digit Counter Module; Simple Shortwave Converter For The 2-Metre Band; Taking Care Of Nicad Battery Packs. October 1990: The Dangers of PCBs; Low-Cost Siren For Burglar Alarms; Dimming Controls For The Discolight; Surfsound Simulator; DC Offset For DMMs; NE602 Converter Circuits. November 1990: Connecting Two TV Sets To One VCR; Build An Egg Timer; Low-Cost Model Train Controller; 1.5V To 9V DC Converter; Introduction To Digital Electronics; A 6-Metre Amateur Transmitter. January 1991: Fast Charger For Nicad Batteries, Pt.1; Have Fun With The Fruit Machine (Simple Poker Machine); Two-Tone Alarm Module; The Dangers of Servicing Microwave Ovens. February 1991: A Practical Approach To Amplifier Design; Synthesised Stereo AM Tuner; Three Inverters For Fluorescent Lights; Low-Cost Sinewave Oscillator; Fast Charger For Nicad Batteries, Pt.2. May 1991: 13.5V 25A Power Supply For Transceivers; Stereo Audio Expander; Fluorescent Light Simulator For Model Railways; How To Install Multiple TV Outlets, Pt.1. July 1991: Loudspeaker Protector For Stereo Amplifiers; 4-Channel Lighting Desk, Pt.2; How To Install Multiple TV Outlets, Pt.2; Tuning In To Satellite TV, Pt.2. March 1994: Intelligent IR Remote Controller; 50W (LM3876) Audio Amplifier Module; Level Crossing Detector For Model Railways; Voice Activated Switch For FM Microphones; Engine Management, Pt.6. April 1994: Sound & Lights For Model Railway Level Crossings; Dual Supply Voltage Regulator; Universal Stereo Preamplifier; Digital Water Tank Gauge; Engine Management, Pt.7. May 1994: Fast Charger For Nicad Batteries; Induction Balance Metal Locator; Multi-Channel Infrared Remote Control; Dual Electronic Dice; Simple Servo Driver Circuits; Engine Management, Pt.8. June 1994: A Coolant Level Alarm For Your Car; 80-Metre AM/CW Transmitter For Amateurs; Converting Phono Inputs To Line Inputs; PC-Based Nicad Battery Monitor; Engine Management, Pt.9. May 1996: High Voltage Insulation Tester; Knightrider LED Chaser; Simple Intercom Uses Optical Cable; Cathode Ray Oscilloscopes, Pt.3. July 1996: VGA Digital Oscilloscope, Pt.1; Remote Control Extender For VCRs; 2A SLA Battery Charger; 3-Band Parametric Equaliser;. August 1996: Introduction to IGBTs; Electronic Starter For Fluores­cent Lamps; VGA Oscilloscope, Pt.2; 350W Amplifier Module; Masthead Amplifier For TV & FM; Cathode Ray Oscilloscopes, Pt.4. September 1996: VGA Oscilloscope, Pt.3; IR Stereo Headphone Link, Pt.1; HF Amateur Radio Receiver; Cathode Ray Oscilloscopes, Pt.5. October 1996: Send Video Signals Over Twisted Pair Cable; 600W DC-DC Converter For Car Hifi Systems, Pt.1; IR Stereo Headphone Link, Pt.2; Multi-Channel Radio Control Transmitter, Pt.8. November 1996: 8-Channel Stereo Mixer, Pt.1; Low-Cost Fluorescent Light Inverter; Repairing Domestic Light Dimmers; 600W DC-DC Converter For Car Hifi Systems, Pt.2. December 1996: Active Filter For CW Reception; Fast Clock For Railway Modellers; Laser Pistol & Electronic Target; Build A Sound Level Meter; 8-Channel Stereo Mixer, Pt.2; Index To Vol.9. January 1997: Control Panel For Multiple Smoke Alarms, Pt.1; Build A Pink Noise Source; Computer Controlled Dual Power Supply, Pt.1; Digi-Temp Thermometer (Monitors Eight Temperatures). July 1994: Build A 4-Bay Bow-Tie UHF TV Antenna; PreChamp 2-Transistor Preamplifier; Steam Train Whistle & Diesel Horn Simulator; 6V SLA Battery Charger; Electronic Engine Management, Pt.10. August 1994: High-Power Dimmer For Incandescent Lights; Dual Diversity Tuner For FM Microphones, Pt.1; Nicad Zapper (For Resurrecting Nicad Batteries); Electronic Engine Management, Pt.11. September 1994: Automatic Discharger For Nicad Batteries; MiniVox Voice Operated Relay; AM Radio For Weather Beacons; Dual Diversity Tuner For FM Mics, Pt.2; Electronic Engine Management, Pt.12. September 1991: Digital Altimeter For Gliders & Ultralights; Ultrasonic Switch For Mains Appliances; The Basics Of A/D & D/A Conversion. October 1994: How Dolby Surround Sound Works; Dual Rail Variable Power Supply; Talking Headlight Reminder; Electronic Ballast For Fluorescent Lights; Electronic Engine Management, Pt.13. October 1991: A Talking Voltmeter For Your PC, Pt.1; SteamSound Simulator For Model Railways Mk.II; Magnetic Field Strength Meter; Digital Altimeter For Gliders, Pt.2; Military Applications Of R/C Aircraft. November 1994: Dry Cell Battery Rejuvenator; Novel Alphanumeric Clock; 80-M DSB Amateur Transmitter; 2-Cell Nicad Discharger. February 1997: PC-Con­trolled Moving Message Display; Computer Controlled Dual Power Supply, Pt.2; Alert-A-Phone Loud Sounding Telephone Alarm; Control Panel For Multiple Smoke Alarms, Pt.2. March 1997: 175W PA Amplifier; Signalling & Lighting For Model Railways; Jumbo LED Clock; Cathode Ray Oscilloscopes, Pt.7. April 1997: Simple Timer With No ICs; Digital Voltmeter For Cars; Loudspeaker Protector For Stereo Amplifiers; Model Train Controller; A Look At Signal Tracing; Pt.1; Cathode Ray Oscilloscopes, Pt.8. May 1997: Neon Tube Modulator For Light Systems; Traffic Lights For A Model Intersection; The Spacewriter – It Writes Messages In Thin Air; A Look At Signal Tracing; Pt.2; Cathode Ray Oscilloscopes, Pt.9. June 1997: PC-Controlled Thermometer/Thermostat; TV Pattern Generator, Pt.1; Audio/RF Signal Tracer; High-Current Speed Controller For 12V/24V Motors; Manual Control Circuit For Stepper Motors. December 1991: TV Transmitter For VCRs With UHF Modulators; IR Light Beam Relay; Colour TV Pattern Generator, Pt.2; Index To Vol.4. December 1994: Car Burglar Alarm; Three-Spot Low Distortion Sinewave Oscillator; Clifford – A Pesky Electronic Cricket; Remote Control System for Models, Pt.1; Index to Vol.7. April 1992: IR Remote Control For Model Railroads; Differential Input Buffer For CROs; Aligning Vintage Radio Receivers, Pt.1. January 1995: Sun Tracker For Solar Panels; Battery Saver For Torches; Dual Channel UHF Remote Control; Stereo Microphone Pre­amp­lifier. June 1992: Multi-Station Headset Intercom, Pt.1; Video Switcher For Camcorders & VCRs; IR Remote Control For Model Railroads, Pt.3; 15-Watt 12-240V Inverter; A Look At Hard Disk Drives. February 1995: 2 x 50W Stereo Amplifier Module; Digital Effects Unit For Musicians; 6-Channel LCD Thermometer; Wide Range Electrostatic Loudspeakers, Pt.1; Remote Control System For Models, Pt.2. October 1992: 2kW 24VDC - 240VAC Sinewave Inverter; Multi-Sector Home Burglar Alarm, Pt.2; Mini Amplifier For Personal Stereos; A Regulated Lead-Acid Battery Charger. March 1995: 2 x 50W Stereo Amplifier, Pt.1; Subcarrier Decoder For FM Receivers; Wide Range Electrostatic Loudspeakers, Pt.2; IR Illuminator For CCD Cameras; Remote Control System For Models, Pt.3. February 1993: Three Projects For Model Railroads; Low Fuel Indicator For Cars; Audio Level/VU Meter (LED Readout); An Electronic Cockroach; 2kW 24VDC To 240VAC Sinewave Inverter, Pt.5. April 1995: FM Radio Trainer, Pt.1; Balanced Mic Preamp & Line Filter; 50W/Channel Stereo Amplifier, Pt.2; Wide Range Electrostatic Loudspeakers, Pt.3; 8-Channel Decoder For Radio Remote Control. ORDER FORM December 1995: Engine Immobiliser; 5-Band Equaliser; CB Transverter For The 80M Amateur Band, Pt.2; Subwoofer Controller; Knock Sensing In Cars; Index To Volume 8. June 1996: Stereo Simulator (uses delay chip); Rope Light Chaser; Low Ohms Tester For Your DMM; Automatic 10A Battery Charger. June 1990: Multi-Sector Home Burglar Alarm; Build A Low-Noise Universal Stereo Preamplifier; Load Protector