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Designing and
Installing a
HEARING LOOP
For the deaf
Many people have hearing impairment. Whether they are watching
TV, listening to radio or music, attending a concert, meeting or
religious service, they have difficulty hearing, or understanding,
what is going on – and that may be in spite of using a hearing aid.
Hearing loops, which inductively couple an audio signal to a hearing
aid, are an increasingly common method of helping ease that difficulty.
J
ust because you have a hearing aid does not mean that ship which older people frequent. In fact, many modern
your hearing problems are solved. When you have nor- buildings are so equipped these days.
In the home, of course, the problem can be just as difmal hearing, your ears are very good at discriminating
between noise and the sounds you want to hear. Not so ficult, especially when shared with those without hearing
with a hearing aid, particularly if you are wearing only one. impairment. But it is unusual for hearing loops to be inThe hearing aid is basically a microphone, amplifier and stalled in the home.
Until now, that is: in this article we describe how to set
earpiece. Unfortunately the microphone picks up all sounds
and noise then amplifies all by the same amount. The wearer up a basic hearing loop for the home or for small to quite
large meeting rooms, to Australian, New Zealand and IEC
often has great difficulty discerning what is going on.
In many situations this problem can be largely overcome (International Electrotechnical Commission) standards –
by a hearing loop, fed by an audio amplifier. The loop is and how to drive it.
This could be done using a commercially made ampliplaced around the room or hall and the radiated signal
is then picked up by a hearing aid fitted with a T-coil (or fier specifically intended for hearing loop applications but
equally could be a standard commercial amplifier or even
Telecoil; see the sidebar, “The origin of the Telecoil”).
Alternatively, the signal can be picked up via a Cochlea one of the many amplifier designs published by SILICON CHIP.
Professional hearing loop installations can cost many
implant or even a loop receiver, as described elsewhere
thousands of dollars, especially when retro-fitted (most
in this issue, driving conventional headphones/earbuds.
new public buildings these days have
Hearing loss increases with age so it
them installed during construction in
is common for hearing loops to be used,
Part 1: By JOHN CLARKE appropriate areas as a matter of course).
for example, in halls and places of wor22 Silicon Chip
siliconchip.com.au
LOOP RECEIVER
& HEADPHONES
HEARING AID
WITH T-COIL
SIGNAL
SOURCE
MICROPHONE
AMPLIFIER
AMPLIFIER
M
LOUDSPEAKER
T
SWITCH
T-COIL
VOLUME CONTROL,
RESPONSE SHAPING
AUDIO INDUCTION LOOP
1
Fig.1: the basic arrangement for a hearing loop. Signal
from the room PA is amplified and coupled into the
loop. The resulting magnetic field is detected by suitably
equipped hearing aids or receivers.
OUTPUT
T-COIL
However, a do-it-yourself installationVOLTAGE
along the lines set
out in this article can provide excellent results and save a
heap of dollars. It is relatively easy to fit and can be made
small or quite large, depending on the area needed to be
covered.
What’s a hearing loop?
MAGNETIC
In its simplest form, a hearing loop system comprises
FIELD a
signal source, an amplifier and a large loop of wire around
the room or hall. As this loop forms a coil with an
AC curAUDIO
rent flowing through it, it radiates an electro-magnetic
wave
INDUCTION
which
is in sympathy with the signal source. LOOP
3
This radiated signal can be detected by a hearing aid
equipped with a T-coil or indeed, a loop receiver (with
headphones) designed for the purpose. Fig.1 shows the arrangement but we will explain just how this works shortly.
If you want to set up a hearing loop in your home you
should be able to get satisfactory results without any special
equipment. For larger setups in halls, the magnetic field
produced by the signal in the loop needs to be set to the
required level, so that all hearing aids with T-coils will
operate correctly.
In a later article in this series we will show how to build
and calibrate a signal level meter to measure signal levels
from the installed loop.
Our hearing loop is suitable for use in a home, office,
hall, church or similar building. We include design graphs
2
Fig.2: a hearing aid equipped with both T-coil and
microphone to cover both signal sources. Many hearing
aids will have a switch to select both. Obviously, the
loudspeaker is tiny enough to fit in the ear.
and tables to make it easy to select the wire size and its
L
length, along with the amplifier power requirements for a
particular installation.
For large loops, say in a community hall or church, you
H
will need a signal pre-conditioner. In a later issue we will
present a suitable design to allow a standard amplifier to
be employed. The pre-conditioner provides stereo signal
mixing, audio compression, treble boost to provide compensation for loop inductance and treble rolloff
I above 5kHz.
Other articles will provide circuit and construction details for an induction loop receiver (see p62 of this issue)
and
5 a microphone loop driver.
Now let’s describe the basics of a hearing aid.
How does a hearing aid work?
As we mentioned earlier, in its simplest form a hearing
Pulpit
Centre Aisle
Steps
Pew
Pew
Listening
Area
Archway
pillars
Archway
pillars
Sound
Desk
Centre Aisle
HEARING
LOOP
FITTED
Pews
Service
table
To use this facility, sit within
the listening area shown shaded
and switch your hearing aid to
the T-coil position.
Kitchen
A Hearing Loop is installed
in this building.
Front Entrance
Plan View
Where a hearing loop is fitted, it doesn’t usually cover the
entire area. Hence a “map” is needed, such as this one in a
church, to show deaf people with hearing aids where to sit.
siliconchip.com.au
The hearing loop (white figure-8) is laid out here for testing
before permanent installation under the floor.
