Arcam P85-3, P85, A85 Service Manual

Service Manual

DiVA A85, P85 & P85/3
Amplifi ers

A85

Issue 2.0

ARCAM

Contents List

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Contents list

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Circuit description

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Service guide

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Circuit diagrams

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Component overlays

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Circuit board parts list

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General assembly parts list

Pre-amplifier circuit description

The A85 preampli fier is a high-performanc e, DC coupled design
with microproc essor control of in put select, two in dependent tap e
loops, electronic volume control, tone bypass and electronic tone
control.

It features a discrete power supply and low-noise linear circuitry to
obtain very good distortion and noise performance, suitable for
high quality sourc e m aterial such as CD or DVD-A.

Input switching

Each of the inputs has a pair of diodes to the ±15V rails to prevent
static spikes from causing damage t o the CMOS multip lexers. In
addition, there is a simple resistor-capacitor filter with a corner
frequency of approximately 340kHz to remove any unwanted high
frequency interference from the signal. This uses high-quality
polypropylene capacitors for best performance.

Z104 and Z105 are the main input select multipl exers, which are
configured in a ‘virtual earth’ unity gain arrangement with Z115
and Z116. This arrangement is slightly lower distortion than the
‘normal’ one, at th e cost of a slightly higher nois e floor. It is an
inverting configuration, which is restored to correct polarity by the
inverting elect r onic volume control which follows.

Z115B and Z116B are integrating servos, which take out any DC
from the input signal before the following stages. The servos are 2­pole, with a passive 2
the left channel) to remove broadband noise from the output of the
servo and improve speed of response.

Z100 thru Z103 are the input selectors for t he 2 tape loops . These
are normal non-inverting selectors which are buffered before being
passed on to the phono sockets.

Z109A output is decoupled by R108 which is included in the
feedback path . Local h igh freq u ency feed ba ck occu rs aroun d C108
to allow the tape loop output to be very low impedance, whilst
being stable into a capacitive load such as may be presented by a
screened in terconnect cable. This is the same for all tape outputs.

Z106 is configured as a double pole changeover switch, used to
select the tone controls. The tone controls are bypassed when not
required so that the noise and distortion can be minimised.

Tone control circuit

The tone control circuit is a non-inverting one, using a gyrated
‘bell’ filter f o r the bass and a simple shelving filter for the t r eble.

Left channel description

The input is attenuated by 6dB and biased to a volt age of +2.5V
DC by C111, R113, R112, R110, R111 and C110 . This is so the
signals fall within the 0 - 5VDC required by the digital
potentiometer Z108.

Z111B and its associated components form an active equivalent of
a series resonan t LCR circui t. This has a n impedance m inimum of

5.4k at around 80Hz with Q=0.7 The reason the bass is done as a
band-boost filter rather than a shelving filter is so that you can
boost the ‘real’ b as s wit hout c ausi ng lot s of s u b- aud i o lou dsp eak er
cone excursion which wastes power and may damage the drive
units.

nd

pole being formed by R180 and C147 (for

The digital pots Z108D and Z108A control the bass and treble
respectively. Th is is done by moving the wiper conn ected to the
frequency-sensitive impedance between the non-inverting and
inverting terminals of Z112A, effectively changing the ratio of
feedback boost and feed-forward attenuation of the circuit at the
desired frequencies, thus providing a EQ gain control that is
symmetrical on a logarithmic scale, with the use of a linear pot.

Z112B provides the 6dB of gain necessary to bring the nominal
signal level back to unity. C116 and C117 remove the 2.5VDC
offset from th e output, to preven t clunks when th e tone controls
are activated.

Z108 is controlled by a simple 3-wire serial interface from the
microprocessor. Each of th e digit al lin es has it s own groun d return
to minimise electromagnetic interference. They are connected
together only at the GND pin of the IC.

Volume control

Z107 is a VSDVC electronic volume control IC. It works, in
conjunction with an external op-amp , by varying t he feed-for ward
and feedback resi stors in an inverting gai n configuration. In th is
way, it can allow output signal swings of up to 22Vpp whilst
operating from a sin gle +5VDC power supply. Also, it allows th e
user the choice of external ci rcuitry to fine-tune the p erformance.
The gain is controlled from th e microprocessor via a 3 -wire serial
interface. The analogue supply rail is derived from the local +5V
via R185 and C156 // C157.

Z117 is the output op-amp. Its outputs a re decoupled via R186,
R187, C158 and C159 so that it has a low output impedance but
can drive cable capacitance without oscillation. R186 and R187
are included in the audio frequency feedback loop to reduce output
impedance when driving ‘difficult’ cables.

RLY100 is a mute relay which shunts the preamp output to
ground. This is to prevent thumps and squeals when the units is
powered up or down.

Power supply

The transformer winding is connected to SK300. The voltage is
rectified and smoothed by D300, D301, D306, D307 and C300,
C310. The un regulated voltage sh ould be around ±27VDC. F300
and F301 are secondary fuses, as the low power preamp winding
would not blow the primary fuses if short circuited.

The voltage regulators a re discrete compound emi tter followers. I
will describe the +15V supply as the negative is essentially an
exact mirror image.

Q300 and R300 act as a constant current source, supplying around
7mA into D310. C302 and C314 reduce ripple and broadband
noise on the zen er diode. Q3 05 and Q306 form a complementary
Darlington NPN transistor which is configured as an emitter
follower, produ cing the + 15VDC at its output. C303 is to pr ovide
bulk charge stora ge an d t o reduce t he AC out put impedanc e of th e
power supply. D302 prevents reverse bias of the supply during
power down.

Z301 is a conventional LM317 type circuit to drop the +15V rail
down to +5V for the tone and volume control circuits.

Star point SP300 explicitly connects the differently named ground
nets together at one point, to minimise hum.

Amplifier & PSU Circuit Description

L882PB is the printed circuit board that provides the power supply
and output stage amplifiers for the A85 integrated and power
amplifiers.
Its function is to:

1. Drive the loudspeakers(!)

2. Provide an (always on) auxiliary 5VDC supply for the micro
controller and display interface

3. Receive logic signals from the micro controller to turn on
the main amp lifier supply rela y (mains) and connect either
pair of speaker output sockets

4. Send logic signals to the micro controller pertaining to the
state of the amplifiers (short circuit protection, DC offset
protection, t hermal protection)

5. Receive and demodulate RC5 remote style control codes via
the rear pan el jack and trans mit them to the micr o controller

6. Send a 12V trigger ou tput via the rea r pan el jack for con trol
of an auxiliary power amp when the unit is on

7. Receive a 12V trigger input from the rear jack (for u s e in the
power amp only version)

8. Drive a pair of headphones via attenuating resistor networks

The power amplifier is a symmetrical, class B, bipolar junction
transistor output, current-feedback design (of which more later)
with DC-coupled signal and feedback paths, featuring an active
integrating volta ge servo to control DC offsets.

It features ‘instantaneous’ safe operating area protection in
addition to sending a signal to the micro to turn off the output
relays in the even t of user or thermal ove rload. Since it i s a DC­coupled desi gn, the unit senses DC at the output and triggers the
micro to turn of f the loudspeak er relays in the even t of excessive
levels (possibly due to a faulty source component or short circuit
output transistor).

The output s tage uses Sank en specia lised ‘audio a mplifier’ pow er
bipolar Darlington transistors which are optimised for use with this
type of topology. Consequently the unit has excellent measured
performance in terms of noise, slew rate, output impedance and
distortion (harmonic and intermodulated) and is essentially load
invariant (to a first order th e measu red p erforman ce i s ind epend ent
of the load impedance).

L882 Circuit Sheet 1

The audio input to the amplifier is connected to SK102 (which
connects to the output of the preamp PCB). This signal is passed
on via SK104A which forms the preamp out connection to the
outside world.

SK104B provides the power amp input connection, with switch
SW100 selecting between pre / power and integrated modes. The
unit is wired as a preamp / power amp combination with the switch
depressed, allowing the user to insert a processor or other function
(e.g. graph ic EQ) between th e output of th e preamp and th e input
of the power amp. With the switch in the ‘out’ position the power
amp input socket is ignored and the input to the power amp is
connected internally to the output of the preamp. PL100 and
PL101 are ‘handbag’ links fitted to the power amp only version to
connect both pairs of phono sockets in parallel for daisy chaining
(as there is no preamp output on a power amp).

Relays RLY100 and RLY101 switch the two pairs of loudspeaker
output sockets and are controlled by the micro lines describes
above. Transistors TR100 and TR101 operate in ‘constant current
sink’ mode which allow relay current to be approximately constant
although the main power supply rails will vary with mains input
and load conditions. The current is around 20mA per relay.

Star point SP100 is the ground ‘mecca’ for the entire amplifier
(comprising a ll three PCBs wit hin the unit ). All of the sepa rately
named grounds are joined explicitly at this point. Different named
grounds are used to ensure that no two ‘different’ grounds share
copper, which could compromise the noise, distortion or crosstalk
performance of the amplifier.

The loudspeaker output signals are passed to socket SK106 which
connects to SK107 and onto the headphone output via the
attenuation resistors R103 thru R106.

The hierarc hy con tai ning t he oth er sheet s i s self expla na tory. E ach
of the port names shown on the top sheet connects t o the port of
the same na me on the lower sheets.