For Power Supplies. August 1990: Universal Safety Timer For Mains Appliances (9 Minutes); Horace The Electronic Cricket; Digital Sine/Square Generator, Pt.2. November 1995: Mixture Display For Fuel Injected Cars; CB Trans­verter For The 80M Amateur Band, Pt.1; PIR Movement Detector. July 1997: Infrared Remote Volume Control; A Flexible Interface Card For PCs; Points Controller For Model Railways; Colour TV Pattern Generator, Pt.2; An In-Line Mixer For Radio Control Receivers. October 1997: 5-Digit Tachometer; Central Locking For Your Car; PCControlled 6-Channel Voltmeter; 500W Audio Power Amplifier, Pt.3. November 1997: Heavy Duty 10A 240VAC Motor Speed Controller; Easy-To-Use Cable & Wiring Tester; Build A Musical Doorbell; Replacing Foam Speaker Surrounds; Understanding Electric Lighting Pt.1. December 1997: Speed Alarm For Cars; 2-Axis Robot With Gripper; Stepper Motor Driver With Onboard Buffer; Power Supply For Stepper Motor Cards; Understanding Electric Lighting Pt.2; Index To Vol.10. January 1998: 4-Channel 12VDC or 12VAC Lightshow, Pt.1; Command Please send the following back issues:________________________________________ 112  Silicon Chip Enclosed is my cheque/money order for $­______or please debit my: o Bankcard o Visa Card o Master Card Card No. Signature ___________________________ Card expiry date_____ /______ Name ______________________________ Phone No (___) ____________ PLEASE PRINT Street ______________________________________________________ 112  Silicon Chip Suburb/town _______________________________ Postcode ___________ 10% OF SUBSCR F TO IB OR IF Y ERS OU 10 OR M BUY ORE Note: prices include postage & packing Australia ............................... $A8.80 (incl. GST) Overseas (airmail) ..................................... $A10 Detach and mail to: Silicon Chip Publications, PO Box 139, Collaroy, NSW, Australia 2097. Or call (02) 9979 5644 & quote your credit card siliconchip.com.au details or fax the details to (02) 9979 6503. Email: silchip<at>siliconchip.com.au February 1998: Telephone Exchange Simulator For Testing; Command Control For Model Railways, Pt.2; 4-Channel Lightshow, Pt.2. April 1998: Automatic Garage Door Opener, Pt.1; 40V 8A Adjustable Power Supply, Pt.1; PC-Controlled 0-30kHz Sinewave Generator; Understanding Electric Lighting; Pt.6. May 1998: 3-LED Logic Probe; Garage Door Opener, Pt.2; Command Control System, Pt.4; 40V 8A Adjustable Power Supply, Pt.2. June 1998: Troubleshooting Your PC, Pt.2; Universal High Energy Ignition System; The Roadies’ Friend Cable Tester; Universal Stepper Motor Controller; Command Control For Model Railways, Pt.5. July 1998: Troubleshooting Your PC, Pt.3; 15W/Ch Class-A Audio Amplifier, Pt.1; Simple Charger For 6V & 12V SLA Batteries; Auto­ matic Semiconductor Analyser; Understanding Electric Lighting, Pt.8. Controller; A MIDI Interface For PCs; Build The Bass Blazer; 2-Metre Groundplane Antenna; LP Doctor – Clean Up Clicks & Pops, Pt.2. Dirt Cheap, High-Current Power Supply; Low-Cost 50MHz Frequency Meter; Long-Range 16-Channel Remote Control System. March 2001: Making Photo Resist PC Boards; Big-Digit 12/24 Hour Clock; Parallel Port PIC Programmer & Checkerboard; Protoboards – The Easy Way Into Electronics, Pt.5; A Simple MIDI Expansion Box. November 2003: PC Board Design, Pt.2; 12AX7 Valve Audio Preamplifier; Our Best Ever LED Torch; Smart Radio Modem For Microcontrollers; PICAXE Pt.9; Programmable PIC-Powered Timer. April 2001: A GPS Module For Your PC; Dr Video – An Easy-To-Build Video Stabiliser; Tremolo Unit For Musicians; Minimitter FM Stereo Transmitter; Intelligent Nicad Battery Charger. December 2003: How To Receive Weather Satellite Images; SelfDiagnostics Plug For Cars; PC Board Design, Pt.3; VHF Receiver For Weather Satellites; Linear Supply For Luxeon 1W Star LEDs; 5V Meter Calibration Standard; PIC-Based Car Battery Monitor; PICAXE Pt.10. May 2001: 12V Mini Stereo Amplifier; Two White-LED Torches To Build; PowerPak – A Multi-Voltage Power Supply; Using Linux To Share An Internet Connection, Pt.1; Tweaking Windows With TweakUI. June 2001: Universal Battery Charger, Pt.1; Phonome – Call, Listen In & Switch Devices On & Off; Low-Cost Automatic Camera Switcher; Using Linux To Share An Internet Connection, Pt.2; A PC To Die For, Pt.1. August 1998: Troubleshooting Your PC, Pt.4; I/O Card With Data Logging; Beat Triggered Strobe; 15W/Ch Class-A Stereo Amplifier, Pt.2. July 2001: The HeartMate Heart Rate Monitor; Do Not Disturb Tele­phone Timer; Pic-Toc – A Simple Alarm Clock; Fast Universal Battery Charger, Pt.2; A PC To Die For, Pt.2; Backing Up Your Email. September 1998: Troubleshooting Your PC, Pt.5; A Blocked Air-Filter Alarm; Waa-Waa Pedal For Guitars; Jacob’s Ladder; Gear Change Indicator For Cars; Capacity Indicator For Rechargeable Batteries. August 2001: DI Box For Musicians; 200W Mosfet Amplifier Module; Headlight Reminder; 40MHz 6-Digit Frequency Counter Module; A PC To Die For, Pt.3; Using Linux To Share An Internet Connection, Pt.3. October 1998: AC Millivoltmeter, Pt.1; PC-Controlled Stress-O-Meter; Versatile Electronic Guitar Limiter; 12V Trickle Charger For Float Conditions; Adding An External Battery Pack To Your Flashgun. September 2001: Making MP3s; Build An MP3 Jukebox, Pt.1; PCControlled Mains Switch; Personal Noise Source For Tinnitus; Directional Microphone; Using Linux To Share An Internet Connection, Pt.4. November 1998: The Christmas Star; A Turbo Timer For Cars; Build A Poker Machine, Pt.1; FM Transmitter For Musicians; Lab Quality AC Millivoltmeter, Pt.2; Improving AM Radio Reception, Pt.1. November 2001: Ultra-LD 100W/Channel Stereo Amplifier, Pt.1; Neon Tube Modulator For Cars; Audio/Video Distribution Amplifier; Build A Short Message Recorder Player; Useful Tips For Your PC. December 1998: Engine Immobiliser Mk.2; Thermocouple Adaptor For DMMs; Regulated 12V DC Plugpack; Build A Poker Machine, Pt.2; Improving AM Radio Reception, Pt.2; Mixer Module For F3B Gliders. December 2001: IR Transceiver For PCs; 100W/Ch Stereo Amplifier, Pt.2; Pardy Lights Colour Display; PIC Fun – Learning About Micros. January 1999: High-Voltage Megohm Tester; A Look At The BASIC Stamp; Bargraph Ammeter For Cars; Keypad Engine Immobiliser. January 2002: Touch And/Or Remote-Controlled Light Dimmer, Pt.1; A Cheap ’n’Easy Motorbike Alarm; 100W /Channel Stereo Amplifier, Pt.3; Build A Raucous Alarm; FAQs On The MP3 Jukebox. March 1999: Build A Digital Anemometer; DIY PIC Programmer; Build An Audio Compressor; Low-Distortion Audio Signal Generator, Pt.2. February 2002: 10-Channel IR Remote Control Receiver; 2.4GHz High-Power Audio-Video Link; Touch And/Or Remote-Controlled Light Dimmer, Pt.2; Booting A PC Without A Keyboard; 4-Way Event Timer. April 1999: Getting Started With Linux; Pt.2; High-Power Electric Fence Controller; Bass Cube Subwoofer; Programmable Thermostat/ Thermometer; Build An Infrared Sentry; Rev Limiter For Cars. May 1999: The Line Dancer Robot; An X-Y Table With Stepper Motor Control, Pt.1; Three Electric Fence Testers; Carbon Monoxide Alarm. June 1999: FM Radio Tuner Card For PCs; X-Y Table With Stepper Motor Control, Pt.2; Programmable Ignition Timing Module For Cars, Pt.1. July 1999: Build A Dog Silencer; 10µH to 19.99mH Inductance Meter; Audio-Video Transmitter; Programmable Ignition Timing Module For Cars, Pt.2; XYZ Table With Stepper Motor Control, Pt.3. August 1999: Remote Modem Controller; Daytime Running Lights For Cars; Build A PC Monitor