September 2010 23
A commercial hearing loop amplifier, in this case the model 1077 from Auditec. It’s a current amplifier,
which has some advantages in hearing loop use but standard voltage amplifiers are certainly usable as well.
aid comprises a microphone, an amplifier and a miniature
loudspeaker. In normal use the sound picked up by the
microphone is amplified and processed, depending on the
complexity of the hearing aid. The amplified signal is then
reproduced via the loudspeaker which is closely coupled
to the wearer’s eardrum at a level which compensates for
the loss of hearing. Fig.2 shows the general internal arrangement.
Better, modern hearing aids also include signal processing to try to present the clearest audio to the wearer. And
the best also include a Telecoil (or T-coil), which comprises
a coil of wire on a ferrite core. A switch on the hearing aid
selects the T-coil or microphone as the input source.
Originally used to couple the electromagnetic energy
from a specially equipped telephone into the hearing aid
(hence the name), their use has now expanded to be able
to detect an electromagnetic signal from a hearing loop,
where fitted. Not all hearing aids have a T-coil and obviously, without one, there is absolutely no advantage from
either telephones or hearing loops.
Fig.3 shows the magnetic field produced by the hearing
loop (sometimes referred to as an audio induction loop) and
how this couples into the T-coil. Normally the induction
loop is horizontal and the T-coil is vertical (for a person
who is sitting or standing). Any variation of the T-coil from
its vertical position will reduce the received signal.
There is nothing to stop the orientation of the hearing
loop being vertical, allowing hearing aid wearers to use the
Here’s a commercial
hearing loop receiver
which drives standard
headphones. Or you can
build your own: see the
article on page 62!
24 Silicon Chip
loop when lying horizontal.
One disadvantage of the T-coil inductor is that it produces
a signal which rises in level with increasing frequency. This
is because the induced voltage is proportional to the rate
of change of the magnetic field and so higher frequencies
will give a higher voltage. This rising response is normally
compensated for within the hearing aid to produce a flatter
frequency response.
So why would a person with a hearing aid prefer to listen via the T-coil instead of listening directly to the sound
from a public address or similar sound system? After all,
a hearing aid is designed to pick up sound, amplify it and
tailor the frequency response to suit the individual user.
As already noted, people with normal hearing have little trouble discriminating between unwanted noise and
the sounds they want to hear. By contrast, the wearer of
the hearing aid finds that in a room full of people or in a
noisy environment, all they hear is a whole lot of noise
and it prevents them from following any one sound or
conversation. To that you can add natural reverberation in
a large room, the noise of people moving about and maybe
background music.
The room, especially if it’s reasonably sized, may well
have some form of public address system fitted. That’s
fine for those with normal hearing but ironically, a PA can
introduce more reverberation, cause hearing aid overload
(distortion) and can raise bass levels to further muddy the
sound clarity.
The solution is to channel signal directly from the public
address system into an audio induction loop to be picked
by the hearing aid T-coil. The resulting sound is clearer
because it only contains that broadcast by the sound system
and extraneous sounds from other people and reverberation are absent.
As good as it is, listening via a T-coil is not perfect: the
hearing aid user can feel isolated from the rest of the group
of people in the building because they do not hear the
ambient sounds of the people around them.
To overcome this, some hearing aids include switching
to select three options: T-coil, T-coil plus microphone and
microphone only. The T-coil plus microphone setting mixes
the signals to allow ambient sounds and the broadcast (PA)
signal to be heard but even this can be a compromise.
There is no perfect electronic cure for deafness! Protect
your hearing while you have it.
As an aside, it is widely and reliably forecast that the
siliconchip.com.au
1
2
T-COIL
The origin of the Telecoil
OUTPUT
VOLTAGE
L
MAGNETIC
FIELD
3Fig.3:
AUDIO
INDUCTION
LOOP
Current flowing in the hearing
loop produces a magnetic field that couples into the
T-coil. Voltage is produced across the T-coil terminals.
next ten to twenty years or so will see an explosion in the
number of younger people with irreversible hearing damage, caused (in particular) by years of exposure to loud rock
music (why do bands have to play so loud?) and more importantly, the massive use of ear-buds at excessive volume
from cassette players, then CD players and most recently
MP3/MP4 players and mobile phones.
Designing a hearing loop system
Before embarking on designing and installing a hearing
loop, you need to decide whether the building is suitable
for installing a loop. For many buildings the loop can be
installed beneath the floor, especially if it is timber construction and there is access to the underside of the flooring.
Where there is a concrete floor, the loop could be placed
around the floor under carpet or behind skirting boards.
Alternatively, the loop could be placed in the ceiling,
provided it is not too high above normal listening level.
Installing a hearing loop in buildings made with steel
frames or reinforced concrete is more difficult. This is because the steel tends to reduce the magnetic field strength.
The solution may be to provide more current drive in the
loop with a larger amplifier and/or by using more complex
loop designs.
For most installations, a single loop is all that is needed.
Loop performance can be checked before it is permanently
installed by simply running the loop wire temporarily
around the area (eg, on the floor) where required.
An important factor to consider when deciding on the
positioning of a loop is interference from the mains power
lines. In particular, phase-controlled light dimmers for
stage and auditorium lighting often cause a buzzing sound,
predominantly at 100Hz. The interference will be highest
when the lamps are dimmed.
Fluorescent lamps can cause interference when they are
switching on but do not usually cause problems once lit.
