Product Review
Kenwood’s DCS-9120
100MHz digital oscilloscope
Kenwood’s DCS-9120 programmable digital
storage oscilloscope provides both analog &
digital modes of operation, with 4-channel
100MHz operation in the analog mode & two
channels at up to 40 megasamples/second in
storage mode.
First impressions of the DCS-9120
are that it is a fairly compact unit with
a front panel that has lots of knobs, buttons and control labelling. The knobs
for vertical sensitivity and timebase do
not have calibrations as their settings
are displayed on the CRT screen, as is
the triggering level and even the date
and time if required.
Most of the pushbuttons on the front
panel are accompanied by backlit legends to indicate the selected setting.
These are good because they give an
unambiguous indication of the various
settings.
On the rear panel are ports for a pen
recorder, plotter and an RS-232 serial
interface. The DCS-9120 can also be
controlled via a GP-IB interface so that
it can be used for automated testing
in production or other applications.
Physical dimensions of the oscilloscope are 310 x 160 x 510mm, not
including the tilting handle. Its mass
is 10kg.
When used in analog mode, the
DCS-9120 functions as you would
expect for a 4-channel 100MHz oscilloscope. Each of the four input channels
has its own sensitivity adjustment
from 5V/div down to 1mV/div and
an uncalibrated variable knob can be
used to vary the sensitivity within
these ranges. In addition, the 100MHz
bandwidth of the oscilloscope can be
reduced to 20MHz to reduce noise
on the display when signals below
20MHz are being measured.
Signal coupling of the inputs can be
88 Silicon Chip
DC, AC or grounded, while both the
channel 2 and channel 4 inputs can
be inverted as well. This feature can
be used to provide a differential input
mode by ADDing channel 1 to channel
2 or channel 3 to 4.
Each input socket incorporates a
detector which automatically adjusts
the sensitivity (Volts/Div) reading on
the screen whenever the supplied
PC-31 probes are switched to 10:1. If
other brands of probes are used, you
will have to resort to mental arithmetic
to multiply the sensitivity by 10 when
10:1 is selected on the probe.
Sweep time is selectable from 20ns/
div to 0.5s/div in 23 ranges, with fine
adjustment and x10 sweep magnification available. Timebase modes are A,
B or delayed trace, A intensified by B,
A and B alternating or X-Y mode. The
delay between the A and B timebases
can be either a continuous delay, a
trigger delay or a count delay.
Triggering modes
Triggering modes are Auto, Norm,
Single and Fixed, with the usual CH1CH4 source selection or line frequency
triggering. You can also select Vert
triggering which automatically triggers on the lowest selected channel
number. No external triggering input
is provided. Coupling for the trigger
signal can be DC, AC, High Frequency
Rejection or TV (line or frame 1 or
frame 2, NTSC or PAL).
Horizontal or vertical cursors can be
displayed on-screen to enable voltage,
period and frequency measurements, a
fairly standard feature of scopes with
CRT readouts.
Menus
Apart from the front panel controls,
there are many functions and operations that can be accessed via the
menu options. The five menu subsets
are Processing, Memory, Set, Output
and Option. Some functions selected
via the menus are only available with
the storage facility. For example, if you
select the average display from the
processing menu, it will not operate in
the analog mode. The averaging feature
is very useful for improving the signal
to noise ratio of the displayed signal
since it filters out random noise. Averaging can be selected from between
2 and 256 waveforms.
Other functions available from the
processing menu are interpolation (off,
linear, sine and spline), calculation
(+, -, x, /) between channels, and peak
detection of maximum, minimum or
both.
Memory menu options allow you
to select the display address, memory
size and reference memory. The latter
is a memory space into which a waveform can be stored, to be recalled at a
later date and compared with another
waveform on the screen.
In the Set menu, you can change
the delayed triggering options to be
displayed in divisions or real time
(seconds). You can also set the type of
TV triggering, buzzer modes, display
offset and time display modes and
settings.
The Option menu provides programming features so that on-panel
settings can be stored, comments can
be made on-screen and the present
status displayed. A parameter sub
menu provides selection of automatic
calculations which can be done by the
oscilloscope and then displayed on the
DCS-9120
The DCS-9120 provides both analog & digital modes of operation. In analog
mode, its bandwidth is 100MHz, while in digital mode it can operate at 40
megasamples/second. Many of the functions are accessed via menu options.
screen. You can only select one per
trace but each trace can have a different
parameter displayed. The parameters
selectable are period, frequency, pulse
width, rise time, fall time, delay, overshoot, undershoot, peak to peak, RMS
volts, top level, base level, amplitude
and power.
Digital storage
Switching from analog to digital
modes is as simple as pressing the
Mode switch. The difference in the
storage mode is clear, however, if you
need to manipulate the display. You
can magnify the stored waveform
by up to 100 times or compress it to
1/ th of the original, depending on
10
how you want to observe the signal.
You can also perform arithmetic operations between traces and set up peak
hold for catching glitches as little as
50ns wide.
Strangely enough, you can also
observe the waveform before the triggering point. This is a feature only
available on storage oscilloscopes
and is possible since the storage of
the waveform is continuous and the
triggering point really only tells the
scope what part of the waveform you
want to observe. Consequently, you
can observe the waveform before or
after the triggering point, depending
on whether post or pretriggering is
selected.
The other interesting feature is the
way the storage memory can be set
up. There are two separate 16K word
waveform memories for channel 1
and channel 2. One is called the acquisition memory and the other the
reference memory. Each word is eight
bits wide. You can set up the memory
to be 2K words long for eight screens of
storage, or 16K words long for storing
a large continuous waveform section.
Storing waveforms
As is the case with most storage
oscilloscopes, it takes some time to
become familiar with the operating
features. A lot of the difficulty was
due to the extraordinary number of
options that are available in the storage mode. However, we found that
digital storage was particularly useful
for catching glitches and for observing
non-repetitive waveforms such as the
firing of a fluorescent tube – virtually
impossible to observe on a normal
analog scope.
We had a minor complaint when
using the Delta REF/DLY TIME rotary
control to scan through the eight x 2K
memory blocks. In operation, the delta
V cursor switch was often accidentally
bumped due to its close proximity to
this control.
The instruction manual for the oscilloscope is good although there are
spelling mistakes and strange English
in some parts. However, all the features
of the oscilloscope are well explained
and examples are given for both analog
and digital storage modes.
Overall, we liked the features of
the DCS-9120. It provides the best of
both types of scope; the fine detail
waveforms in the analog mode and
the facility to store and manipulate
waveforms in the digital storage mode.
The ability to print out waveforms and
control the unit via the GP-IB interface
also help make this oscilloscope a very
versatile unit. It should appeal to a
wide variety of users for laboratory,
test bench and production use.
The Kenwood DCS-9120 is priced at
$9308 plus 20% sales tax if applicable
and it comes with a 12-month warranty. For further information, contact the
Australian distributor for Kenwood
test equipment, Nilsen Instruments, 18
Hilly St, Mortlake, NSW 2137. Phone
SC
(02) 736 2888. (J.C.)
January 1994 89