Checker; Switching Temperature Controller; XYZ Table With Stepper Motor Control, Pt.4; Electric Lighting, Pt.14. September 1999: Autonomouse The Robot, Pt.1; Voice Direct Speech Recognition Module; Digital Electrolytic Capacitance Meter; XYZ Table With Stepper Motor Control, Pt.5; Peltier-Powered Can Cooler. October 1999: Build The Railpower Model Train Controller, Pt.1; Semiconductor Curve Tracer; Autonomouse The Robot, Pt.2; XYZ Table With Stepper Motor Control, Pt.6; Introducing Home Theatre. November 1999: Setting Up An Email Server; Speed Alarm For Cars, Pt.1; LED Christmas Tree; Intercom Station Expander; Foldback Loudspeaker System; Railpower Model Train Controller, Pt.2. December 1999: Solar Panel Regulator; PC Powerhouse (gives +12V, +9V, +6V & +5V rails); Fortune Finder Metal Locator; Speed Alarm For Cars, Pt.2; Railpower Model Train Controller, Pt.3; Index To Vol.12. January 2000: Spring Reverberation Module; An Audio-Video Test Generator; Parallel Port Interface Card; Telephone Off-Hook Indicator. March 2002: Mighty Midget Audio Amplifier Module; 6-Channel IR Remote Volume Control, Pt.1; RIAA Pre­-A ­ mplifier For Magnetic Cartridges; 12/24V Intelligent Solar Power Battery Charger. April 2002:Automatic Single-Channel Light Dimmer; Pt.1; Water Level Indicator; Multiple-Output Bench Power Supply; Versatile Multi-Mode Timer; 6-Channel IR Remote Volume Control, Pt.2. May 2002: 32-LED Knightrider; The Battery Guardian (Cuts Power When the Battery Voltage Drops); Stereo Headphone Amplifier; Automatic Single-Channel Light Dimmer; Pt.2; Stepper Motor Controller. July 2002: Telephone Headset Adaptor; Rolling Code 4-Channel UHF Remote Control; Remote Volume Control For The Ultra-LD Stereo Amplifier; Direct Conversion Receiver For Radio Amateurs, Pt.1. August 2002: Digital Instrumentation Software For PCs; Digital Storage Logic Probe; Digital Therm./Thermostat; Sound Card Interface For PC Test Instruments; Direct Conversion Receiver For Radio Amateurs. September 2002: 12V Fluorescent Lamp Inverter; 8-Channel Infrared Remote Control; 50-Watt DC Electronic Load; Spyware – An Update. October 2002: Speed Controller For Universal Motors; PC Parallel Port Wizard; Cable Tracer; AVR ISP Serial Programmer; 3D TV. November 2002: SuperCharger For NiCd/NiMH Batteries, Pt.1; Windows-Based EPROM Programmer, Pt.1; 4-Digit Crystal-Controlled Timing Module; Using Linux To Share An Optus Cable Modem, Pt.1. December 2002: Receiving TV From Satellites; Pt.1; The Micromitter Stereo FM Transmitter; Windows-Based EPROM Programmer, Pt.2; SuperCharger For NiCd/NiMH Batteries; Pt.2; Simple VHF FM/AM Radio; Using Linux To Share An Optus Cable Modem, Pt.2. February 2000: Multi-Sector Sprinkler Controller; A Digital Voltmeter For Your Car; Safety Switch Checker; Sine/Square Wave Oscillator. January 2003: Receiving TV From Satellites, Pt 2; SC480 50W RMS Amplifier Module, Pt.1; Gear Indicator For Cars; Active 3-Way Crossover For Speakers; Using Linux To Share An Optus Cable Modem, Pt.3. March 2000: Resurrecting An Old Computer; 100W Amplifier Module, Pt.1; Electronic Wind Vane With 16-LED Display; Glowplug Driver. February 2003: PortaPal PA System, Pt.1; SC480 50W RMS Amplifier Module, Pt.2; Windows-Based EPROM Programmer, Pt.3; Using Linux To Share An Optus Cable Modem, Pt.4; Fun With The PICAXE, Pt.1. May 2000: Ultra-LD Stereo Amplifier, Pt.2; LED Dice (With PIC Microcontroller); 50A Motor Speed Controller For Models. June 2000: Automatic Rain Gauge; Parallel Port VHF FM Receiver; Switchmode Power Supply (1.23V to 40V) Pt.1; CD Compressor. March 2003: LED Lighting For Your Car; Peltier-Effect Tinnie Cooler; PortaPal PA System, Pt.2; 12V SLA Battery Float Charger; Little Dynamite Subwoofer; Fun With The PICAXE, Pt.2 (Shop Door Minder). July 2000: Moving Message Display; Compact Fluorescent Lamp Driver; Musicians’ Lead Tester; Switchmode Power Supply, Pt.2. April 2003: Video-Audio Booster For Home Theatre Systems; Telephone Dialler For Burglar Alarms; Three PIC Programmer Kits; PICAXE, Pt.3 (Heartbeat Simulator); Electric Shutter Release For Cameras. August 2000: Theremin; Spinner (writes messages in “thin-air”); Proximity Switch; Structured Cabling For Computer Networks. May 2003: Widgybox Guitar Distortion Effects Unit; 10MHz Direct Digital Synthesis Generator; Big Blaster Subwoofer; Printer Port Simulator; PICAXE, Pt.4 (Motor Controller). September 2000: Swimming Pool Alarm; 8-Channel PC Relay Board; Fuel Mixture Display For Cars, Pt.1; Protoboards – The Easy Way Into Electronics, Pt.1; Cybug The Solar Fly. October 2000: Guitar Jammer; Breath Tester; Wand-Mounted Inspection Camera; Subwoofer For Cars; Fuel Mixture Display, Pt.2. June 2003: PICAXE, Pt.5; PICAXE-Controlled Telephone Intercom; PICAXE-08 Port Expansion; Sunset Switch For Security & Garden Lighting; Digital Reaction Timer; Adjustable DC-DC Converter For Cars; Long-Range 4-Channel UHF Remote Control. November 2000: Santa & Rudolf Chrissie Display; 2-Channel Guitar Preamplifier, Pt.1; Message Bank & Missed Call Alert; Protoboards – The Easy Way Into Electronics, Pt.3. July 2003: Smart Card Reader & Programmer; Power-Up Auto Mains Switch; A “Smart” Slave Flash Trigger; Programmable Continuity Tester; PICAXE Pt.6 – Data Communications; Updating The PIC Programmer & Checkerboard; RFID Tags – How They Work. December 2000: Home Networking For Shared Internet Access; White LED Torch; 2-Channel Guitar Preamplifier, Pt.2 (Digital Reverb); Driving An LCD From The Parallel Port; Index To Vol.13. August 2003: PC Infrared Remote Receiver (Play DVDs & MP3s On Your PC Via Remote Control); Digital Instrument Display For Cars, Pt.1; Home-Brew Weatherproof 2.4GHz WiFi Antennas; PICAXE Pt.7. January 2001: How To Transfer LPs & Tapes To CD; The LP Doctor – Clean Up Clicks & Pops, Pt.1; Arbitrary Waveform Generator; 2-Channel Guitar Preamplifier, Pt.3; PIC Programmer & TestBed. siliconchip.com.au September 2003: Robot Wars; Krypton Bike Light; PIC Programmer; Current Clamp Meter Adapter For DMMs; PICAXE Pt.8 – A Data Logger; Digital Instrument Display For Cars, Pt.2. February 2001: An Easy Way To Make PC Boards; L’il Pulser Train October 2003: PC Board Design, Pt.1; JV80 Loudspeaker System; A January 2004: Studio 350W Power Amplifier Module, Pt.1; HighEfficiency Power Supply For 1W Star LEDs; Antenna & RF Preamp For Weather Satellites; Lapel Microphone Adaptor For PA Systems; PICAXE-18X 4-Channel Datalogger, Pt.1; 2.4GHZ Audio/Video Link. February 2004: PC Board Design, Pt.1; Supply Rail Monitor For PCs; Studio 350W Power Amplifier Module, Pt.2; Shorted Turns Tester For Line Output Transformers; PICAXE-18X 4-Channel Datalogger, Pt.2. March 2004: PC Board Design, Pt.2; Build The QuickBrake For Increased Driving Safety; 3V-9V (or more) DC-DC Converter; ESR Meter Mk.2, Pt.1; PICAXE-18X 4-Channel Datalogger, Pt.3. April 2004: PC Board Design, Pt.3; Loudspeaker Level Meter For Home Theatre Systems; Dog Silencer; Mixture Display For Cars; ESR Meter Mk.2, Pt.2; PC/PICAXE Interface For UHF Remote Control. May 2004: Amplifier Testing Without High-Tech Gear; Component Video To RGB Converter; Starpower Switching Supply For Luxeon Star LEDs; Wireless Parallel Port; Poor Man’s Metal Locator. June 2004: Dr Video Mk.2 Video Stabiliser; Build An RFID Security Module; Fridge-Door Alarm; Courtesy Light Delay For Cars; Automating PC Power-Up; Upgraded Software For The EPROM Programmer. July 2004: Silencing A Noisy PC; Versatile Battery Protector; Appliance