Another source of interference is close proximity to
computers and monitors; in fact anything with a “switchmode” power supply.
We’ll be describing a Hearing Loop Level Meter in a future
article, which can be used to check the background interference levels down to 21dB below a 100mA/m reference.
What level?
According to the Australian standards (AS60118.4-2007),
environmental audio frequency background field levels
siliconchip.com.au
5
Hearing aids installed with a Telecoil or T-coil began as
a solution to a problem that occurs when using a hearing
aid with a telephone. The Hname Telecoil originates from
the words telephone and coil.
To understand the problem you need to be aware that
there is coupling between the telephone mouthpiece
and the telephone earpiece, so as you speak some of
the sound is heard through the earpiece.IThe coupling is
called side tone and is deliberately introduced to prevent
the telephone sounding dead when speaking.
This can cause a problem when using a hearing aid.
When it is brought close to the earpiece of a telephone,
the hearing aid often produces a loud-pitched squeal, or
feedback. This is caused by the microphone on the hearing aid picking up sound that is amplified and reproduced
by the hearing aid loudspeaker, which is then received
by the telephone handpiece and then further re-amplified
by the hearing aid and so on.
To allow a hearing aid wearer to use a telephone,
without this problem occuring, the telephone is modified
to include a wire loop that is driven by the same signal as
the telephone loudspeaker. The loop produces a small
magnetic field that varies in sympathy with the signal.
To utilise this feature, the hearing aid needs to include
a Telecoil (T-coil) that detects signal from the phone’s
magnetic field. When required to be used in this way, the
hearing aid is switched to the “T-coil” position, disabling
the hearing aid microphone and thus avoiding the audio
feedback.
Some telephones include a Telecoil already installed
within the handpiece; some may need one fitted as an
accessory. More information is available from your telephone supplier or via The Independent Living Centres
Australia (www.ilcaustralia.com/home)
Some hearing aids are designed to automatically
switch over to the T-coil position in the presence of a
strong DC magnetic field. The magnet in the telephone
earpiece provides this field.
Due to the success of the T-coil in hearing aids with
telephones, its application has broadened to where
hearing loops are now commonly used wherever sound
needs to be available for the hearing impaired.
A “behind the ear”
hearing aid. The
tube at the top
feeds into the
ear canal, fed
by the miniature
loudspeaker at
the top of the unit.
Controls on the
back of the unit
include a volume
control, power
switch and the allimportant T-coil/
microphone switch.
September 2010 25
1
2
should be below –20dB ‘A-weighted’ with respect to a
100mA/m reference field (or –40dB below 1A/m) using a
OUTPUT
T-COIL
slow (S) time weighting of 1 second.
VOLTAGE
We do have reservations about whether this level is sufficiently low for satisfactory hearing loop performance. The
Hearing Loop Level Meter will also measure noise using a
wider frequency response than the A-weighting provides.
This can give a more realistic indication of whether noise
will be intrusive.
MAGNETIC
Another consideration is whether the loop wire will
be
FIELD
running close and parallel to signal wires in a public address
system, such as for microphones. This has the potential to
cause instability in the sound system although it INDUCTION
isAUDIO
usually
LOOP
no more
wiring
3 severe than feedback caused by loudspeaker
running close to the microphone cables.
Further problems may occur with dynamic, electret and
UHF radio microphones and guitars with magnetic pickups.
It is wise to test for these problems with a temporary loop
installation. Problems will be evident if the sound seems
distorted or has a “metallic” quality. An oscilloscope can
also be used to monitor the sound system signal for any
instability.
Note that an audio induction loop setup will not cause
direct acoustic feedback, ie, the squeal associated with
audio coupling of microphones and guitars to loudspeakers.
Spill
Generally, the area where a hearing aid will receive the
signal is within the loop itself. Outside the loop, the signal
level drops off. Fig.4 shows the measured field strength of
a 10m x 10m square loop at a height of 1m above the loop.
The signal is reasonably constant (to within 3dB) within
the loop area but drops off just outside the loop. Any signal
outside the loop is called the “spill”.
Spill means that the signal is not secure and might be
intercepted from outside the building, simply by using a
T-coil-equipped hearing aid. If security is important, that
is a consideration.
Spill also means that if more than one
Field strength over loop area for a 10m square loop <at> 1m
loop is installed in a building
above loop measures are required to
prevent interference between them.
0
-5
-10
Field Strength (dB)
H
I
Fig.5:
for a magnetic
5
field strength (H) of 100mA/m at the centre of the square
loop, the current required through the loop of side
length L is I=L/9n amps, where n is the number of turns.
More than one loop will be required where a very large
area needs to be covered. If each loop broadcasts the same
signal, then using out-of-phase adjacent loops can minimise
signal loss at the loop junction.
Where the signal in each loop is different (eg, in a multicinema theatre) the loop design must prevent any signal
spill into adjacent loops. Special loop designs enable spill
to be minimised. For more information on spill control, see
Ampetronic’s website: www.ampetronic.com
Coverage area
In many cases it is only necessary to provide loop coverage for part of a room or hall rather than attempt to provide
for the full area.
For example, where a hall has seating for say 500 people,
you may only need to provide hearing loop coverage for
50 seats or perhaps even less. This would mean that a map
would be required to show potential users the designated
listening area and/or any booking system would need to
provide priority for hearing impaired within that area.
A smaller loop also means that a lower-powered amplifier can be used.