L882 Circuit Sheet 2

This sheet contains the power supplies, the rear panel jack socket
trigger circuits, the standby relay control and the ‘interface’
circuits between the output signals of the power amplifiers and the
inputs expected by the micro processor.

The mains input enters the unit at SK203, with capacitors C205
and C206 acting as conducted RF suppression. The earth
connection is passed on to the chassis (for safety reasons the
chassis metalwork remains connected to mains power earth at all
times). Switch SW200 is the voltage selector switch, allowing the
unit to be operated in 230V or 115V mains countries by switching
the dual-primary mains transformers between series and parallel
winding. Varistors VR200 and VR201 act to prevent over-voltage
surges from da maging the unit . If the user selec ts 115V opera tion
and then connec ts the unit to a 230V sup ply, the varist ors will go
to a low impedance and blow the primary fuses. Any very high
voltage line transients will also be suppressed, helping to eliminate
transformer isola tion breakdown.

Relay RLY200 switches the primary side of the mains transformer,
allowing the micro to control th e on / off status of th e amplifier. Its
contacts are snubbed by capacitors C207 and C208 (to eliminate
switching spark transients and prolong relay lifespan). The primary
windings of the toroidal mains transformer connect to SK204.

PCB mounted transformer TX200 is powered all the time that
mains is presen t on S K203 , i rres p ective of t h e on / off st at u s of the
amplifier. This is to ensure that the micro processor is always
operational and can thus control the mains switching for the main
amplifier. Secondary fuse F202 limits the current in the event of a
failure mode, as the short circuit primary current of TX200 would
be insufficient to blow the mains fuses.

Diodes D200 thru D203, C227 and IC201 provide the 5VDC
supply which powers the micro and display PCB and the relay
coils. C224 is to reduce diode noise being transmitted back
through the leakage capacitance of TX200.

The mains transformer secondary winding is connected to SK200.
This is a centre tapped winding, and is used with full bridge
rectifier BR200 to produce the main positive and negative supplies
for the power amp. C209 and C210 are the large reservoir
capacitors, with C211 and C212 acting as high frequency
decouplers. The main power supply rails and ground are accessible
on SK205 for future module expansion.

The circuitry around SK201A and IC200 is to receive and
demodulate remote control commands sent in via the rear panel
jack socket. This is for mu lti-room applications.
L200 and C200 form a parallel resonant circuit at approximately
37kHz. The output from this bandpass filter is passed into IC200A
where it is ‘chopped’ and fed to IC200B to provide the output
signal.

SK201B is a 13VDC signal trigger output which is active
whenever the am plifier is powered up. R218 and DZ207 / C223
provide a reference voltage which is buffered by TR200. TR201
and R217 act as a current limit and prevent damage due to a short
circuit on the output of SK201B. The maximum current is
approximately 65mA.

TR203 and TR202 are a complementary Darlington pair which
turn on mains relay RLY200 when activated by a signal from the
microprocessor.

TR204 and its associat ed componen ts are to detec t whenever AC
mains is present at the IEC socket. This is to notify the
microprocessor i f the u ser ha s unplugged th e mains cord, s o that it
can take the necessary action (muting all the outputs and switching
off the mains rela y). The reser voir ca pacit ors should last at leas t 4
mains cycles which gives t he microproces sor plenty of time for a
controlled shutdown.

TR204 forms a monostable circuit. Each cycle of AC turns on
TR204 via R211. TR204 then ‘shunts’ C229 ensuring that it is
kept at a low potential. If more than one mains cycle is missing,
then R219 charges up C229 sufficiently to trigger Schmitt inverter
IC202E thus pa ssing on a logic signal to the mi croprocessor. Th e
use of a Schmitt inverter for IC202 is to ensure that the micro
receives ‘clean’ logic levels - the hysteresis voltage (about 0.5V) is
sufficient to prevent circuit noise from producing a string of
‘ghost’ signals wh en analogue levels are near the threshold point.

TH200 is a positive tempco thermistor placed adjacent to the
heatsink on which the output transi stors are mounted. When the
temperature of the thermistor exceeds 90 degrees Celsius the
thermistor goes to a high impedance and so the input to IC202F
goes low. This triggers a HIGH output to the micro indicating
thermal overload .

The VI protection signals from the left and right channels pass into
IC202A and IC202B respectively, to be ‘cleaned up’ via the
Schmitt trigger. They are then NOR’d using TR205 which sends a
HIGH signal t o t h e mi cr o in th e event of ei t h er c h an n el su ff eri ng a
short circuit or current overload. Exactly the same approach is
used for the DC fault lines using IC202C and IC202D.

L882 Circuit Sheet 3

This is the main audio power amplifier circuit. The amplifier is a
class B design, which uses SAP ‘audio’ transistors in a
symmetrical current feedback configuration. Input and feedback
paths are DC c oupled and there is an active integrating s ervo to
remove DC offsets from the output.

The basic principle of operation i s foll ows:
The input signal is amplified by a factor of 2 in IC300A. This
drives a 44 impedance to ground causing the supply pin currents
to change with the signal level. These chan ging supply pin currents
are then ‘reflected’ by a pair of complementary Wilson mirrors
and passed on to a series of buffer transistors before being
connected to the load . The ‘f eedba ck curr ent’ f lows back from the
output terminal via R331 and R332 and attempts to provide the
current necessary to allow IC300A to swing its output without
drawing excessive current from its supply pins, thus making the
change in supp ly current very small i ndeed. This i s why the term
‘current feedback’ is used - it is the current flowing in the
feedback resis tors that sets the overall gain of the amplifier.

IC300B acts as an in vert in g int egra tor a nd its pu rp ose i s to remove
DC from the loudspeaker output. Any positive DC offset will
cause the output of IC300B to go negative, thus increasing the
current in its n egative supply pin and pullin g the output voltage
back towards zero. R330 and C317 set the time constant of this
integrator (0.47 seconds) so that audio frequency components are
ignored and only DC and subsonic frequencies are removed.

The input to the amplifier is limited to ±5.4V via back-to-back
zener diodes D Z302 and DZ303. Th is is to prevent th e user from
grossly overdriving the input to the amplifier and possibly causing
damage. The diodes appear before series resistor R324 so that their
variable capacitance does not introduce high frequency harmonic
distortion.

R324, R327 and C316 act a s an input filter - this is a first order
low pass filter with a corner frequency of around 340kHz to
prevent RF sign als from being in jected into the fron t end of the
amplifier. The corner frequency was ch osen such that the phase
shift introduced is less than 5 at 20kHz (considered by the AES
to be the minimum perceptible relative amount by the human ear).
The input impedance of the amplifier is 23kW at DC, falling to
around 14kW at 20kHz.

Operational amp lifier IC300A is actin g as a non-invertin g gain of
2, driving the input signal into a 44W impedance to ground via
R322 and R337. Its output voltage will be an accurate
amplificati on of its input voltage (i.e. the signal on pin 1 should
look identic al t o th at on pi n 3 bu t a t twice t he am pli tude). The op ­amp is used in a slightly unusual configuration here, in that its
power supply pins are used as a (current) output, and its output pin
is used as a (current) feedback.

Transistors TR311 and TR303 supply the ±15V rails to the op­amp, and act as cascades to pass its supply pin currents through to
the current mirrors, which sit at a potentia l too high for the op-amp
to be connected directly.

TR300, TR301 and TR321 form a PNP Wilson current mirror,
which reflects the current sunk by the positive supply pin of
IC300. Likewise TR314, TR315 and TR320 form an NPN Wilson
current mirror, which reflects the current sou rced by the negative
supply pin of IC300.

R315 thru R318 provide emitter degeneration of approximately
300mV for the current mirrors (as they pass about 3mA DC in
quiescent c onditions) , to ensure ac curate oper ation ind ependent of
the small variations between t he transistors in the current mirrors.
They also ensure that the current passing down the next sta ge is
reasonably constant as the internal temperature of the amplifier
changes, swamp ing out small t hermal varia tions in the V
mirror transistors.

R319 and R320 slightly decouple the rails to the current mirrors
from the main power rails of the amp lifier, to allow the bootstra p
circuit to operat e. The bootstrap consis ts of C302 and C306 with
metal film power resistors R352 and R353. The bootstrap is
provided to allow the power supply rails of the current mirrors to
go up and down slightly with the output signal into the
loudspeaker. This enables the driver stage to fully saturate the
output transi stors and thu s give th e greatest power outp ut and b est
thermal effici ency for any given power rail voltage. The voltage on
the ‘inside’ end of R319 and R320 will vary by about 12 volts
peak to peak at full output power, rising above the main power
rails during signal peaks.
C307 and C308 with R333 and R335 provi de the compensation
necessary to ensure stability when the loop is closed. They are
Miller capacitors which dramatically reduce the transimpedance
(i.e. current to voltage gain) of the current mirrors at high
frequencies. The present value of 47pF provides for a unity gain
open loop ban dwidth of around 75MHz, whilst en suring a clos ed
loop gain margin of around 6dB (note that gain margin in a current
feedback design is not dependent on system bandwidth to a first
order approximati on). R3 33 and R335 provid e a ‘zero’ in th e open
loop frequency response which is tailored to give the best time
domain performance (i.e. to make high frequency square waves
look square with minimal ringing or overshoot).