Energy Meter, Pt.1; A Poor Man’s Q Meter; Regulated High-Voltage Supply For Valve Amplifiers; Remote Control For A Model Train Layout. August 2004: Video Formats: Why Bother?; VAF’s New DC-X Generation IV Loudspeakers; Video Enhancer & Y/C Separator; Balanced Microphone Preamp; Appliance Energy Meter, Pt.2; 3-State Logic Probe. September 2004: Voice Over IP (VoIP) For Beginners; WiFry – Cooking Up 2.4GHz Antennas; Bed Wetting Alert; Build a Programmable Robot; Another CFL Inverter. October 2004: The Humble “Trannie” Turns 50; SMS Controller, Pt.1; RGB To Component Video Converter; USB Power Injector; Remote Controller For Garage Doors & Gates. November 2004: 42V Car Electrical Systems; USB-Controlled Power Switch (Errata Dec. 2004); Charger For Deep-Cycle 12V Batteries, Pt.1; Driveway Sentry; SMS Controller, Pt.2; PICAXE IR Remote Control. December 2004: Build A Windmill Generator, Pt.1; 20W Amplifier Module; Charger For Deep-Cycle 12V Batteries, Pt.2; Solar-Powered Wireless Weather Station; Bidirectional Motor Speed Controller. January 2005: Windmill Generator, Pt.2; Build A V8 Doorbell; IR Remote Control Checker; 4-Minute Shower Timer; The Prawnlite; Sinom Says Game; VAF DC-7 Generation 4 Kit Speakers. February 2005: Windmill Generator, Pt.3; USB-Controlled Electrocardiograph; TwinTen Stereo Amplifier; Inductance & Q-Factor Meter, Pt.1; A Yagi Antenna For UHF CB; $2 Battery Charger. March 2005: Windmill Generator, Pt.4; Sports Scoreboard, Pt.1; Swimming Pool Lap Counter; Inductance & Q-Factor Meter, Pt.2; Shielded Loop Antenna For AM; Cheap UV EPROM Eraser; Sending Picaxe Data Over 477MHz UHF CB; $10 Lathe & Drill Press Tachometer. April 2005: Install Your Own In-Car Video (Reversing Monitor); Build A MIDI Theremin, Pt.1; Bass Extender For Hifi Systems; Sports Scoreboard, Pt.2; SMS Controller Add-Ons; A $5 Variable Power Supply. May 2005: Getting Into Wi-Fi, Pt.1; Build A 45-Second Voice Recorder; Wireless Microphone/Audio Link; MIDI Theremin, Pt.2; Sports Scoreboard, Pt.3; Automatic Stopwatch Timer. June 2005: Wi-Fi, Pt.2; The Mesmeriser LED Clock; Coolmaster Fridge/ Freezer Temperature Controller; Alternative Power Regular; PICAXE Colour Recognition System; AVR200 Single Board Computer, Pt.1. July 2005: Getting Into Wi-Fi, Pt.3; Remote-Controlled Automatic Lamp Dimmer; Lead-Acid Battery Zapper; Serial Stepper Motor Controller; AVR200 Single Board Computer, Pt.2; Salvaging & Using Thermostats; Unwired Modems & External Antennas; PICAXE in Schools, Pt.3. August 2005: Mudlark A205 Valve Stereo Amplifier, Pt.1; Programmable Flexitimer; Carbon Monoxide Alert; Serial LCD Driver; Enhanced Sports Scoreboard; Salvaging Washing Maching Pressure Switches. September 2005: Build Your Own Seismograph; Bilge Sniffer For Boats; VoIP Analog Phone Adaptor; Mudlark A205 Valve Stereo Amplifier, Pt.2; PICAXE in Schools, Pt.4. October 2005: A Look At Google Earth; Dead Simple USB Breakout Box; Studio Series Stereo Preamplifier, Pt.1; Video Reading Aid For Vision Impaired People; Simple Alcohol Level Meter; Ceiling Fan Timer. November 2005: Good Quality Car Sound On The Cheap; Pt.1; Microbric – Robotics For Everyone; PICAXE In Schools, Pt.5; Studio Series Stereo Headphone Amplifier; Build A MIDI Drum Kit, Pt.1; Serial I/O Controller & Analog Sampler; Delta XL02 Tower Loudspeaker System. December 2005: Good Quality Car Sound On The Cheap; Pt.2; Building The Ultimate Jukebox, Pt.1; Universal High-Energy Ignition System, Pt.1; Remote LED Annunciator For Queue Control; Build A MIDI Drum Kit, Pt.2; 433MHz Wireless Data Communication. PLEASE NOTE: issues not listed have sold out. All other issues are in stock. We can supply photostat copies from sold-out issues for $8.80 per article (includes p&p). When supplying photostat articles or back copies, we automatically supply any relevant notes & errata at no extra charge. January 2006  113 A complete index to all articles published to date can be downloaded free from our web site: www.siliconchip.com.au 113  January 2006 Control For Model Railways, Pt.1; Pan Controller For CCD Cameras. ASK SILICON CHIP Got a technical problem? Can’t understand a piece of jargon or some technical principle? Drop us a line and we’ll answer your question. Write to: Ask Silicon Chip, PO Box 139, Collaroy Beach, NSW 2097; or send an email to silchip<at>siliconchip.com.au Garage door indicator wanted Do you have a design for a garage door monitor which would transmit the state of the door to an indicator in the house? I have seen a commercial design which mounts a reflector on the door and then sends an infrared beam to that reflector. It has a radio link to the house-mounted indicator. (K. A., Sale, Vic). • We do not have a suitable design although it would probably be possible to adapt the 4-channel UHF remote switch using latched outputs on the decoder. This was published in the July 2002 issue. Recording LPs onto CDs Have you ever published a circuit for a cheap phono preamp to connect to a computer using the computer’s 12V supply and maybe an LM833. This would enable you to record old records onto HDD and burn MP3 CDs – all for under $10. I think a lot of people have old records that they would like to transfer to CD and a cheap preamp powered by the computer power supply would be an alternative. (R. B., via email). • Have a look at our RIAA Preamplifier for Magnetic Cartridges in the March 2002 issue. This uses a total supply voltage of 30V (ie, +15V, -15V) to get good overload margin from the preamp. It is not possible to get a sufficient overload margin from an RIAA preamp using only a 12V supply. Double-heading with the Li’l Pulser I have seen part of the article on “Li’l Pulser Train controller” (SILICON CHIP, February 2001). It may do the job I want but I would like to know if it is capable of running more than one loco (up to three). Also, where can I get a kit if one is available or a PC board? (R. H., via email). • The specified power supply is rated at 1A, so it depends on how much your locos draw. It should cope with at least two. If you use a bigger power supply and mount the Mosfet on a bigger heatsink, the circuit can deliver a lot more power and so you could hook up more locos. However, it is generally advisable to use identical locos when 6V Operation For New Ignition System I have already purchased a kit for the new version of the Electronic Ignition, as featured in the December 2005 issue. I am pleased that you have achieved a reduction in the coil current (coil heating) because the application I have in mind (a motorcycle restoration) has “delicate” coil hardware and excess heating has resulted in dead coils. It is a 6V motorcycle and coils for these are getting hard to source. This brings me to my first question: could this project be used for a 6V application? Would this new version be more frugal in the watts department and would it function 114  Silicon Chip on a (kick-start) motorcycle with only a 6V supply? Finally, I was disappointed to note that there has been no reduction in the size of the case. There simply isn’t room on a modern (post 1960) motorcycle for a large diecast box! With the reduction achieved in coil current, couldn’t some reduction in box size be achieved? (R. J., via email). • The new ignition system will work on a 6V battery. And you could use a box smaller in height, provided the power transistor was mounted horizontally inside the case. “double-heading” otherwise one loco will try to do the lion’s share