Amplifiers for Hearing Loops
5
)
B
d
(
h
tg
n
re
tS
ld
ie
F
L
-15
-20
-25
-30
-35
-7
-6
-5
-4
-3
-2
-1
0
1
2
3
4
5
6
7
Distance from centre (m)
Distance from centre (m)
Fig.4: field strength over loop area for a 10m square loop at
a height of 1m above loop.
26 Silicon Chip
As noted, an audio amplifier is required to “drive” the
loop. You have three choices: using a commercial hearing
loop amplifier, using a standard commercially-made amplifier . . . or you build your own!
Most commercial amplifiers specifically made for hearing loop use are “current” amplifiers, whereas “ordinary”
amplifiers, including ones you would build yourself, are
“voltage” amplifiers.
Current amplifiers have the advantage that the loop
current does not vary with frequency, which would normally occur due to the inductance of the loop. However,
standard voltage amplifiers can be used as well although
it is true that they provide reduced current to the loop as
the frequency rises. This is easily fixed, in most cases, with
some judicious treble boost.
And with our signal pre-conditioner for power amplifiers
to be described in a future issue, using a voltage amplifier
becomes very practical.
Minimum load for a voltage amplifier
One requirement when using a voltage amplifier is that the
siliconchip.com.au
Vout
9k
SIGNAL
Vin
1k
Vout
R
R
L
LOAD
(INDUCTION
LOOP)
SIGNAL
Vin
L
LOAD
(INDUCTION
LOOP)
R/10
B CURRENT AMPLIFIER
A VOLTAGE AMPLIFIER
Fig.6 (left): a voltage amplifier driving a hearing aid loop load will produce less current in the loop with rising load
impedance. Fig.7 (right) : a current amplifier driving a hearing aid loop load will maintain current in the loop with
rising loop impedance. More on this subject next month.
loop must be designed to suit its minimum load, typically 4Ω.
Hence, the design is based on the size of the loop and
wire gauge required to provide a 4Ω DC resistance. Once
you have decided on the hearing loop dimensions, you add
up the length of wire sides (almost invariably the “loops”
are rectangular or square) required to make up the loop
(don’t forget the wire between the loop and the amplifier).
Then the gauge of wire to provide a 4Ω load is selected
from Table 1.
But that is not the full story because the wire must be
able to carry the current needed to produce the required
magnetic field strength of 100mA/m (millamps/metre). This
100mA/m field strength is the standard level long term
average signal level. With normal program material, peak
signals can be 12dB higher or up to 400mA/m.
To allow for this we have set a large factor of safety for
the wire current rating by restricting average wire current
to 5A/square mm when the wire could easily accept 8-10A
continuously.
Calculation of the current requirements to produce the
100mA/m field strength (H) at the centre of a square loop
and along the same plane as the loop uses the equation:
Current (A) = L(m)/9n, where L(m) is the length of the
side in metres and n is the number of turns.
For the purposes of loop design, a rectangular loop can
use the same equation with L as the smaller of the rectangle sides.
As an example, when using the equation for a single-turn
9m square loop, a current of 1A is required to produce the
100mA/m field. For a 2-turn loop the current requirement
to produce that same field is halved, to 0.5A.
How much amplifier power?
The amplifier power needed must allow for the signal to
be +12dB over the base signal level, without overload (ie,
clipping). So the required amplifier power requirement will
be (current required for 400mA/m field strength) squared
multiplied by the 4Ω load.
As an example, if the current required is 1A, the power
will only be 4W. If it is 4A, the power required will be 64W.
Listener’s height
Another factor to consider is that the maximum field
strength lies in the same plane as the loop and will be
lower at a distance above (or below) the plane of the loop.
So a design for monitoring signal in the same plane of the
Table 1: Loop wire and current calculator
Wire cross
section area
(mm2)
Wire current
capacity
(based on
5A/mm2)
(A)
Ohms per metre
(Ω/m) (based
on 0.017241Ω
mm2/m at 20°C)
Wire length
required for 4Ω
(For figure-8
wire use half
this length)
Maximum
square loop
size
(two turns)
Current for
100mA/m for
max. loop
size (A)
Current
required for
1.7m above or
below loop
(A)
1 x 0.25mm
1 x 0.315mm
1 x 0.5mm
0.049
0.07793
0.1963
0.245
0.389
0.982
0.351
0.2212
0.0878
5.7m
18m
45m
0.7m square
2.25m square
5.63m square
0.078
0.25
0.63
1.50
1.01
14 x 0.14mm
14 x 0.18mm
14 x 0.20mm
19 x 0.18mm
20 x 0.18mm
24 x 0.20mm
41 x 0.20mm
0.21555
0.3626
0.43982
0.48349
0.50894
0.75398
1.28805
1.077
1.81
2.20
2.42
2.54
3.77
6.44
0.080
0.0484
0.039
0.03566
0.03388
0.02287
0.013387
50m
84m
104m
112m
118m
176m
298m
6.25m square
10.5m square
13m square
14m square
14.75m square
22m square
37.5m square
0.70
1.17
1.44
1.56
1.64
2.44
4.17
1.05
1.40
1.58
1.64
1.71
2.45
4.18
Wire size
When you’ve decided on a loop dimension, use this to read off the nearest wire size and length required to make a 4Ω load.
siliconchip.com.au
September 2010 27
1400
Loop current and power multiplier versus height
above loop
1300
That is because the current is directly proportional to field
strength. If the listening height is changed so that more
current is required in the loop to maintain field strength,
then that means that the field strength will be lower at that
height if the current is not increased to compensate.