DZ304 and C311 provide a fixed 4.7V bias voltage to allow the
following st ages to opera te correc tly. C31 1 is ther e to ensure t hat

of the

BE

both halves of the following stage receive an equal AC signal
component at high frequency.

TR310 and TR307 are the ‘pre-driver’ transistors, which act to
buffer the outputs from the preceding stage and drive the
Darlington output power transistors. TR309 and R321 act as a
current limit, to ensure that the emitter current of TR310 does not
exceed 30mA in a fault condition. TR306 and R323 provide the
same function for TR307.

R338 and R339 are to lo osely cou ple t he out puts of t he pre-d river
stage to the inpu ts of the Da rlingt on power outpu t devices. This is
so that the inbuilt temperature sensing diodes of the output
transistors can accurately control the quiescent current of the
output stage as the junction temperature of the power devices
varies. C312 and C31 8 ensure tha t both halves of t he output sta ge
receive an equal AC signal component.

The output t ransistors are TR318 and TR 319. These are Sanken
SAP15N and SAP15P devices respectively. They are specially
designed for audio power amplifier use. In addition to high current
gain (Darlington with a typical h
inbuilt emitter resistor (thick film power resistor of 0W22) and
temperature sensing diodes which closely and rapidly track the
V

versus temperature characteristic of the power transistors,

BE

allowing for easy, fast-responding and reasonably accurate control
of quiescent current (one of the major headaches of class B
amplifier des ig n!)

RV300 is for fine trimming of the quiescent current. PL300
provides a convenient measuring point for this, which is short­circuit protected in the event of a slip with the multimeter probe!
All of the remaining circuitry to the right of TR318 and TR319 is
essentially for output stage p r otection...

Transistors TR312 and TR304, alon g with th e network of resist ors
and capacitors to which they are connected, provide instantaneous
overload protection of the output stage. This is a conventional
single slope VI protection scheme, which allows much greater
current to be delivered into a rated load than into a short circuit.
The values allow for 18A peak delivery (at clip) into a purely
resistive load, 7A peak (at clip) into a purely capacitive load and
around 4A peak in to a short circui t. R345, C303, R34 6 and C304
allow these values to be doubled for short transient bursts
(approximately 2.7 milliseconds) so that impulsive musical
transients can be delivered cleanly with minimal risk of damaging
the output transistors.

TR313, TR302 and th eir associated components send a signal to
the micropro cessor when the inst antaneous protect ion circuits are
having to work ‘hard’ to prevent amplifier overload. This instructs
the micro th at the user is sever ely abusing th e amplifier and will
switch off the loudspeaker relays to prevent possible permanent
damage. In reality, if you short circuit the outputs at any
appreciable volume level, this circuit will trigger and the
microprocessor will turn off the loudspeaker relays and send a
signal to the user.

R308, R314 and C320 form a low pass filter from which the DC
detection circuits can sense excessive DC at the loudspeaker
outputs. If there i s any positive DC present, then TR316 will turn
on, which turns on TR305 and thus activates the DC p rotection
line to the micro, turning off the loudsp eaker relays.

If there is any negative DC present, then TR308 will turn on,
which turns on TR317 whi ch then tu rns on TR305 in turn, cau sing
the same effect.

R350 and C319 are the Zobel network which is provided to ensure
the amplifier ‘sees’ a constant and resistive load at very high
frequencies, to aid stability, although the amplifier will be stable
without the Zobel fitted.

of 20,000) they provide an

FE

C313 locally couples the ‘high frequency’ and loudspeaker ground
returns together at the output to overcome the effects of track
inductance back to the star point. C309 couples the ‘high
frequency’ and signal grounds togeth er at the input for th e same
reason.

D303 and D304 are ‘flyback’ diodes to protect the output
transistors from reverse bias when the amplifier is heavily clipped
into an inductive load (such as a loudspeaker voice coil!)

Sheet 4 is an identical copy of sheet 3 so I will not describe it
separately.

L870 Phono Circuit Description

The Phono board is a simple single stage RIAA amplifier. It
consists of two channels of high gain amplification, and switching
between moving magnet (MM) and moving coil (MC) settings.

PSU
The unit derives its ±15V regulated rails from the unit it is fitted

into with only local decoupling capacitors on board.
Interface
The unit connects to the host unit via a 8 way connector:
Amplifier
The left channel has designators beginning with 100, and the right

with 200. For the pu rposes of t his descri ption the left chann el will
be described, as the right channel the same in all respects.

The amplifier is a small signal class A voltage feedback amplifier
with switchable gain. The input consists of an actively loaded
differential pair of very low noise PNP tran sistors (TR106,107).
These transistors are very specific and should only be replaced
with identical parts with the E grade high gain. TR100 & TR101
form a current source for the pair, which sets the qui escent current
for the entire amplifier. The active load consists of TR110 &
TR111, which forms part of a differential current mirror with
TR112,113 & 114. This differential stage also has an active load
(TR102 & TR103) to keep gain to a maximum .

Both of these d i ff eren ti a l st a ges a re des i gned t o h a ve a s mu ch gain
as possible to enable the single stage design. The RIAA response
is achieved in the feedback network:
C101,110,111, 112,119,120,&R115,112. C115 is used to correct
between MM & MC gains as the amplifier is non-inverting.

SW100 switches between MM & MC. Two poles of the switch
change between the different loading required for each type of
cartridge: R108 & C109 for MM, and added in parallel for MC
R104 & C108. The oth er two poles change the feed back resistor
value to alter the gain. MM: R105 and in parallel for MC R123.

The DC offset is c ontrolled by a non-i nverting servo b uilt around
IC100. The amount of servo current is different for each gain
setting via R111 (MM ) & R124(MC) so that the low frequency
high pass point remains the same for both settings. However the
high pass point for the circuit is set by C113. This gives a warp
filter, stops DC startup thumps from upsetting DC coupled
circuitry an d an approximation of the RIAA/ IEC curve (-2dB @
20Hz).

The output is class A buffered by a dual mirror follower
(TR104,105,108,109). The quiescent current is set up by D100
and R118,119.

Closed loop stability is achieved with C116,117, giving
symmetrical slewing capability.

SK103 connects to the micro controller and display PCB.
The 14 pin connector is numbered as follows:

No Name Type Description
1 +5V_D O/P 5 volt digital supply (for micro)
2 0V_D O/P Digital ground
3 +49V O/P Main power supply for VFD (via fusible resistor)
4 STANDBY I/P Mains relay control signal (HIGH = ON)
5 SPKR1 ON I/P Speaker 1 relay control signal (HIGH = ON)
6 SPKR2 ON I/P Speaker 2 relay control signal (HIGH = ON)
7 THERMPROT O/P Over temperature protect (HIGH = FAULT)
8 VIPROT O/P Short circuit protect (HIGH = FAULT)
9 DCPROT O/P DC offset protect (HIGH = FAULT)
10 AC PRESENT O/P Indicates AC mains is plugged in (HIGH = ON)
11 TRIGGER O/P 12V DC trigger input (HIGH = ON)
12 REMOTE O/P Demodulated RC5 remote input from rear panel
13 0V_D O/P Spare digital ground pin
14 +5V_D O/P Spare 5 volt digital supply pin

The ground naming convention is as follows:

Name Description
0V_D Digital ground (used for micro processor circuitry, display and interface)
0V_LS_R Right channel loudspeaker ground return
0V_SIG Signal ground (this is the ‘clean’ precision reference ground)
0V_PSU Power supply ground (high current pulses for the large reservoir caps)
0V_TRIG Ground return for the jack socket trigger and remote control circuit
0V_HF_R Decoupling ‘noisy’ ground for the right channel power amp
0V_LS_L Left channel loudspeaker ground return
0V_HF_L Decoupling ‘noisy’ ground for the left channel power amp

A85, P85, P85/3 Service Guide

Build History

ECO
Number

00_1089 02/10/00 A85 – Fascia position changed to prevent display buttons sticking
00_1129 01/11/00 A85, P85, P85/3 – Improved stability under heavy clipping of amplifier R345,

00_1138 27/11/00 A85, P85, P85/3 – C303, C304, C403 changed from 10uF to 100uf capacitors –

01_1030 23/02/01 A85, P85, P85/3 – RV300, RV400 changed to 220R presets to make it easier to

01_1068 11/04/01 A85, P85, P85/3 – New output device clamp fitted to heatsink
01_1101 04/06/01 A85, P85, P85/3 – Sensitivity of DC offset detection circuit reduced – Power

01_1142 22/08/01 A85 – Preamp board upgraded from L866 to L937
01_1178 12/10/01 A85, P85, P85/3 – Speaker terminals changed from Camcon to 4mm binding

01_E014 28/11/01 A85 – Preamp board fuses F300, F301 up rated to 2A surface mount
02_E033 31/01/02 A85 – Extra pad F038 fitted under TX to stop TX coming loose in transit
02_E035 04/02/02 A85, P85, P85/3 – Main 20mm fuse rating changed to 4AT

Software History

ECO
Number

01_1072 18/04/01 1.1 Remote standby action changed from turning unit completely off

01_1095 21/05/01 1.2 Delay added to start H8 start up routine (volume control chip)
01_1167 12/09/01 1.3 Volume chip read/write protocol changed
01_1179 26/10/01 2.0 Added the processor mode option
01_E011 23/11/01 2.1 Corrected the welcome message saving fault. This fault was