and will end up spinning its wheels. The kit is available from Jaycar (Cat. KC-5304). High-power ultrasonic pigeon deterrent We need to amplify ultrasonic signals to over 100dB. I plan on using a Stamp 2 module to generate the signals and feed them to your Studio 350 Amplifier. We want to generate these frequencies to repel seagulls and pigeons from factory roofs. We have done our tests and believe we know what sequence of frequencies is required. They range from 15-30kHz. We need to connect up to 40 tweeters (Jaycar Cat. CT-1912), all with 100m of cable to a central box which includes the microcontroller and amplifier. A salesperson at Jaycar Electronics said the Studio 350 will handle frequencies up to 60kHz so I presumed it would be good enough to amplify the frequencies generated from my microcontroller. What type of PA would you recommend I need to interface to the amplifier to achieve this? (V. J., St Albans, NSW). • Unfortunately, your scheme won’t work. For a start, the Studio 350 is not suitable for high power delivery at supersonic frequencies. Its output filter will burn out and the output transistors will all overheat. It would need a substantial re-design to make it suitable. Second, it could not drive 40 tweeters, or anything like that number, and that particularly applies if the tweeters you propose to use are piezoelectric. This is because piezo tweeters are capacitive and therefore their impedance is very low at supersonic frequencies. We do not know of any amplifier design which will deliver its rated power at 30kHz, let alone 60kHz. While typical audio amplifiers may have a frequency response to 100kHz and beyond, their power response is typically not much beyond 20kHz. siliconchip.com.au You would need an amplifier specially designed to drive piezo electric transducers, as in high-power ultrasonic cleaning baths. Ultimately, you would probably be better off using a very high power frequency-modulated oscillator, with transformer coupling to the tweeters. We have used a similar approach in past projects to discourage dogs from barking: (1) Woofer Stopper Mk2, February 1996; (2) Dog Silencer, July 1999; and (3) Dog Silencer Mk2, April 2004. We can supply these articles at $8.80 each, including postage. You could take the same approach but at a much higher power level. The circuits all use power Mosfets in the output so it would be possible to increase the power substantially by using more Mosfets but the gate drive circuits would also have to be considerably beefed up. The transformer would be a specially wound job. We suggest you contact Harbuch Electronics. Phone (02) 9476 5854. Where to obtain 240VAC-rated resistors Triac Failure in USB Powerboard I built two of USB-activated powerboards (SILICON CHIP, November 2004) and they worked fine for a while. The Triac in both units then failed short-circuit between pins 1 & 2 and powers the board at all times, even when the computer is off. I measured the worst-case current draw of my three peripherals – a small desk fan, scanner and printer – at 0.1A, 0.2A and 2.4A, respectively. This appears well within the 3A limit for the board. I replaced the Triac in one unit with a BT136 600E, which is the same as was supplied in the Jaycar kit. This too failed after four days, in the same manner as the original. I referred to the parts list in the Jaycar instructions and note that it calls for a BT136 6A 500V unit but the parts layout lists a BT136F. My perusal of the specifications of both online seem to show they are compatible. Should I be using a BT136F, a small heatsink or are my peripherals too close to the current limit? (F. W., via email). • There is not much difference between the BT137F-600 Triac which we originally specified and A number of your projects use 240VAC-rated resistors (eg, Philips VR25 1.2MW). I have not been able to find a supplier for these type of resistors. Could you advise of any known retailers, especially in the Canberra region? (I. F., via email). • VR25 resistors (0.25W, 1150VAC rated) are available from Farnell, phone 1300 361 005 or browse to www.farnellinone.com.au. The stock number for a 1.2MW resistor is 341629 or 9477152, while a 1.5MW resistor as used in the Fan Timer (SILICON CHIP, October 2005) has a stock number of 341630 or 9477160. Could you please advise me how to do this? (M. I., via email). • In addition to adding the extra pushbutton switches to trigger each of the eight message areas individually for random-access operation, you also need to switch the RE-bar (record enable) input of the HK828 chip (pin 27) high for recording mode and low for playback mode. If you do this, you should find that it works correctly. Multiple message mode for voice recorder After-market chip for Land Rover I purchased the Voice Recorder kit (SILICON CHIP, May 2005) and it operates in single message mode with no faults. I have now programmed the module to run in random access mode for eight fixed messages, having installed the extra pushbuttons which now become the record/start play for each message. I have not been able to work out how to record the individual messages though. I am considering installing an aftermarket computer chip in a Land Rover Discovery. Can you tell me whether this is a safe modification and is a plugin unit better than making changes to the settings in the ECU? (N. W., via email). • We are not in a position to make recommendations concerning ECU chips for cars. However, unless the chip has been specifically tailored for siliconchip.com.au the BT136F-600 device which we understand Jaycar have supplied in their kits. The main difference is that the BT137F has higher RMS and peak non-repetitive current ratings – 8A and 55A respectively versus the 4A and 25A ratings for the BT136F. As you suggest, these differences shouldn’t normally make much difference in the USB Powerboard project, because the average load current should be below 3A anyway and the peak currents shouldn’t even reach 25A. You don’t advise in your email where you are operating your own unit but if it’s in the country, your power lines may be subject to fairly severe “spikes” due to lightning strikes, etc. Perhaps these could have caused the damage. We suggest that you try replacing the damaged Triacs with BT137F-600 or even BT137F-800 devices if you can get them, to make the units more “rugged”. It might also be a good idea to feed your computer and the USB powerboard through a power line filter and surge suppressor unit. your vehicle, it is unlikely to provide any improvements to the engine. If you want a tailored system, you will be best served by a workshop team who can dyno tune the engine and alter the code within the ECU. Any overthe-counter chips that simply plug into the ECU cannot be guaranteed to provide any improvements and may cause engine damage. Unmute for portable PA I have built two PortaPAL PA kits (SILICON CHIP, February & March 2003) which work well and are good value for money. I would like to be able to bypass the “Mute” stage during a live performance, to prevent the truncation of the first few seconds of a song. Is it possible to do this and if so, how can I go about it? (D. R., via email). • Pin 4 of IC9 (TDA1562Q) should be tied to +12V to disable the muting. The connection to pin 7 of IC6b should be January 2006  115 Mobile Phone Jammer Wanted Have you ever produced, intend to produce or would consider producing a mobile phone jammer (if this is possible)? I