25
24
1200
23
22
1100
21
20
Height comparison
1000
19
So let’s compare the variation in field strength between
when
a person is standing and when seated. We choose
1 Turn
Current
1.7m as the expected highest listening point above the loop
2 Turns plane noting that hearing aids are at ear level rather than
Power
the height of the person. We choose 0.5m as the lowest
expected listening height above the loop plane. For a 6.8m
loop, a 1.7m height gives a 0.25 height to loop dimension
ratio and the current multiplier is about 1.4. For the 0.5m
height, the ratio against the loop dimension is very close
to 0.1 and the multiplier is very close to 1.
A 1.4 variation in field strength corresponds to a 3dB
change. Taking the log of 1.4 and multiplying by 20 calculates this. So for the 6.8m square loop; if the loop current is
set so the signal strength is correct at the 1.7m height, then
the field strength will increase by 3dB at the 0.5m height
due to the closer proximity to the loop. If the loop field
strength is set for correct level at 0.5m, then the strength
will drop by 3dB at 1.7m in height.
The calculation shows that a 6.8m square loop is the
smallest sized loop that will provide only a 3dB change
in field strength level between the two expected minimum
Height above (or below) loop/shortest side length
and maximum heights above the loop.
Smaller loops will have a wider variation while larger
Fig.8:
extra
current
and
power
are
required
for
height
offsets
1
2
3
5
7 10 15 20 25 30 35 40 45
loops will have less variation. If you are after minimal
above or below the loop plane to maintain field strength.
variation in field strength with height changes, use a larger
square loop side dimension (m)
loop. A 10m loop, for example, will show less than 3dB
loop will not deliver that field strength at a higher level variation with a 2m change in listening height.
above the plane.
Note that the extra power requirements for the amplifier
For most hearing loop installations the loop is either are very high when the listening height above or below the
placed just below the floor, at floor level or in the ceiling. loop is significant compared to loop size. For example if
Typically, this means that the listener’s hearing aid is about you are using a 2m loop and are 1m above the loop, the
1.7m above or below the plane of the loop.
0.5 height to loop size ratio shows a loop current requireFig.8 shows a graph of the extra current and power
required for height offsets above or below the loop plane.
To use the graph, divide the distance that the hearing aid
will be above or below the loop plane by the shorter side
length of the loop. So if the loop has a 5m shorter side
and the height is 2m above the loop, the division gives us
0.4. Comparing 0.4 on the graph gives us a multiplier of
FIGURE-8
about 2.1 times more current that must be applied to the
CABLE
loop to maintain the field strength at 2m above (or below)
the loop plane.
While the current needs to be 2.1 times greater, power
requirements must be 4.4 times greater. This is where larger
loops are better in this respect because the height above or
below the loop plane is relatively small compared to the
loop side dimension.
This fact is important to consider because users of the
induction loop are seldom all the same height, nor do they
always remain at the same height. They might stand some
of the time and sit for other times or they could be in a
wheel chair. Ideally the loop should be sized so that the
field strength does not vary by more than 3dB between the
Fig.9: this shows how
lowest and highest listening heights.
to form a 2-turn loop
The graph of Fig.8 can also be used to determine the
using figure-8 wire.
TO
variation in field strength with changes in listening height.
AMPLIFIER
18
900
17
16
800
700
600
15
Multiplier
)
H
m
(
ec
n
tac
u
d
In
r
ie
l
ip
t
l
u
M
14
13
Current
12
Power
11
10
9
500
8
7
400
6
5
300
4
3
200
2
1
100
0
0
0
0.1
0.2
0.3
0.4
0.5
0.6
0.7
0.8
0.9
1
Height above (or below) loop
shortest side length
28 Silicon Chip
siliconchip.com.au
2-turns 4W
Power requirements versus loop size
2-turns 4W
siliconchip.com.au
)
(W
r
e
) w
o
W
( P
r
e
w
o
P
Power (W)
ment of 2.8 times higher compared to directly along the
loop plane. Power requirements are eight times more. This
also means that a 2m square loop is impractical because
the listener must remain fixed at the one height otherwise
the signal level will vary too much.
When you have decided on a loop dimension, use Table.1
to read off the nearest wire size and length requirement to
make a 4Ω load. You might require extra wire if the amplifier is not located close to the loop. Note that the table
only shows figure-8 wire length. Figure-8 wire comprises
two insulated and parallel running wires and when connected to make a single length of wire will form a 2-turn
loop (see Fig.9).
We show only figure-8 wire in the table because interestingly, a 2-turn loop is the only practical option for an
induction loop that is driven using a voltage amplifier. It
works out that a 2-turn loop that provides a 4Ω load will
have the correct current rating to prevent overheating the
loop wire.
This applies even with the extra current requirement
for loop monitoring at 1.7m above or below the loop. Using a single turn loop requires twice the current for the
100mA/m field strength and is likely to overheat the loop
wire, making it impractical.
Using more than two turns is not recommended because
of loop inductance which increases by the square of the
number of turns. So while two turns produces four times
the inductance of a single turn loop, a four turn loop will
have 16 times the inductance.
Higher inductance means that the amplifier (whether a
current or voltage type) needs to be able to provide much
more voltage drive at higher frequencies. More details about
this inductance effect are provided later.