02_E048 15/02/02 2.2 Corrected the processor loop volume jump when v/c adjusted

Current Fuse Ratings (20/02/02)

Fuse Position Fuse Rating

Main Supply fuses - A85, P85, P85/3 2 x 4AT 20mm (Arcam part number C12406)
PSU fuse F202 - A85, P85, P85/3 750mA surface mount (Arcam part number C3751)
Preamp fuses F300, F301 – A85 2A surface mount (Arcam part number C3202)

Quiescent Current Setting

Left channel Measure points indicated on PCB -

Right channel Measure points indicated on PCB -

Date Description of Change

R346, R445, R446 changed from 100R to 0R link
C307, C308, C407, C408 changed from 47P to 100P capacitors

this prevents protection circuit from operating when driving a 4 ohm load at
low frequenc y

adjust the bias settings

amp cct R308, R408 changed to 22K - R314, R414 changed to 10K
PSU surface mount fuse F202 up rated from 500mA to 750mA

post

Date Version Description of Change

to putting unit into standby

introduced with version 2.0 software

Adjust RV300 for 8.5mV cold or 12 mV when warm

Adjust RV400 for 8.5mV cold or 12 mV when warm

Fault Diagnostics

Fault Action

No power Check fuses

Check power supply rails

Unit functions ok but no audio Check preamp fuses

Check RL100A (volume control mute relay)
Check +5V supply rail

Check mute signal line
Volume cont rol locks up Check softwar e version is 2 .0 or higher
DC offset Check equipment connected to amp for DC on the audio leads

Check alterations as per ECO 01_1101 have been fitted
Unit fails to respond to commands Check ribbon cable from display to main board

Check ribbon cable from display to preamp board
Unit gets very hot Check power stage IQ settings

Hints & Tips

!

To check software version press PHONO, TUNER, DVD buttons on the front panel
simultaneously.

!

On issue 2 phono boards only, fit Kapton insulation tape to the phono stage PCB (rear panel
end) to prevent track shorting to chassis.

!

Check all fuses are the correct rating.

!

Check DC offset alterations are fitted as per ECO 01_1101

!

To isolate a fault between the pre or power amp section press the PRE/PWR button on the
rear panel to separate the two sections.

!

Check R100 on amp/psu board is not shorting to the track underneath (through plated via).

87654321

D

L882C3

L882C3_3.2.SCH
L SIG
0V SIG
0V_LS_L
0V_HF_L
+49V

-49V +5V_D

R SIG
0V_SIG
0V LS R
0V_HF_R
+49V

-49V

INPUT
0V_SIG

0V_HF
VPOS
VNEG

L882C4

L882C4 3.2.SCH

INPUT
0V_SIG

0V_HF
VPOS
VNEG

VIPROT

DCPROT

OUTPUT0V_LS

VIPROT

DCPROT

OUTPUT0V_LS

VIPROT L
DCPROT L
LS L

VIPROT_R
DCPROT_R
LS R

0V D
0V_PSU

STANDBY
VIPROT_L
VIPROT_R
0V TRIG
DCPROT L
DCPROT_R

L882C2
L882C2 3.2.SCH

0V_D +5V(D)
0V_PSU
PWRON

THPROT_uCVIPROT_L

VIPROT_R VIPROT_uC
DCPROT_L

DCPROT_R

DCPROT_uC

AC_PRES0V_TRIG

TRG IN

VPOS
VNEG

RC5 IN

+49V

-49V
THERMPROT
VIPROT
AC PRESENT
DCPROT
REMOTE
TRIGGER

0V TRIG

0V_D

34

5 6

1 2

SP100

STAR_8

TP121

78

0V SIG
0V HF R

D

0V_LS_R
0V LS L0V HF L
0V_PSU

C

FROM PREAMP

SK102

1
2
3
4

AMPCT4

0V_SIG

1

PHONO4G

F

EMC

N

SK104A

0V_SIG

SW100A
2PCO

1

2

PL100

2

C100
1N0 SM

0V_SIG

PL101

2

3

1

TP100

1

SK104B

F

N

PHONO4G

TP101

TP102

L SIG
R SIG

LS L

0V_LS_L

LS R

SK105

HPSKT

LHC

RHC

R

+49V

RLY100C

D100

SK106
1
2
3
4

AMPCT4

4

TP118

L

5
2

3
1

6
7

TP119

TP120

R105
100R 1W CF

R103
330R 1W CF

R104
330R 1W CF

R106
100R 1W CF

SK107
1
2
3
4

AMPCT4

1N4003F

TR100
BD179

RLY G5Z-2A-E

TR101
BD179

R107
220R SM

RLY101C
RLY G5Z-2A-E

R101
100R SM

R102
100R SM

R108
220R SM

D101
1N4003F

C

SPKR1 ON

SPKR2 ON

B

SK103

1
2
3
4
5
6
7
8
9
10
11
12
13
14

SW100B
2PCO

R100
10R MF

4

5

6

INTEGRATED / PRE-POWER
MODE SELECT SWITCH

+5V D

+49V

STANDBY
SPKR1 ON
SPKR2 ON
THERMPROT
VIPROT
DCPROT
AC PRESENT
TRIGGER
REMOTE
0V_D

TP103

TP104

TP105

TP106

TP107

TP108

TP109

TP110

TP117

LS L

TP111 TP113 TP115

0V_LS_L

LS R

TP112 TP114 TP116

0V_LS_R

RLY100A

RLY G5Z-2A-E

RLY100B

RLY G5Z-2A-E

SK100A

Top+

Top-

CAMCON_G

SK101A

Top+

Top-

CAMCON_G

RLY101A

RLY G5Z-2A-E

RLY101B

RLY G5Z-2A-E

SK100B

Bot+

Bot-

CAMCON_G

SK101B

Bot+

Bot-

CAMCON_G

PCB

PCB

L882PB_3
EL

EARTH LEAD

8M101

EARTH LEAD

0V D

B

A

FFC 14W 2.54MM VER
8K7014

DRAWING TITLE

A85 amplifier and PSU - top sheet

23425

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

Notes:

Filename

L882C1_3.2.PRJ

Circuit Diagram

01_1101 JR 6/4/01 POWER SUPPLY FUSES AND DC OFFSET 3.2
00_1134 MGM 17/11/00 NO CHANGE TO THIS SHEET
00_1138 JR 27/11/00 NO CHANGE TO THIS SHEET
00_1129 JR 1/11/00 NO CHANGE TO THIS SHEET
00_1115 JR 16/10/00 NO CHANGE TO THIS SHEET
00_1086 JR 19/9/00 NO CHANGE TO THIS SHEET

ECO No. DESCRIPTION OF CHANGE

Date Printed

INITIALS

6-Jun-2001

DATE

Drawn by:

J Reckless

1 4Sheet of

DRAWING NO.

L882C1

2.4

A

2.3

2.2

2.1

2.0

ISSUE

1 2 3 4 5 6 7 8

NEUTRAL

87654321

SK204

4
3

D

EMC Shield

BC200
TOOLING4.1

SH200
EMCMAINS

Green

SK202
CAGECLAMP1

1

C205
3N3 MAINS

TP206

N E L

N

E

TP200

TP207

EARTH

C234

SK203

IEC3 NO RIVETS

L

C206

3N3 MAINS

LIVENEUTRAL

LIVE

NEUTRAL

LIVE

SW200B
VOL SEL SLIDE

F200

AS2A

SW200A
VOL SEL SLIDE

F201

AS2A

2
1 5

MOLEXPWR8

RLY200A

DPDT5V

C207

3N3 MAINS

RLY200B

DPDT5V

C208

3N3 MAINS

8
7
6

TP202

TP201

TP210

TP203

1 0V

NF
VR200

VDR 115V

2
3

NF

VR201

VDR 115V

4

TX200

9V

115V

0V

9V

0V

115V
TX 3VA 9301

HS200
TO220HS08REG

9VRMS

IC201

F202

5

T750mA SM

C224
6
7

8

100N CD

D200
1N4003F

D201
1N4003F

TP204

D202
1N4003F

+

C227
3300u 25V

D203
1N4003F

7805

I

Vin

C225
100N CD

GND

G

Vout

O

HS

TP205

C226
100N CD

0V_D

+5V_D

+5V(D)