work in a customer service field and there is nothing more frustrating than the rude customer who comes up to the counter while talking on their mobile phone, or indeed even takes a call at the counter and expects you and all those behind them to wait while they complete their call. I see this happening with increasing regularity, not only at my place of work but also at the supermarket, bank, post office, and anywhere else I find I need to queue. It would ideally be a low-powered unit that could be concealed broken when doing this. A single-pole double-throw (SPDT) switch could be used with the wiper of the switch connecting to pin 4 of IC9. Connect +12V to one side of the switch and pin 7 of IC6b to the other side. There is a link on the PC board between IC7 and IC8 that connects pin 4 of IC9 to pin 7 of IC6b. This can be cut to enable the switch connection, while +12V can be obtained at pin 7 of IC8. What are impedance protected motors? What does “Impedance Protected” mean? The statement “Impedance Protected” appears on a new in-line ventilation 240V fan I am using. I know it’s an induction motor type, so I guess on your person, with a range of about two metres or so, and able to be left on all day so it affected all phones within range and prevented then from ringing in the first place, or caused them to drop out as they were brought into range. (T. L., via email). • You want a “cone of silence”, don’t you? We doubt whether there is any low-power jamming device which would be effective on a mobile phone (and if there was, it would be illegal). As you know, two or more mobile phones can be used in fairly close proximity without interference to each other. People who behave like that are very annoying though! it has something to do with protecting the motor’s windings. But I don’t know how, what or why. I have asked my father this, as he’s a Visiting Professor Of Faculty Of Engineering. He doesn’t know either, which is strange. Perhaps you can answer this interesting question. (A. B., via email). • Impedance protection prevents motor burnout if the fan is jammed. It is achieved by having high resistance windings, normally in a shaded-pole motor. IR train detector needs pulsed signal I have made several attempts to construct an IR train detector for my model train. I have found circuits in my model rail books dating back 10 years. I have also bought kits, some too expensive to duplicate and others where the parts are not clearly marked or the provider will not tell me the component values. The circuit I have sent to you is the easiest one I have found but the LED is on all the time when I apply 12V filtered DC. I have tried changing the value of R1 downwards and have also tried D1 and Q1 from different sources to no avail. Could you help me out here? I am a novice electronics user, although I have had previous success with other circuits. (G. J., via email). • We are unable to assist with troubleshooting of circuits not published by us. We have not published an IR train detector but would suggest that you could base one on the infrared light beam relay in the December 1991 issue or the Infrared Sentry in the April 1999 issue. Both circuits use a pulsed IR signal – any other approach is futile. Projects suitable for diesel vehicles Are the projects described in “Performance Electronics for Cars” suitable for diesel vehicles? I bought the book so that I could build the Intelligent Turbo Timer device for my vehicle which is a turbo diesel. What other projects in the book are applicable to diesels? (G. B., via email). • Most of the projects are applicable to diesels. These include the timer, the frequency, temperature and voltage switches, speedo corrector and thermometer. The adjusters may or may not be applicable, depending on the type of engine management in the SC diesel vehicle. WARNING! SILICON CHIP magazine regularly describes projects which employ a mains power supply or produce high voltage. All such projects should be considered dangerous or even lethal if not used safely. Readers are warned that high voltage wiring should be carried out according to the instructions in the articles. When working on these projects use extreme care to ensure that you do not accidentally come into contact with mains AC voltages or high voltage DC. If you are not confident about working with projects employing mains voltages or other high voltages, you are advised not to attempt work on them. Silicon Chip Publications Pty Ltd disclaims any liability for damages should anyone be killed or injured while working on a project or circuit described in any issue of SILICON CHIP magazine. Devices or circuits described in SILICON CHIP may be covered by patents. SILICON CHIP disclaims any liability for the infringement of such patents by the manufacturing or selling of any such equipment. SILICON CHIP also disclaims any liability for projects which are used in such a way as to infringe relevant government regulations and by-laws. Advertisers are warned that they are responsible for the content of all advertisements and that they must conform to the Trade Practices Act 1974 or as subsequently amended and to any governmental regulations which are applicable. 116  Silicon Chip siliconchip.com.au Notes & Errata Inductance & Q-factor Meter (February & March 2005): an update for the AT90S2313 microcontroller firmware (v1.1) is now available from our website. The update incorporates two major changes from the initial release, which are: (1) the meter now reads up to 10mH as originally described; and (2) the meter indicates when both L and Q values are out of bounds (indicated by the letter “E” on the display). In addition, to improve meter performance when measuring certain combinations of L & Q, install two pairs of series diodes in parallel with the test terminals, as shown in the accompanying circuit diagram. The diodes can be fitted on the copper side of the PC board (see photo) and must be 1N4148 small-signal types. The diodes act as dampers, serving to lower the peak of the ringing waveform to below 1.2V as quickly as possible. The author also offers the following additional information on the meter’s operation in regard to outof-bounds detection and display: The meter measures frequency and decay constant, so L and Q are derived quantities. This means that a Q value will be out of bounds when the meter can not acquire IO Controller, November 2005: the PC board pattern erroneously connects the positive lead of the 220mF supply-rail filter capacitor to the anode of diode D1. It should instead go to D1’s cathode. The circuit diagram on page 73 (Fig.3) of November 2005 is correct. While the circuit will still work in this configuration, there is no reverse polarity protection for the 220mF capacitor if the power supply is connected the wrong way around. The solution is to mount the 220mF capacitor as shown in the accompanying diagram. This involves drilling a small hole in the PC board at the indicated location, to accept the capacitor’s positive lead. This lead is then be bent flat against the PC board and soldered to D1’s adjacent cathode pad. siliconchip.com.au sufficient periods of oscillatory decay to reliably calculate a decay constant. This can occur for one of three reasons: (1) the Q is too low; (2) the Q is too high, so that negligible decay is observed on the scale of several hundred oscillations; or (3) the decay occurs on a very large time scale outside the range of the meter (this can occur when the measured frequency drops to several tens of kilohertz). Note that an out-of-bounds Q does not automatically indicate that L and F are also unobtainable. These parameters will continue to be displayed, although their precision generally drops to around 1020% of nominal. If no stable value for F can be had, then the L and F displays will blank out and a sole “E” will show in the Q position. K K A A Constructors should also be aware that LC circuits can have parasitic oscillations. If these are large, they can register as an incorrect value for L. This occurs because some inductors can not be well approximated by a simple theoretical L, so there is no unique answer to “what is the value of this inductor?”