The table has values of wire resistance calculated based
on copper resistance at 0.017241Ω mm2/m at 20°C. The
cross sectional area is the radius of the wire squared times
pi(). For wire with more than one strand, the area for one
strand is multiplied by the number of strands. The ohms/
metre value was obtained by dividing the total cross sectional area into the 0.017241Ω mm2/m.
Power requirements for a given loop size is calculated
using the required current to produce the 100mA/m field
and multiplying this by four to get the current for the 400mA
peak. For a 2-turn loop, divide this value by two. Overall,
this simplifies to multiplying the current for the 100mA/m
field by two. The value is then squared and multiplied by
the resistance (4Ω) to obtain the power requirement.
Chances are that the loop you are using will not be
exactly one of the loop sizes listed in the table. For an inbetween value loop size, use the next lowest listed loop
size wire gauge. This will mean that the resistance will be
higher than 4Ω due to the extra length for the larger loop.
Amplifier power requirements may need to be higher if the
rated power of the amplifier you are using is close to the
amount of power required.
To simplify calculations, Fig.10 shows amplifier power
requirements for a 2-turn 4Ω loop of various sizes. One
graph shows power required for directly at the loop plane
and the second for 1.7m above (or below) the plane. The
power requirements take into consideration the 400mA/m
field strength produced during signal peaks. As mentioned
if the loop is more than 4Ω, power requirements will need
to be increased by the same ratio. So an 8Ω loop will require
400
390
380
400
370
390
360
380
350
370
340
360
330
350
320
340
310
330
300
320
290
310
280
300
270
290
260
280
250
270
240
260
230
250
220
240
210
230
200
220
190
210
180
200
170
190
160
180
150
170
140
160
130
150
120
140
110
130
100
120
90
110
80
100
70
90
60
80
50
70
40
60
30
50
20
40
10
30
0
20
1
10
0
Loop plane
Loop plane
1.7m above (or be
Loop plane
loop
1.7m above (or belo
1.7m above
loop
(or below)
loop
2
3
5
7
10 15
20 25 30
35 40 45
Square loop side dimensions (m)
Square loop side dimension (m)
2 3 5 power
7 10 requirements
15 20 25 30 when
35 40 driving
45
Fig.10:1 amplifier
a 2-turn
4Ω loop of various sizes. Power is shown for directly along
side1.7m
dimension
(m) (or below) the plane.
the loopSquare
planeloop
and
above
double the power. There is no problem using an amplifier
that has more power than is required.
For a loop of 15m and larger, the power requirements for
along the plane and 1.7m are almost the same. This means
that the field strength in the loop effectively does not vary
over a 1.7m range.
As a consequence any change in listening height above
the plane of the loop will not be subject to variation in signal level. In practice 10m square loops also do not appear
to have any noticeable signal level change with normal
variations in height.
What voltage amplifiers are suitable?
As mentioned, a voltage amplifier for the loop designs
described here needs to be able to drive a 4Ω load and it must
be unconditionally stable. This is important because we do
not want the amplifier oscillating at a very high frequency
and radiating radio frequencies. In addition, the amplifier
would produce lots of distortion if it is prone to oscillation.
While many commercially made amplifiers could be
used, Table 2 shows some of the more recent and suitable amplifiers that SILICON CHIP has published. The table
September 2010 29
Loop Inductance
We mentioned that loop inductance was a concern because it reduces the amount of current that is applied to the
loop as frequency increases. Hence, treble boost is needed.
Australian Standard AS60118.4-2007 recommends that
the frequency response of the magnetic field be 100Hz
to 5kHz within ±3dB. Naturally, the response can cover
a wider range of frequencies. In practice though, having
rolloff above 5kHz is ideal because it removes the need for
excessive treble boost.
We plotted loop inductance versus loop size and this
can be seen in the graph of Fig.12. Inductance of a square,
rectangular or circular loop can be calculated using an
inductance calculator.
We used the calculator at www.technick.net/public/
code/cp_dpage.php?aiocp_dp=util_inductance_calculator
For the purpose of this exercise, inductance calculation
was based on 1mm diameter wire (0.5mm radius). The µ
value for air is 1. Inductance is shown for both a single
turn loop and using figure-8 wire that forms two turns.
Note how the inductance for two turns is four times that
of one turn. The inductance values are based on a square
loop shape. Rectangular loop inductance can be calculated
using the rectangular shape option in the above mentioned
inductance calculator.
Typically, a rectangular loop will have the same inductance as a square loop that has the same wire length. For
example a 10m square loop has the same inductance as a
15 x 5m rectangular loop.
From the inductance we can calculate the 3dB down
rolloff for a 4Ω loop. How this is calculated is described
in the section entitled ‘Inductance of the loop’. A simplified calculation for 4Ω loops is that the -3dB frequency =
0.6366/inductance in Henries. Multiply the -3dB frequency
by two for 8Ω loops.
The graph in Fig.13 shows the –3dB rolloff frequency
against loop side length. The graph reveals that for a 2-turn
loop, the frequency response is no more than 3dB down at
5kHz for square loops up to almost 5m. Larger loops will
require treble boost to compensate for the rolloff.
Actual rolloff against frequency for various sized loops is
shown in the Fig.14 graph. For the 5m square loop, rolloff
is just over 3dB down at 5kHz, but for a 20m square loop
i
R
V
L
Z
XL
R (4 )
12
Fig.11: the total impedance of a series-connected
resistor and inductor is calculated using a phasor
diagram. Impedance of the resistor is R and reactance
of the inductor is XL. Total impedance is Z.