+

C228
1000u 10V

0V_D

D

220N X2 CLASS

R231
1M5 VR25

C

+49V

TP208

VPOS

SK205
1
2
3
4
5
6

AMPCT6

VNEG

SK200

3
2
1

MOLEXPWR6

1

BR200
BRGBU8D

+

6
5
4

3

~

-

4

2

~

+

C209
10,000u 63V

+

C210
10,000u 63V

C211
100N PC

0V_PSU

C212
100N PC

0V_PSU

TP209

MAINS WIRING AND AUXILIARY SUPPLY

9VRMS

R211
10K SM

TR204
BC849B

D206
BAS16W SM

0V_D

+5V_D

R219
1K8 SM

+

C229
22U EL

+5V_D

IC202E

74HC14D

MICROPROCESSOR SIGNALS INTERFACE

1011

R220

AC_PRES

10R SM

C

POWER AMP SUPPLY

-49V

CARRIER FILTER AND DEMODULATOR

R223
10K SM

1

R229
100K SM

C231

1N0 SM

5
6

R209
10K SM

R224
1K8 SM

R230
1K5 SM

R225
1K8 SM

IC200A

2
3

LM393A SM

C230
10N SM

R222
10K SM

TRG IN

SK201A

B

TP211

Near to PCB

JACK3.5X2

MODULATED RC5
REMOTE CONTROL INPUT

R226
470R SM

R227
1K0 SM

R228
100K SM

DZ204
4V7 350MW SM

RC5 IN

R208
10K SM

L200
27mH

IC200B

7

LM393A SM

C200
680P PP

+5V_D

84

IC200C
LM393A SM

C232
100N SM

+

C233
10U EL

VIPROT_L

R201
1K0 SM

R202

VIPROT_R

1K0 SM

14

IC202G
74HC14D

7

C214
10N SM

0V_D

C201
100N SM

IC202A

1 2

74HC14D
IC202B

3 4

C215
10N SM

74HC14D

C202
100N SM

0V_D

TH200
PTH90DEG

R205
1K0 SM

R213
4K7 SM

R214
4K7 SM

IC202F

74HC14D

C219
10N SM

+5V_D

R206
1K0 SM

0V_D

R221

1213

10R SM

TR205
BC856B

THPROT_uC

B

C203
100N SM

VIPROT_uC

C218
10N SM

+5V_D

0V_TRIG

+49V

R218

+5V_D

TR200
RLY200C
DPDT5V

R200

A

STANDBY RELAY CONTROL

R212

PWRON

4K7 SM

1K0 SM

TR203
FMMT497

D205
BAS16W SM C213

10N SM

TR202
FMMT597

0V_D

TRIGGER OUTPUT
APPROX 13.5VDC
60mA MAX CURRENT

SK201B

Far from PCB

JACK3.5X2

0V_TRIG

C235

1N0 SM

BD179

TP212

R210
10K SM

CAMCON_G
SK101C

R217
10R SM

+

C222
10U EL

CHASS

TR201
FMMT497

10K SM

DZ207
15V 350MW SM

+

C223
10U EL

0V_TRIG

DRAWING TITLE

A85 amplifier - power supply and microcontroller interface

23425

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

DCPROT_L

DCPROT_R

Notes:

Filename

L882C2 3.2.SCH

R203
1K0 SM

R204
1K0 SM

C216
10N SM

C217
10N SM

0V_D

Circuit Diagram

IC202C

5 6

74HC14D
IC202D

74HC14D

R207
1K0 SM

0V_D

TR206
BC856B

DATE

C204
100N SM

DCPROT_uC

C220
100N SM

NO CHANGE TO THIS SHEET 2.1

Drawn by:

J Reckless

2 4Sheet of

DRAWING NO.

L882C2

A

2 4

2.2

ISSUE

R215
4K7 SM

89

R216
4K7 SM

01_1101 JR 6/4/01 POWER SUPPLY FUSES AND DC OFFSET 3.2
00_1134 MGM 17/11/00 NO CHANGE TO THIS SHEET
00_1138 JR 27/11/00 NO CHANGE TO THIS SHEET 2.3
00_1129 JR 1/11/00 NO CHANGE TO THIS SHEET
00_1115 JR 16/10/00
00_1086 JR 19-9-00 R231, C234, C235 ADDED FOR EMC 2.0

ECO No. DESCRIPTION OF CHANGE

Date Printed

C221
10N SM

INITIALS

6-Jun-2001

1 2 3 4 5 6 7 8

87654321

D

R319
100R SM

R300
10K SM

R315
100R SM

R316
100R SM

PRE DRIVER

VPOS

D

PNP CURRENT MIRROR

TR310
TR300
FMMT597

+

C300
100U EL

0V_HF

C

INPUT

DZ302
4V7 350MW SM

DZ303
4V7 350MW SM

0V SIG

0V_SIG

+

0V_HF

C301
100U EL

DZ300
15V 350MW SM

C310
100N SM

0V_SIG

INPUT FILTER V TO I AMP

R324
1K0 SM

C309
100N SM

0V_HF

DZ301
15V 350MW SM

R327
22K SM

0V_SIG

3
2

C316
470P PPW

C314
100N SM

TR311
FMMT497

R328
4K7 SM

TP302

84

IC300A

TL072CD

TP303

TR303
FMMT597

7

0V_SIG

1

C317

470N PE

IC300B

TL072CD

TP304

R322
22R SM

R337
22R SM

0V_SIG

R333
3K3 SM

100P SM

DC SERVO

R330

6

1M0 SM

5

0V_SIG

R331
1K5 SM

R332
1K8 SM

C311
100N PC

R335
3K3 SM

100P SM

C307

TR322
FMMT497

C308

TR301
FMMT597

TR321
FMMT597

R355
6K8 SM

R354
1K0 SM

TR320
FMMT497

TR309
FMMT497

R338
150R SM

BOOTSTRAP

+

C302
100U EL 100V

R352
470R 2W MF 5%

470R 2W MF 5%
R353

+

C318
10U EL

+

C306
100U EL 100V

BOOTSTRAP

R339
150R SM

TR306
FMMT597

FMMT497

R321
22R SM

C312

10N SM

R323
22R SM

ADJ BIAS

RV300
100R PSET

D300
BAS16W SM

OUTPUT STAGE

TR318
SAP15N

TP305

R325
1K0 SM

R340
100K SM

R326
1K0 SM

TP306

TR319
SAP15P

OUTPUT STAGE

PL300

1
2

MEASURE
BIAS
(SET TO 16mV)

R341
330R SM

R342
330R SM

R343
100R SM

R344
100R SM

V-I PROTECTION

R334
22K SM

R347
100R SM

R345
0R0 SM

+

C303
100U EL

+

C304
100U EL

R346
0R0 SM

R348
100R SM

R336
22K SM

V-I PROTECTION

D301
BAS16W SM

TR312
FMMT497

TR304
FMMT597

D302
BAS16W SM

D303
1N4003F

DC OFFSET SIGNAL
TO MICRO

D304
1N4003F

0V_HF

R349
100R SM

DCPROT

TR305
FMMT597

TP308

DZ306
4V7 350MW SM

R302
10K SM

R310
4K7 SM

C315
100N SM

R301
10K SM

R329
4K7 SM

TR313
FMMT497

R303
10K SM

R304
10K SM

0V_HF

TR316
FMMT497

TR302
FMMT597

R305
10K SM

R306
10K SM

+

DC OFFSET
DETECTION

R307
10K SM

R313
10K SM

VI PROTECT
SIGNAL TO MICRO

TP307

C305
10U EL

R308
22K SM

VIPROT

DZ305
4V7 350MW SM

0V_HF 0V_LS

C320
100U NP

2U2H LAC SMALL

R350
5R6 2W CF

C319
100N PE

R314
10K SM

R351
10R MF

L300

ZOBEL NETWORK

C313

100N SM

C

OUTPUT

0V LS

0V HF

TR314

R309
10K SM

FMMT497

NPN CURRENT MIRROR

R317

B

100R SM

R320
100R SM

TR315
FMMT497

R318
100R SM

TR307

FMMT597

PRE DRIVER

TR308
FMMT597

R311
10K SM

R312
10K SM

B

TR317
FMMT497

VNEG

A

01_1101 JR 6/4/01 POWER SUPPLY FUSES AND DC OFFSET 3.2

DRAWING TITLE

A85 amplifier - power output stage left

Circuit Diagram

23425

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

1 2 3 4 5 6 7 8

Notes:

Filename

L882C3 3.2.SCH

00_1134 MGM 17/11/00 NO CHANGE TO THIS SHEET
00_1138 JR 27/11/00 C303 C304 FROM 10U TO 100U 2 3
00_1129 JR 1/11/00 R345 R346 C307 C308 VALUE CHANGES
00_1115 JR 16/10/00 R338 R339 CHANGED TO 150R
00_1086 JR 19/9/00 NO CHANGE TO THIS SHEET 2 0

ECO No. DESCRIPTION OF CHANGE

Date Printed

INITIALS

6-Jun-2001

DATE

Drawn by:

J Reckless

3 4Sheet of

DRAWING NO.

