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HX290 Service Manual

1. Receive Signal Path

Incoming RF from the antenna jack passes through a low-
pass filter consisting of coils L1001, L1002, & L1004, ca-
pacitors C1005, C1009, C1015, C1025, & C1214, antenna
switching diode

D1004

(

RLS135

), and Surge Protector

diode

D1005

(

1SS400

Signals within the frequency range of the transceiver en-
ter a high-pass filter consisting of coils L1012 and L1014,
capacitors C1054, C1057, and C1065, then amplified by

Q1015

(

3SK294

) and enter a Varactor-tuned band-pass

filter consisting of coils L1021 & L1023, capacitors C1098,
C1102, C1104, C1113, C1115, & C1211, and diode

D1016

(

DAN235E

), before first mixing by

Q1023

(

3SK318

Buffered output from the VCO is amplified by

Q1004

(

2SC5006

) to provide a pure first local signal between

134.35 and 141.575 MHz for injection to the first mixer

Q1023

(

3SK318

The 21.7 MHz first mixer product then passes through
monolithic crystal filter XF1001/XF1002 to strip away all
but the desired signal, which is then amplified by

Q1025

(

2SC4915

). The amplified first IF signal is applied to FM

IF subsystem IC

Q1026

(

NJM2591V

), which contains the

second mixer, second local oscillator, limited amplifier,
noise amplifier, and RSSI amplifier.

A second local signal is produced from the PLL reference/
second local oscillator of X1001 (21.25 MHz). The 21.25
MHz reference signal is delivered to mixer section of FM
IF subsystem IC

Q1026

(

NJM2591V

) which produce the

450 kHz second IF mixed with the first IF signal.

The second IF then passes through the ceramic filter
CF1001 to strip away unwanted mixer products, and is
then applied to the limited amplifier in the FM IF sub-
system IC

Q1026

(

BA4116FV

), which removes amplitude

variations in the 450kHz IF, before detection of the speech
by the ceramic discriminator CD1001.

2. Audio Amplifier

The demodulated audio signal from the

Q1026

(

NJM2591V

) passes through the de-emphasis circuit, then

applied to the audio filter

Q1030

(

LM2902PWR

). Then

passes through the audio mute switch

Q1033

(

TC7S66FU

), the audio volume VR1006 and the audio

power amplifier

Q1035

(

TDA2822L

) pin 7, providing up

to 700 mW of audio power to the 16-ohm loudspeaker.

3. Squelch Control

The squelch circuitry consists of a noise amplifier and
band-pass filter and noise detector within

Q1026

(

NJM2591V

). When no carrier received, noise at the out-

put of the detector stage in

Q1026

(

NJM2591V

) is ampli-

fied and band-pass filtered by the noise amplifier section
of

Q1026

(

NJM2591V

) and the network between pins 7

and 8, and then rectified by detection circuit in

Q1026

(

NJM2591V

The resulting DC squelch control voltage is passed to pin
64 of the microprocessor

Q1028

(

UPD78F0484GK

). If no

carrier is received, this signal causes pin 38 of

Q1028

(

UPD78F0484GK

) to go low and pin 67 to go high. Pin 67

signals of

Q1028

(

UPD78F0484GK

) to disable the supply

voltage to the audio amplifier

Q1035

(

TDA2822

Thus, the microprocessor blocks output from the audio
amplifier, and silences the receiver, while no signal is be-
ing received (and during transmission, as well).

4. Transmit Signal Path

The speech input from the microphone MC1001 passes
through the audio amplifier

Q1027

(

NJM12902V

), which

is adjusted the microphone gain. The speech signal pass-
es through pre-emphasis circuit to

Q1027

(

NJM12902V

which contains the IDC, and low-pass filter. Then passes
through VR1004 which allows manual adjustment of the
transmitter deviation level.

The filtered audio signal is applied to varactor diode