30 Silicon Chip
Inductance (H)
indicates the recommended sized loop that could be used
with each.
The amplifier power requirement for the loop size takes
into account the fact that the loop will be about 1.7m away
from the listening position. See www.jaycar.com.au and
www.altronics.com.au for kits.
390
Inductance versus loop size
380
370
1700 360
350
1600
340
330
1500
320
1400 310
300
1300
290
280
1200
270
1100 260
250
1000 240
)
H
m
(
230
e
c
) 900
n
a
1T
t
220
c
W
Loop plan
(
u
d
r
1 turn
n
I
2T
e 800 210
w
o
200
P
700 190
1.7m abov
2 turns
180
loop
600
170
160
500
150
400 140
130
300
120
110
200
100
100 90
80
0
70
1
2
3
5
7
10
15
20
25
30
35
40
45
60
square loop
sideloop
dimension
(m)
Square
side
dimensions
(m)
50
40
Fig.12: the
plot of loop inductance versus loop size. The
30
graph shows
inductance for both 1-turn and 2-turn loops.
20
Note how
10 inductance is four times greater in the 2-turn
loop. Typically,
a rectangular loop will have the same
0
inductance1 as2a square
loop
that has the same wire length.
3 5
7 10 15 20 25 30 35 40 45
Square loop side dimension (m)
rolloff is –14dB down.
The Hearing Loop amplifier signal pre-conditioner that
we will describe in a later issue has treble boost compensation to correct for these rolloffs.
Note that adding treble boost to an amplifier’s signal input
might appear to mean that extra power will be required
from the amplifier.
However, extra amplifier power is not normally required
because the power requirement for reproducing naturally
occurring sounds becomes less at higher frequencies. Typically, natural sounds have the same energy per octave. And
so while there are four octaves between 100Hz and 1600Hz
there are less than two octaves between 1600Hz and 5kHz.
Treble boost is only applied from about 1600Hz through
to 6kHz.
However for large loops (15m square and over), a fair
degree of treble boost is necessary. In these cases it may
be best to use a slightly higher powered amplifier than one
selected from the design graph and tables, especially if the
power available from the amplifier is only just sufficient
for the size of the loop. It is not practical to compensate for
treble loss for loops larger than 20m square.
Impedance of the loop
A hearing loop generally comprises a wire length in the
shape of a rectangle or square. The impedance of the loop
comprises the resistance of the wire plus the reactance
due to the inductance of the loop. These two components
are effectively in series. The loop resistance will remain
siliconchip.com.au
Loop Frequency Response
(4W, 2 turns)
(4W, 2 turns)
-3dB upper rolloff frequency versus loop size
based on a 4W 2-turn loop
0
20
0
19
-1
-1
18
-2
17
-2
16
-3
-3
-4
-4
-5
-5
-6
-6
15
14
LOOP SIZE
13
Frequency (kHz)
12
)
B
d
(l
e
v
Le
11
10
)
B
-7(d
l
e
v
e
L
-8
Level (dB)
3m square loop
3m square loo
z)
H
k
(
y
c
n
e
u
q
e
rF
3m square
5m square loop
5m square loo
5m square
10 square loop
10 square loop
-7
10m square
15m square15m
loopsquare lo
15m square
-8
9
20m square loop
20m square lo
20m square
-9
8
7
-9
-10
-10
6
-11
-11
5
-12
4
-12
-13
3
-13
2
-14
-14
1
-15
0.25
0
1
2
3
5
7
10
15
length
SideSide
length
(m)
20
25
30
35
40
45
0.5
-15
0.25
1
2
0.5
3
1
4
5
2
3
Frequency (kHz)
6
4
7
5
8
6
9
7
10
8
9
10
Frequ ency (kHz)
(m)
Frequency (kHz)
Fig.13: this shows the –3dB rolloff frequency with various
loop side lengths (4Ω, two turns). Frequency response
varies by no more than 3dB up to 5kHz for loops no larger
than 5m square. Larger loops will require treble boost to
compensate for the rolloff before 5kHz.
Fig.14: frequency response for various sized loops (4Ω, two
turns). For a 5m square loop, rolloff is just over 3dB down
at 5kHz but for a 20m square loop rolloff is –14dB down.
Typically, a rectangular loop will have the same response
and –3dB rolloff as a square loop with the same wire length.
reasonably constant although it will vary with temperature.
The main variation in the loop will be due to the reactance
that rises with frequency.
A pure resistance without inductance has a current that
is in phase with the voltage. For a pure inductor, which
has no resistance, the current lags the voltage by 90°. Its
reactance is 2 x x the frequency x the inductance (L). To
find the total impedance effect of both the resistance and
the reactance of the inductor we need to consider the two
quantities as shown in the phasor diagram of Fig.11.
Resistance is shown as R and the reactance (XL) is 90°
difference in phase. To add the two values we square both
the R value and the XL value, add the two squared values
and then take the square root. This gives the value of the
(Z) impedance. Mathematically, this is just using Pythagoras’ theorem to calculate the length of the hypotenuse in
a right-angled triangle.
Assuming the resistance R is 4Ω, at low frequencies the
impedance of the inductor is low and so the overall impedance is close to 4Ω. As frequency rises, the impedance
of the inductor rises and begins to have a greater effect on
the overall impedance of the loop.
Table 2: SILICON CHIP Amplifier Data
Power into 4Ω
Loop size
Amplifier Name
Silicon Chip publication date
Kit supplier No.