L882C3

2 4

2 2

2.1

ISSUE

A

87654321

D

R419
100R SM

R400
10K SM

R415
100R SM

R416
100R SM

PRE DRIVER

VPOS

D

PNP CURRENT MIRROR

TR410
TR400
FMMT597

+

C400
100U EL

0V_HF

C

INPUT

DZ402
4V7 350MW SM

DZ403
4V7 350MW SM

0V SIG

0V_SIG

+

0V_HF

C401
100U EL

DZ400
15V 350MW SM

C410
100N SM

0V_SIG

INPUT FILTER V TO I AMP

R424
1K0 SM

C409
100N SM

0V_HF

DZ401
15V 350MW SM

R427
22K SM

0V_SIG

3
2

C416
470P PPW C411

C414
100N SM

TR411
FMMT497

R428
4K7 SM

TP402

84

IC400A

TL072CD

TP403

TR403
FMMT597

7

0V_SIG

1

C417

470N PE

IC400B

TL072CD

TP404

R422
22R SM

R437
22R SM

0V_SIG

R433
3K3 SM

100P SM

DC SERVO

R430

6

1M0 SM

5

0V_SIG

R431
1K5 SM

R432
1K8 SM

TR422
FMMT497

100N PC

R435
3K3 SM

100P SM

C407

C408

TR401
FMMT597

TR421
FMMT597

R455
6K8 SM

R454
1K0 SM

TR420
FMMT497

TR409
FMMT497

R438
150R SM

BOOTSTRAP

+

C402
100U EL 100V

R452
470R 2W MF 5%

470R 2W MF 5%

R453

+

C418
10U EL

+

C406
100U EL 100V

BOOTSTRAP

R439
150R SM

TR406
FMMT597

FMMT497

R421
22R SM

C412

10N SM

R423
22R SM

ADJ BIAS

RV400
100R PSET

D400
BAS16W SM

OUTPUT STAGE

TR418
SAP15N

TP405

R425
1K0 SM

R440
100K SM

R426
1K0 SM

TP406

TR419
SAP15P

OUTPUT STAGE

PL400

1
2

MEASURE
BIAS
(SET TO 16 mV)

R441
330R SM

R442
330R SM

R443
100R SM

R444
100R SM

V-I PROTECTION

R434
22K SM

R447
100R SM

R445
0R0 SM

+

C403
100U EL

+

C404
100U EL

R446
0R0 SM

R448
100R SM

R436
22K SM

V-I PROTECTION

D401
BAS16W SM

TR412
FMMT497

TR404
FMMT597

D402
BAS16W SM

D403
1N4003F

DC OFFSET SIGNAL
TO MICRO

D404
1N4003F

0V_HF

R449
100R SM

DCPROT

TR405
FMMT597

TP408

DZ406
4V7 350MW SM

R402
10K SM

R410
4K7 SM

C415
100N SM

R401
10K SM

R429
4K7 SM

TR413
FMMT497

R403
10K SM

R404
10K SM

0V_HF

TR416
FMMT497

TR402
FMMT597

R405
10K SM

R406
10K SM

+

DC OFFSET
DETECTION

R407
10K SM

R413
10K SM

VI PROTECT
SIGNAL TO MICRO

TP407

C405
10U EL

R408
22K SM

VIPROT

DZ405
4V7 350MW SM

0V_HF 0V_LS

C420
100U NP

R450
5R6 2W CF

C419
100N PE

R414
10K SM

R451
10R MF

L400

2U2H LAC SMALL

ZOBEL NETWORK

C413

100N SM

C

OUTPUT

0V LS

0V HF

TR414

R409
10K SM

FMMT497

NPN CURRENT MIRROR

R417

B

100R SM

R420
100R SM

TR415
FMMT497

R418
100R SM

TR407

FMMT597

PRE DRIVER

TR408
FMMT597

R411
10K SM

R412
10K SM

B

TR417
FMMT497

VNEG

A

01_1101 JR 6/4/01 POWER SUPPLY FUSES AND DC OFFSET 3.2

DRAWING TITLE

A85 amplifier - power output stage right

Circuit Diagram

23425

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

1 2 3 4 5 6 7 8

Notes:

Filename

L882C4 3.2.SCH

00_1134 MGM 17/11/00 L300 L400 CHANGED TO 7D002C
00_1138 JR 27/11/00 C403 C404 FROM 10U TO 100U 2 3
00_1129 JR 1/11/00 R435 R436 C407 C408 VALUE CHANGES
00_1115 JR 16/10/00 R438 R439 CHANGED TO 150R
00_1086 JR 19/9/00 NO CHANGE TO THIS SHEET 2 0

ECO No. DESCRIPTION OF CHANGE

Date Printed

INITIALS

6-Jun-2001

DATE

Drawn by:

J Reckless

4 4Sheet of

DRAWING NO.

L882C4

2 4

2 2

2.1

ISSUE

A

DISP1
DISP SSV-07MS09

87654321

R1

R3

R2

10K SM

D

C

B

C1

100N SM

Test pad change for issue 3:
Q_23= SO (was STBLED)
Q_9=SI (was GND)

DATA /O

SK1

A

FFC8H SM

R14
4K7 SM

+5V

SW3
PAUSE

R15
1K0 SM

R11
10K SM

Q3
BC847B

Q_26

Q5
BC856B

Q6
BC846B

R12
10K SM

D5

BZX284-C5V6

R7
33K SM

F1

SW4
PLAY

Q4
BC847B

VKK

CATHODE BIAS CCT

IRIRQ

+

SW5
STOP

C5
10U EL SM

SW6
OPEN

Q_18

R5
470R SM

LED2
LED GREEN3 1MM

HDCD

+

C6

10U EL SM

(was POWER)
SW7

FWD>>

SO
SI

SCK
CS

F2

Q_29

Q_1

Q_2

Q_3

Q_4

BAS16W SM

D1

BAS16W SM

D2

BAS16W SM

D3

BAS16W SM

D4

R16
1K0 SM

R6
1K0 SM

HDCDLED

STBLED

C4

1N0 SM

1
2
3
4
5
6
7
8

9
10
11

+5V

+5V

VKK_D

VKK_CK

VSS

Q1
BC856B

+5V

38L439L340L241L142

VDD

Q2
BC847B

Q_24

Q_25

43

44

OSC

SW1
SW2
SW3
SW4
SO
SI
VSS
SCK
CS
K1
K2

K312K413VDD14S115S216S317S418S519S620S721S8

C2
100N SM

DRAWING TITLE

DVD DISPLAY PCB

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

F11F12G15G26G37G48G59G610G7

11

C3
100N SM

G1
G2
G3

37

G434G335G236G1

G5

G6
S16/G7
S15/G8
S14/G9

S13/G10

VEE

S12/G11

S11
S10

S9

22

LED1

R

On=Green
Standby=red

G

LED RED/GRN 3MM

Notes

Filename

J:\ECO wip\L886 DV88 Display board correct R4 cock-up\L8863\L8863.0a.ddb - L886 3.0a.sch

G4

Z1

33

G5

32

G6

31

G7

30
29
28
27

VKK

26
25
24
23

BU2872AK

SEG8
SEG7
SEG6
SEG5
SEG4
SEG3
SEG2
SEG1

R4
220R SM

FIX1
FIX NG HOLE

Circuit Diagram

SEG15
SEG14
SEG13

SEG12
SEG11
SEG10
SEG9

74HC74 SM

7

FIX2
FIXING HOLE

GND

14

+5V

VCC

Z2C

C8
100N SM

FIX3
FIX NG HOLE

FIX4
FIXING HOLE

ECO No. DESCRIPTION OF CHANGE

Date Printed

S125S226S327S428S529S630S731S832S933S1034S1135S1236S1337S1438S1539F242F2

F2F1

43

PCB

L886PB_3

SP1

IR RX SUPPORT PAD

PS

PHOTO_STRIP

EL1

UPDATE_BOX

DD2

10

12

D

11

CLK

Display clips: PCB footprint is called E882PM
This footprint will accept either E874PM (current clip)
or E882PM (new clip not designed yet)
This part type currently calls for p/n E874PM, change to E882PM when new clip is available

INITIALS

Z2B

9

Q

SD

8

Q

CD

74HC74 SM

13

LC1

VFD CLIP

E882PM
E874PM

DVD DISPLAY CLIP

PG 17/11/00 Correct error R4 is 1206 not 0805 3.0a
PG00_1082 14/09/00 Change RX1 to l/p part, test pad changes, display clip, R4 VALUE 3.0
CL 23/08/00 MINOR MODIFICATIONS 2.0
CL 31/07/00 PRODUCTION RELEASE 1.0

DATE

LC2

VFD CL P

E882PM
E874PM

DVD DISPLAY CL P

Drawn by:

PG17-Nov-2000

DD6

CLOGO

Layout by

Cliff

1 1Sheet of

DRILL_DWG

DRAWING NO.

10K SM

10K SM

SBX1610-52/PIC-26043TM2

Q_7

1

_6

2

_5

3

Q_30

4

_8

5
6
7
8

1 2 3 4 5 6 7 8

Q_27

K3

Q_28

K2

+5V

R13
1M0 SM

3

RX1

O/P

+5V

O/P

GND1Case

Case

GND +5V

DUAL FOOTPRINT

+5V

R8
4K7 SM

Q_23

SO
IR RQ
CS
SCK
SI

Q_9

2
3

C7
100N SM

2

Pwr in

+5V

SW1
SKIP>

SW8
<<RWD

(was MENU)

+5V

4

D

SD

CLK

CD

1

R9
10K SM

SK2

Q_10

1

Q_11

2

Q_12

3

Q_13

4
5

Q_14

6

AMPCT6H

K4

SW2
<SKIP

VKK switching CCT

Z2A

5

Q

6

Q

74HC74 SM

VKKIN VKK

R10
10K SM

VKKIN

VKK = -19.5V
F1= -13.9V
F2 = -9 6V

PCB

R RX

SUPPORT PAD

DD1

PCB MATERIAL

FR4, 1 OZ Cu

FR4_1OZ

Photo Strip

Update Box

Drilling

Detail

DD3

A2 Horizontal

Paper Marker

DD_A3H

DD4

A2 Vertical

Paper Marker

DD_A3V

FD_1

F DUCIAL

D

C

B

FD_2

FIDUCIAL

A

ISSUE

L886_3

4321

D

C

D

C

Main signal path
L937C2 1.1.SCH

B

Power supply
L937C3 1.1.SCH

B

USE EXCLUDE NF WHEN USING RUNOUT SHEET PROGRAM

DRAWING TITLE

Integrated amplifier preamp

PCB1

A

PCB

L937PB_1

23425

A & R Cambridge Ltd.
Pembroke Avenue

Notes:

Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

1 2 3 4

Filename

J:\Change_Control\ECO_AGENDA\01_E014 Fuse changes on A32 preamp\L937_1.1.ddb - Documents\Schematic\L937C1_1.0.PRJ

Circuit Diagram

01_E014 JBR 28/11/01 Fuses uprated to 2A 1.1
01_1142 JBR 14/8/01 First production release 1.0

ECO No. DESCRIPTION OF CHANGE

Date Printed

INITIALS

28-Nov-2001

DATE

Drawn by:

JBR

1 3Sheet of

DRAWING NO.