. Nevertheless, the value derived from the frequency of oscillation with a given capacitor is a perfectly legitimate result, though if one were to make measurements at other frequencies, or use V = L x dI/dt to get L, a different answer could be obtained. In other words, some thought must be given to the details of the measurement, rather than relying solely on the instrument to produce the magic number! to see if the modification is necessary. In addition, there was a bug in the Windows interface software that prevented the input values from being displayed on machines running Windows XP. This has now been corrected and the revised software posted on our website. Note that only early kit versions should need this modification, as later kit versions will be supplied with a corrected PC board. Check your supplied PC board carefully Universal High-Energy Ignition System, December 2005: there are several errors in the parts list published in Pt.1. In the main section, there should be three (not two) 100mF capacitors, the LM2940CT-5 regulator should be designated REG1 and there should be three (not two) crimp eyelets. In addition, the 22W resistor listed under the “Optical Pickup Version” heading should in fact be 22kW. January 2006  117 MARKET CENTRE Cash in your surplus gear. Advertise it here in Silicon Chip. FOR SALE PCBs MADE, ONE OR MANY. Any format, hobbyists welcome. Sesame Electronics Phone (02) 9593 1025. sesame<at>sesame.com.au www.sesame.com.au SUPERBRIGHT LEDS from just 15 cents each, including new wide angle range! 12 volt LED lightbars, great for solar/camping. Nixie tubes and nixie clock kits. Lots of other stuff, and always more items being added. New webshop now online! www.ledsales.com.au RCS RADIO/DESIGN is at 41 Arlewis St, Chester Hill 2162, NSW Australia and has all the published PC boards from SC, EA, ETI, HE, AEM & others. Ph (02) 9738 0330. sales<at>rcsradio. com.au, www.rcsradio.com.au USB KITS: Gas Sensors (CO, LPG, Alcohol), GPIB Interface, Thermostat Tester, LCD Module Interface, Stepper Motor Controller, PIO Interface, DTMF Transceiver, Thermometer, DDS HF Generator, Compass, 4 Channel Volt­meter, I/O Relay Card, USB via Lab­VIEW. Also available: Digital Oscillo­ scope, Temperature Loggers, VHF Receivers and USB ActiveX (and USBDOS.exe file) to control our kits from your own application. www.ar.com. au/~softmark SMD COMPONENTS: 1 Watt SMD LEDs & specials. Go to www.lazer. com.au ImageCraft C Compilers: 32-bit Wind­ows IDE and compiler. For AVR, 68HC­ 08, 68HC11, 68HC12, 68HC16. from $330.00 Atmel Flash CPU Programmer: Handles the 89Cx051, 89C5x, 89Sxx in both DIP and PLCC44 and some AVR’s, most 8-pin EEPROMS. Includes socket for serial ISP cable. $220, $11 p&p. SOIC adaptors: 20 pin $132.00, 14 pin $126.50, 8 pin $121.00. Full details on web-site. Credit cards accepted. GRANTRONICS PTY LTD, PO Box 275, Wentworthville 2145. (02) TAIG MACHINERY Micro Mini Lathes and Mills From $489.00 Stepper motors: 200 oz in $89.00, 330 oz in $110.00 Digital verniers: 150mm $55.00, 200mm $65.00 59 Gilmore Crescent (02) 6281 5660 Garran ACT 2605 0412269707        118  Silicon Chip 9896 7150 or http://www.grantronics. com.au MORE CONTROL SOLUTIONS for you: Tachometer Panel Meter Display: Fully programmable – you can monitor engine speeds & other frequency sources. RF Coax Adaptor Kit: 40 piece gold plated adaptor kit for N, F, BNC etc connectors. Stepper Motors: we have a selection of Stepper motors for hobby and high torque CNC applications. DC Motors for both hobby and high torque applications. DC, Stepper & Servo Motor controller kits. Labjack Ethernet/USB Data Acq­ uisition Module: features 14 16-bit analog inputs, 23 digital I/O, 2 analog outputs and 2 high-speed counters. Free software, Labview driver and ActiveX component. Counter and Timers: 7-digit and 10year battery operated. Multi Function Timer and Cyclic Timer /Pulse Generator. Proximity sensors: industrial grade. Photoelectric sensors: up to 15 met­res. Serial & Parallel port relay controller cards. Pump and Trip Alarm Controller card. Duty-Standby operation. PIC MicroProgrammers: serial and USB port operated. 2,4 & 8 Relay Cards: suitable for TTL and Open Collector Outputs. Switch Mode, Battery Chargers and DC-DC converters. Full details and credit card ordering available at www.oceancontrols.com. au. Helping to put you in control. WEATHER STATIONS: windspeed &   siliconchip.com.au New New New Mark22-SM Slimline Mini FM R/C Receiver WANTED OlD TrANsmiTTiNg VAlVEs • Working or not working • Preferably 150 to 280mm in length • Required for exhibition purposes ONLY • • • • • 6 Channels 10kHz frequency separation Size: 55 x 23 x 20mm Weight: 25gm Modular Construction Price: $A129.50 with crystal speakerbits.com.au direction, inside temperature, outside temperature & windchill. Records highs & lows with time and date as they occur. Optional rainfall and PC interface. Used by government departments, farmers, pilots and weather enthusiasts. Other models with barometric pressure, humidity, dew point, solar radiation, UV, leaf wetness, etc. Just phone, fax or write for our FREE catalog and price list. Eco Watch phone: (03) 9761 7040; fax: (03) 9761 7050; Unit 5, 17 Southfork Drive, Kilsyth, Vic. 3137. ABN 63 006 399 480. S-Video . . . Video . . . Audio . . . VGA distribution amps, splitters, standards converters, tbc’s, switchers, cables, etc, & price list: www.questronix.com.au NEED AN INEXPENSIVE CONTROLLER TO AUTOMATE YOUR PROJECT? One you can make yourself? siliconchip.com.au Laceys.tv ™ 42 Brunel Rd Seaford VIC 3198 Tel (03) 9776 9222 web:www.laceys.tv also Sydney, CoffsHarbour, Ulverstone Satellite TV Reception Best high end DIY audio kits on the planet! www.aksaonline.com International satellite TV reception in your home is now affordable. Send for your free info pack containing equipment catalog, satellite lists, etc or call for appointment to view. We can display all satellites from 76.5° to 180°. Select your microcontroller kit and get started... Fax a copy of Foam surrounds,voice coils,cones and more Original parts for Dynaudio,Tannoy and others Expert speaker repairs – 20 years experience Australian agents for products Trade welcome – email for your user ID Phone (03) 9647 7000 TC870 Please contact Maree at Jaycar on +02 9741 8555 or via email mmazzoni<at>jaycar.com.au Electronics PO Box 580, Riverwood, NSW 2210. Ph/Fax (02) 9533 3517 email: youngbob<at>silvertone.com.au Website: www.silvertone.com.au Low Cost Signal Meter From $295* this ad and receive a 5% discount on your order! Feature rich, compiler, editor & debugger with royalty free TCP/IP stack RCM3400 • Prices exclude GST and delivery charges. Tel: + 61 2 9906 6988 Fax: + 61 2 9906 7145 www.dominion.net.au 4007 You have the Circuit - We can Package it? Printed Circuit Boards - Call Mike for PCB Layout Prototyping, Small Runs and Production Runs Product & Panel Labelling - Call Martin for Full Colour on Clear, White, Brushed Aluminium, or Gold Label. Resources Mi M ar AV-COMM P/L, 24/9 Powells Rd, Brookvale, NSW 2100. Tel: 02 9939 4377 or 9939 4378. Fax: 9939 4376; www.avcomm.com.au FACTORY 3 / 26 STAFFORD STREET HUNTINGDALE 3166 Tel: (03) 9 562 7030 Fax: (03) 9 562 7040 e-mail: pcbs<at>alphalink.com.au CLEVERSCOPE USB OSCILLOSCOPES 100MSa/s 10bits each channel 4M samples per input 100MHz bandwidth 8 digital inputs Sig-gen option Spectrum analyser Windows 98/Me/NT/2k/XP GRANTRONICS PTY LTD PO Box 275, Wentworthville. 