20W
3-8m square
Compact High Performance
12V Stereo Amplifier
May 2010
Jaycar KC5495,
Altronics K5136
30W
2.5-11m square
Schoolies Amplifier
December 2004
Altronics K5116
55W
2-16m square
50W Audio Amplifier Module
March 1994
Jaycar KC5150,
Altronics K5114
70W
2-18m square
SC480
January 2003
Altronics K5120
200W
1.5-33m square
Ultra-LD Mk2
August 2008
Jaycar KC5470,
Altronics K5151
350W
Up to 42m square
Studio 350 Power Amplifier
January 2004
Jaycar KC5372
This shows some of the more recent and suitable loop driving amplifiers published in SILICON CHIP, ranging from 20W
through to 350W. The table also shows the recommended size of loop that could be used with each.
siliconchip.com.au
September 2010 31
The rising impedance has an effect on the current flow
within the loop. So if an amplifier is fed with a constant
voltage level, the current will reduce as frequency rises as
the impedance increases. The loop current is the voltage
divided by the impedance.
At low frequencies, the reactance XL is close to zero and
so the 4Ω resistance mainly sets loop current. As the frequency rises, the reactance increases, the total impedance
rises and so current drops. The –3dB down frequency is
when the resistance R is equal to the reactance XL. Then
the current is 0.7071 of the DC current.
As an example (and using simple numbers) lets say R
is 1Ω and voltage is 1VAC. Current I at a low frequency
is 1A. When the AC frequency is higher the reactance of
the inductor will be 1Ω at a specific frequency depending
on the inductance. The impedance Z becomes the square
root of 2 or 1.414Ω. So the current is 1/1.414 or 0.7071 in
value. This reduction to 0.7071A compared to the original
1A is the –3dB level.
A hearing loop does not use radio!
A common misconception with hearing loops is that they
operate using radio waves. In other words, it is assumed
that the loop acts as a radio antenna and the hearing aid
includes a wireless receiver for reception. This is not true.
The magnetic field from the loop is simply modulated at
the audio signal frequency at up to around 5kHz.
While the magnetic field produced by the loop is a part
of the electromagnetic spectrum its properties are unlike
radio waves: for example, the wavelength at 3kHz is so
long at around 100km compared to radio waves that start
at around 300m.
In the same way, the electromagnetic fields produced
by 50Hz power lines are not considered to be radio waves.
Other examples of waves that are also part of the electromagnetic field spectrum include Infrared radiation (heat),
visible light, ultra-violet light (UV) and X-rays. These too
are not considered radio.
Health effects using a hearing loop?
While it is certain that some electromagnetic fields can
cause detrimental health effects (eg, UV and X rays), it is
unclear whether the low frequency and low level magnetic field from a hearing aid will have any detrimental
effect. Most research concerning the effects on cells with
electromagnetic radiation is concentrated on 50Hz power
transmission along with the higher frequencies such as
microwaves, X rays, ultra-violet radiation etc.
Mobile phones come under the microwave category
and operate at around 3GHz. The microwave energy from
a mobile phone is vastly higher than that from a hearing
loop and its frequency is at least 1 million times greater
and with much higher energy.
There is no correlation between the effects of microwave
energy causing cell damage in the body and any effects
caused by hearing loops.
If we consider the 50Hz power line frequency as being
the closest studied radiation compared to the hearing loop,
the recommended maximum continuous exposure to magnetic field is 0.1mT (milliTesla). This data was obtained
from the Australian Radiation Protection and Nuclear
Safety Agency. (www.arpansa.gov.au/radiationprotection/
facsheets/is_emf.cfm).
The recommended magnetic field strength in audiofrequency induction loops for hearing aid purposes is
100mA/m at 1kHz rising to 400mA/m during peaks, which
equates to 0.126µT and 0.5µT respectively – more than
1000 times less than the 0.1mT level.
Magnetic field strength
For the hearing loop specifications, magnetic field
strength is expressed using the units of A/m or amperes
per meter. The letter H is used to label this field. The field
represents the total amount of field strength provided by
the loop.
Another way of expressing a magnetic field is with the
letter B, which is the magnetic field density and describes
how the field is concentrated due to the medium within the
field. Its units are in Tesla (T). The field medium can be free
space (usually air) or it can be other material such as iron
or ferrite. These latter mediums distort the magnetic field
with higher concentrations found within the iron or ferrite.
Where a hearing loop is installed and there is significant
steel in the field, then available field strength in the free
space (air) will be reduced because the field will
be concentrated through the steel. The hearing
loop needs to be driven with more power to
counteract the loss within the steel.
The B field strength values and the H magnetic field density values are easily converted
from one to the other using the equation B=µH.
B is the magnetic flux density (T) and µ is the
permeability of the magnetic field medium. This
is 4 x x 10-7 for air and free space.
For a hearing loop, the 100mA/m field
strength produces a field density of 0.126µT.
The 400mA/m level is 0.5µT.
By the way, if you prefer to use Gauss (G) units
instead of Tesla, the conversion is 0.1µT=1mG.
So 0.126µT is 1.26mG.
Next month
An under-floor hearing loop installation. Unfortunately, under-floor
access is rarely this good. Special considerations also apply if the floor is
steel-reinforced concrete; indeed under-floor loops may not be possible.
32 Silicon Chip
We’ll continue our look at Hearing Loops,
examining at some of the commercial equipment available.
SC
siliconchip.com.au
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