L937C1

ISSUE

A

87654321

D100

+15V -15V

BAV99W DUAL SM

SK2A

CDL1 CDL

0V_SIG

D101
BAV99W DUAL SM

D102
BAV99W DUAL SM

0V_SIG

TUNR1

D106
BAV99W DUAL SM

D107
BAV99W DUAL SM

0V_SIG

D108
BAV99W DUAL SM

D112
BAV99W DUAL SM

0V_SIG

D113
BAV99W DUAL SM

D114
BAV99W DUAL SM

0V_SIG

D115
BAV99W DUAL SM

D116
BAV99W DUAL SM

0V_SIG

D117
BAV99W DUAL SM

R100
1K0 SM

R101
1K0 SM

R102
1K0 SM

R125
1K0 SM

R126
1K0 SM

R127
1K0 SM

R156
1K0 SM

R157
1K0 SM

R158
1K0 SM

R189
1K0 SM

R190
1K0 SM

R191
1K0 SM

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

0V_SIG

R103
100K SM

CDR

R104
100K SM

TUNL

R105
100K SM

TUNR

R128
100K SM

AVL

R129
100K SM

AVR

R130
100K SM

DVDL

R159
100K SM

DVDR

R160
100K SM

TAPEIL

R161
100K SM

TAPEIR

R192
100K SM

VCRIL

R193
100K SM

VCRIR

R194
100K SM

CD L

470P FKP2

CD R

0V_SIG

TUNER L

TUNER R

0V_SIG

AV L

AV R

0V_SIG

DVD L

DVD R

TAPE IN L

TAPE IN R

VCR IN L

VCR IN R

C101

C102
470P FKP2

C103
470P FKP2

C122
470P FKP2

C123
470P FKP2

C124
470P FKP2

C140
470P FKP2

C141
470P FKP2

C142
470P FKP2

C161
470P FKP2

C162
470P FKP2

C163
470P FKP2

CD INPUT

1

F

EMC

N

C100
1N0 SM

0V_SIG

D

TUNER INPUT

CDR1

PHONO4G

+15V -15V

+15V -15V

SK2B

TUNL1

F

N

PHONO4G

+15V -15V

+15V -15V

C

AV INPUT

SK3A

AVL1

1

F

EMC

N

C121
1N0 SM

0V_SIG

DVD INPUT

B

TAPE INPUT

AVR1

PHONO4G

+15V -15V

+15V -15V

SK3B

DVDL1

F

N

DVDR1

PHONO4G

+15V -15V

+15V -15V

SK4A

TAPEIL1

1

F

EMC

N

C139
1N0 SM

0V_SIG

VCR INPUT

A

C160
1N0 SM

0V_SIG

TAPEIR1

PHONO4G

+15V -15V

+15V -15V

SK5A

VCRIL1

1

F

EMC

N

VCRIR1

PHONO4G

+15V -15V

1 2 3 4 5 6 7 8

+15V

-15V

+15V

-15V

+15V

-15V

0V_SIG

C106
100N SM

C107
100N SM

C125
100N SM

C126
100N SM

C127
100N SM

C128
100N SM

0V_SIG

0V_SIG

+15V

C104
100N SM

C105
100N SM

-15V

0V_SIG

0V_SIG

0V_SIG

+15V

-15V

+15V

C145
100N SM

C146
100N SM

-15V

AUX INPUT

C164
1N0 SM

VCR2

C143
100N SM

C144
100N SM

PHONO2G

AUX L
CD L
TUNER L
AV L
DVD L

VCR IN L
MODULE L

0V_SIG

AUX R
CD R
TUNER R
AV R
DVD R

VCR IN R
MODULE R

TAPE 2

AUX L
CD L
TUNER L
AV L
DVD L
TAPE IN L

MODULE L

VCR01

AUX R
CD R
TUNER R
AV R
DVD R
TAPE IN R

MODULE R

AUX L
CD L
TUNER L
AV L
DVD L
TAPE IN L
VCR IN L
MODULE L

LIST2

AUX R
CD R
TUNER R
AV R
DVD R
TAPE IN R
VCR IN R
MODULE R

LISTEN0

LISTEN1

LISTEN2

D118
BAV99W DUAL SM

AUXIL1

1

TAPE 1

TAPE 2

TAPE 0

TAPE 1

LIST1

TAPE 0

0V_SIG

0V_SIG

VCR 2

0V_SIG

VCR 2

0V_SIG

LIST0

VCR 1

VCR 1

R162
22K SM

R163
22K SM

R164
22K SM

R165
22K SM

R166
22K SM

R167
22K SM

R168
22K SM

R169
22K SM

TAP0

TAP1

TAP2

TAPE0

TAPE1

TAPE2

VCR11

VCR21

VCR0

VCR1

+15V -15V

SK6

F

EMC

N

0V_SIG

AUXIR1

+15V -15V

D119
BAV99W DUAL SM

VCR 0

VCR 0

R195
1K0 SM

R196
1K0 SM

+5V

+5V

+5V

+5V

-15V

-15V

LISTEN 0
LISTEN 1
LISTEN 2

0V_SIG

LISTEN 0
LISTEN 1
LISTEN 2

0V_SIG

Z100
4
5
6
7

12
11
10

9
2

1

16
15

14

3

DG408DY

Z101
4
5
6
7

12
11
10

9
2

1

16
15

14

3

DG408DY

Z102
4
5
6
7

12
11
10

9
2

1

16
15

14

3

DG408DY

Z103
4
5
6
7

12
11
10

9
2

1

16
15

14

3

DG408DY
R170

22K SM
R171

22K SM
R172

22K SM
R173

22K SM

R174
22K SM

R175
22K SM

R176
22K SM

R177
22K SM

AUXL

0V_SIG

0V_SIG

X0
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

X0
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

X0
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

X0
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

+5V

+5V

R197
100K SM

AUXR

R198
100K SM

-15V

-15V

AUX R

AUX L

V+

D

V+

D

V+

D

V+

D

4
5
6

7
12
11
10

9

2

1
16
15

14

3

4

5

6

7
12
11
10

9

2

1
16
15

14

3

+15V
13
8

R106
1M0 SM

0V_SIG

+15V-15V
13
8

R107
1M0 SM

0V_SIG

+15V
13
8

R131
1M0 SM

0V_SIG

+15V-15V
13
8

R132
1M0 SM

0V_SIG

Z104

X0

V+
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

DG408DY
Z105

X0

V+
X1
X2
X3
X4
X5
X6
X7

EN
A0
A1
A2

GND
V-

DG408DY

SK103

1
2
3
4
5
6
7

TO PHONO PCB

8

AMPCT8

C165

0V_SIG

470P FKP2

C166
470P FKP2

D

D

AUX R

AUX L

13
8

13
8

+15V

+15V

+15V1

0V_HF

0V_SIG

0V_SIG

-15V1

-15V

3
2

5
6

3
2

5
6

C147
100N PE

C167
100N PE

+15V

AUXR1

AUXL1

+15V -15V

D103
Z109A
TL072 SM

Z109B
TL072 SM

Z110A
TL072 SM

Z110B
TL072 SM

C148

22P SM
R178
22K SM

2

Z115A

3

OPA2134PA SM

C149

22P SM
R179
22K SM

2

Z116A

3

OPA2134PA SM

Z109C

TL072 SM

Z113C

TL072 SM

BAV99W DUAL SM

R108

1

47R SM

C108
100P SM

+15V -15V

D104

BAV99W DUAL SM

R109

7

47R SM

C109
100P SM

+15V -15V

D109

BAV99W DUAL SM

R133

1

47R SM

C129
100P SM

+15V -15V

D110

BAV99W DUAL SM

R134

7

47R SM

C130
100P SM

Z115_1A

1

R180
100K SM

R199
100K SM

84

-15V

84

-15V

7

OPA2134PA SM
+15V

1

7

OPA2134PA SM

C168
100N SM

0V_SIG 0V_SIG 0V_SIG 0V_SIG

C169
100N SM

-15V2

C170
100N SM

0V_SIG 0V_SIG 0V_SIG 0V_SIG 0V_SIG

C171
100N SM

C150

470N PE

+

+

-15V
C151

470N PE

TAPE02

Z115B

C188
10U EL

C189
10U EL

Z116_1A

Z116B

TL072 SM

TL072 SM

TAPEO1

0V_SIG

VCRO1

0V_SIG

VCR02

Z110C

Z114C

VCR OUTPUT

6
5

0V_SIG

0V_SIG

6
5

0V_SIG

84

84

SK4B

F

N

PHONO4G

SK5B

F

N

PHONO4G

R183
1M0 SM

R184
1M0 SM

C172
100N SM

C173
100N SM

C174
100N SM

C175
100N SM

TAPE OUTPUT

TONE*

C152
100N SM

TONE*

Z111C

TL072 SM

Z115C

OPA2134PA SM