2145. Ph: 02 9896 7150 www.grantronics.com.au Importer Direct Sale Check out ULTRAsmart’s inexpensive, easy-to-use microLOGIC software coupled with Dick Smith Electronics’ K-2805 parallel port interface kit, and run them on an old PC. FREE demo software at www.ultrasmart.org DVD/VHS NATIONAL VINTAGE RADIOFEST SEPT 2005: fantastic footage of our national radio heritage, a hilarious dinner, the late great Ray Kelly. $25 P&P cheque, d/deposit, BILBY VIDEO (02) 6238 1472. New American technology, polycrystalline solar panels, super long service life, high-efficiency output, compact and light, just 34 x 36cm and 1.58kg. Full weather-proof aluminium frame and tempered glass. Rated 10W, 12V, 0.82A; can charge 12V battery in virtually any climate. Brand new, limited stock. $159. Free post delivery. Ausino Pty Ltd, 129 Mcewan Rd, Heidelberg West, Vic 3081. Tel: (03) 9459 6011; Email: ausino99<at>optusnet.com.au January 2006  119 Do You Eat, Breathe and Sleep TECHNOLOGY? Opportunities for full-time and part-time positions all over Australia & New Zealand Jaycar Electronics is a rapidly growing, Australian owned, international retailer with more than 39 stores in Australia and New Zealand. Our aggressive expansion programme has resulted in the need for dedicated individuals to join our team to assist us in achieving our goals. We pride ourselves on the technical knowledge of our staff. Do you think that the following statements describe you? Please put a tick in the boxes that do: Knowledge of electronics, particularly at component level. Assemble projects or kits yourself for car, computer, audio, etc. Have empathy with others who have the same interest as you. May have worked in some retail already (not obligatory). Have energy, enthusiasm and a personality that enjoys helping people. Appreciates an opportunity for future advancement. Have an eye for detail. Why not do something you love and get paid for it? Please write or email us with your details, along with your C.V. and any qualifications you may have. We pay a competitive salary, sales commissions and have great benefits like a liberal staff purchase policy. Send to: Retail Operations Manager - Jaycar Electronics Pty Ltd P.O. Box 6424 Silverwater NSW 1811 Email: jobs<at>jaycar.com.au Jaycar Electronics is an equal opportunity employer and actively promotes staff from within the organisation. ANNOUNCEMENTS CENTRAL COAST FIELD DAY: Sunday 19th Feb. Don’t miss Australia’s biggest Amateur Radio exhibition and sale of new and used radio and communications equipment at Wyong Race Course, just 1 hour north from Sydney. Gates open 8.30am. Special Field Day bargains from traders and tons of disposals 555 Electronics.............................55 Alternative Technology Assoc....100 Altronics................................. 94-97 Aspen Amplifiers........................119 Ausino Pty Ltd............................119 Av-Comm...................................119 BitScope Designs.........................77 Conference Plus...........................85 Dick Smith Electronics........... 26-31 Dominion Electronics..........100,119 Eco Watch..................................118 WANTED WANTED: EARLY HIFIs, AMPLIFIERS, Speakers, Turntables, Valves, Books, Quad, Leak, Pye, Lowther, Ortofon, SME, Western Electric, Altec, Marantz, McIntosh, Goodmans, Wharfedale, Tannoy, radio and wireless. Collector/ Hobbyist will pay cash. (07) 5471 1062. johnmurt<at>highprofile.com.au Advertising Index Elexol...........................................85 Evatco........................................107 FreeNet Antennas......................118 Furzy Electronics........................118 Grantronics.................................118 gear in the flea market. Exhibits by clubs and groups with interests ranging from vintage radio, packet radio, scanning, amateur TV and satellite www.ccarc. org.au (Ph (02) 4340 2500). JED Microprocessors................5,67 KIT ASSEMBLY Laceys TV..................................119 NEVILLE WALKER KIT ASSEMBLY & REPAIR: • Australia wide service • Small production runs • Specialist “one-off” applications Phone Neville Walker (07) 3857 2752 Email: flashdog<at>optusnet.com.au Microgram Computers....................3 Harbuch Electronics.....................67 Instant PCBs..............................120 Jaycar ..................IFC,57-64,67,120 Microbric......................................41 MicroZed Computers....................53 MiMar Resources.......................119 NewTek Instruments.......................7 Oatley Electronics........................51 Ocean Controls..........................118 Quest Electronics...........67,118,119 CLASSIFIED ADVERTISING RATES: $22.00 (incl. GST) for up to 20 words plus 66 cents for each additional word; display ads: $36.00 (incl. GST) per column centimetre (max. 10cm). Closing date: five weeks prior to month of sale. To run your classified ad, print it clearly on a separate sheet of paper, fill out the form & send it with your cheque or credit card details to: Silicon Chip Classifieds, PO Box 139, Collaroy, NSW 2097. Alternatively, fax the details to (02) 9979 6503 or send an email to silchip<at>siliconchip.com.au Taxation Invoice ABN 49 003 205 490 Radio Parts..............................OBC RCS Radio.................................118 RF Modules...........................IBC,67 RF Probes..................................101 SC Perform. Elect. For Cars.........50 Silicon Chip Back Issues.... 112-113 Silicon Chip Bookshop........... 42-43 Enclosed is my cheque/money order for $­__________ or please debit my Silicon Chip Subscriptions.........103 o Bankcard   o Visa Card   o Master Card Silvertone Electronics................119 Card No. Signature­­­­­­­­­­­­__________________________ Card expiry date______/______ Name _________________________________________________________ Street _________________________________________________________ Suburb/town ______________________________ Postcode______________ Phone:_____________ Fax:_____________ Email:_____________________ 120  Silicon Chip Siomar Batteries..........................85 Speakerbits................................119 Taig Machinery...........................118 Telelink.........................................67 ____________________________ PC Boards Printed circuit boards for SILICON CHIP projects are made by: RCS Radio Pty Ltd. Phone (02) 9738 0330. Fax (02) 9738 0334. siliconchip.com.au SILICON CHIP If you are seeing a blank page here, it is more than likely that it contained advertising which is now out of date and the advertiser has requested that the page be removed to prevent misunderstandings. Please feel free to visit the advertiser’s website: www.rfmodules.com.au