84

84

0V_SIG

C176
100N SM

C177
100N SM

C178
100N SM

C179
100N SM

1
2
3
4

6
7
8

+

C110
100U EL

0V_SIG

+

C131
100U EL

0V_SIG

Z106

SEL1
D1
S1
V­GND5VL
S4
D4
SEL4

DG413DY

+15V2

Z112C

TL072 SM

OPA2134PA SM

SEL2

SEL3

+15V

84

84

Z116C

+5V

R110
2K2 SM

R112
22K SM

R111
2K2 SM

Z115_1B

+5V

R135
2K2 SM

R137
22K SM

R136
2K2 SM

Z116_1B

TONE

+5V

C180
100N SM

C181
100N SM

C182
100N SM

C183
100N SM

/TONE

TONE*

OPA2134PA SM

16
15

D2

14

S2

13

V+

12
11

S3

10

D3

9

Z111_3

Z113_3

+15V-15V

0V_SIG

+15V

84

Z117C

R113
22K SM

+

R138
22K SM

+

Z111A
TL072 SM

3
2

C111
10U CERAFINE

Z113A
TL072 SM

3
2

C132
10U CERAFINE

+

Z107_4

C153
100N SM

Z107_13

0V_SIG

0V_SDATA

0V_SLOAD

0V_SCLK

C184
100N SM

C185
100N SM

C154
10U EL

Z111_7

Z113_7

1

1

0V_SIG

R182
100R SM

R200
2R2 SM
R201
2R2 SM
R202
2R2 SM

Z111_1

Z113_1

C155
100N SM

D105
BAV99W DUAL SM

0V_SIG

1618

Z108D
17

DS1844

5
6

R115
2K7 SM

R116
2K7 SM

D111
BAV99W DUAL SM

62

Z108B
7

DS1844

5
6

R140
2K7 SM

R141
2K7 SM

0V_SIG

C156
100N SM

1

0V_SIG

AVCC

SCLK

SDATA

+5V

C186

100N SM

0V_SIG

Z112_3

Z108_19

C113
470N PE

Z114_3

Z108_3

C134
470N PE

LFO

LMO
RFO

RMO

16

R181
10K SM

DS1844

0V_SIG

DS1844

0V_SIG

1519

53

+

C157
100U EL

3

2
14

15

Z107
VSDVC

Z108A
14

0V_SIG

Z108C
4

0V_SIG

0V_SIG

+

R117
5K6 SM

R142
5K6 SM

C187
10U EL

C114
CFKP2 63V 2N2

3
2

C135
CFKP2 63V 2N2

+15V

2

Z117A

3

OPA2134PA SM

6

Z117B

5

OPA2134PA SM

R114
22K SM

7
Z111B

TL072 SM

C112

470N PE

C192

470N PE

+5V

R139
22K SM

7
Z113B

TL072 SM

C133

470N PE

C193

470N PE

+5V

R185
22R SM

Z107_1

7

DVCC

4

LIN

5

LGND

13

RIN

12

RGND

DGND11XCS6DATA9CCLK10XMUTE8AGND

SLOAD

DRAWING TITLE

Integrated amplifier preamp - main signal path

23425

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

Notes:

Filename

J:\Change Control\ECO AGENDA\01 E014 Fuse changes on A32 preamp\L937 1.1.ddb Documents\Schematic\L937C2 1.0 SCH

Circuit Diagram

Z112A
TL072 SM

3
2

R118
22K SM

Z114A
TL072 SM

C136

22P SM

R143
22K SM

+

C190
10U EL

+

C191
10U EL

-15V

C158
22P SM

C159
22P SM

D120
BAS16W SM

C115

22P SM

1

7

Z112B
TL072 SM

Z112_1

5

1

6

Z114B

Z114_1

TL072 SM

5

1

6

+15V -15V

0V_SIG

SK102_1

R186
47R SM

SK102_3

R187
47R SM

+5V

+-RLY100C

RLY DPDT 5V SM

Q100
BC849B

0V_D

Z112_7

7

0V_SIG

7

R144
22K SM

R145
22K SM

+

C137
10U CERAFINE

0V_SIG

D121
BAV99W DUAL SM

RLY DPDT 5V SM

0V_SIG

R203
4K7 SM

01_E014 JBR 28/11/01 Fuses uprated to 2A 1.1
01_1142 JBR 14/8/01 First production release 1.0

ECO No. DESCRIPTION OF CHANGE

Date Printed

C117

+

10U CERAFINE

R119
22K SM

R120
22K SM

+

C116
10U CERAFINE

C138

+

10U CERAFINE

D122
BAV99W DUAL SM

RLY100A

MUTE*

INITIALS

Z106_14

R121
22K SM

Z106_11Z114_7

R146
22K SM

RLY100B

RLY DPDT 5V SM

DATE

SCLK

SDATA

TONEID

0V_D

0V_TONEID

SK102
1
2
3
4

AMPCT4
TO POWER AMP I/P

Drawn by:

JBR28-Nov-2001

SCLK

SDATA

TONEID

IC DS1844

0V_TONEID

0V_SDATA

0V_SCLK

LISTEN 0
LISTEN 1
LISTEN 2
VCR 0
VCR 1
VCR 2
TAPE 0
TAPE 1
TAPE 2

TONE*
TONEID

0V_SDATA

13
12

9

R122
2R2 SM

R124
2R2 SM

R123
2R2 SM

MUTE*

SDATA

0V_SLOAD

0V_SIG

2 3Sheet of

+5V

CLK
DIN
RST

R147
22K SM

R148
22K SM

R149
22K SM

R150
22K SM

SLOAD

0V_SCLK

R188

10K SM

20

Z108E

VCC

1

PS

8

R/W

11

DOUT

GND

10

0V_SIG

SCLK

AUX L
AUX R
CD L
CD R
TUNER L
TUNER R
AV L
AV R
DVD L
DVD R
TAPE IN L
TAPE IN R
VCR IN L
VCR IN R
MODULE L

MODULE R

0V_MODULE

DRAWING NO.

C118
100N SM

R204
10K SM

C119
10N SM

R151
22K SM

R152
22K SM

R153
22K SM

R154
22K SM

R155
22K SM

FFC22V1MM

L937C2

+

C120
10U EL

SK100
1
2
3
4
5
6
7
8

9
10
11
12
13
14
15
16
17

TO MICRO / DISPLAY PCB

18
19
20
21
22

SK101

1

2

3

4

5

6

7

8

9
10
11
12
13
14
15
16
17
18
19
20

TO PLUG IN MODULE PCB
21
22

23
24
25
26
27
28
29
30

FFC30V SM

ISSUE

D

C

B

A

4321

D302

BAS16W SM

Q305
2SA1964

D

C

SK300
MOLEXPWR4

3

4

1

2

F300

T2A SM

F301

T2A SM

AC1

C307
470N PE

AC2

D300
S1D

C308
100N SM

C309
100N SM

D301
S1D

UR+

+

C300
1000u 35V

Q300
J112

R300
330R SM

C314
1N0 PP

C315
1N0 PP

Q303
J112

Q306
BC846B

D310+

+

C302
220U EL

+

C312
220U EL

D311-

D310
15V 350MW SM

D311
15V 350MW SM

+15V

+

+

I

+15V3

C304
100N SM

C303
3300u 25V

C313
3300u 25V

Z301
LM317T

Vin

0V_PSU

D304

BAS16W SM

Vout

ADJ

A

+3.75V

R302
1K2 SM

R307
220R SM

O

+

C305
10U EL

-15V

D305
BAS16W SM

+15V

0V_PSU

0V_MODULE

R303
470R SM

SK301
1
2
3
4

IDC4S

+5V

+5V

+

C306
470U EL 25V

D

C

D306
S1D

B

D307
S1D

+

UR-

C310
1000u 35V

R304
330R SM

Q301
2SC5248

D308

BAS16W SM

Q307
BC856B

-15V

-15V3

SP300
STAR POINT 4

0V_HF 0V_MODULE

0V_PSU

0V SIG

0V_SIG

B

DRAWING TITLE

Integrated amplifier preamp - power supply

A

23425

Notes:

Circuit Diagram

01_E014 JBR 28/11/01 Fuses uprated to 2A 1.1

A

A & R Cambridge Ltd.
Pembroke Avenue
Denny Industrial Centre
Waterbeach
Cambridge CB5 9PB

1 2 3 4

Filename

J:\Change_Control\ECO_AGENDA\01_E014 Fuse changes on A32 preamp\L937_1.1.ddb - Documents\Schematic\L937C3_1.0.SCH

01_1142 JBR 14/8/01 First production release 1.0

ECO No. DESCRIPTION OF CHANGE

Date Printed

INITIALS

28-Nov-2001

DATE

Drawn by:

JBR

3 3Sheet of

DRAWING NO.

L937C3

ISSUE