EFJohnson 764X, 761X service manual B UHF 7640 CIRCUIT DESCRIPTION, Uhf Receiver Circuit

NOTE: The UHF transceiver block diagram is located on page 8-6.

5.5 UHF RECEIVER CIRCUIT

5.5.1 ANTENNA SWITCHING CIRCUIT

The antenna switching circuit functions as a low- pass filter while receiving and a resonator circuit while transmitting. This prevents the transmit signal from entering the receiver in the transmit mode.

Received signals enter the antenna connector and pass through a low-pass filter consisting of L1-L3, C1, C2, and C9-C12. The filtered signal is then fed through a quarter-wave type antenna switching circuit formed by D4, D5, and L15 and applied to the receiver RF circuit.

5.5.2 RF CIRCUIT

The RF circuit amplifies the frequencies that are within the receive band range and attenuates out-of- band signals.

The signal from the antenna switching circuit passes through attenuator D4/D5. The attenuator cir- cuit functions only when the attenuator function is assigned to a programmable key. It is enabled to mini- mize RF amplifier distortion caused by excessively strong receive signals.

When the attenuator function is turned on, CPU IC1, pin 32 switches the voltage level of the “RF ATT” line from high to low and then controls the attenuator switch Q1. The D4/D5 current then increases and D4/D5 act as an attenuator.

This signal is then applied to a two-stage tunable bandpass filter controlled by D7 and D8. The filtered signals are amplified by RF amplifier Q2 and applied to another two-stage bandpass filter controlled by D9 and D10. These filters attenuate unwanted signals.

The filtered signal is then applied to the first mixer Q3.

The tunable bandpass filters controlled by D7-

D10 employ varactor diodes to tune them to the center frequency of the RF passband. This gives a wide bandwidth receiver good image response rejection. The diodes are controlled by the CPU IC1 via level controller IC12.

5.5.3 FIRST MIXER AND FIRST IF CIRCUITS

The first mixer circuit converts the received sig- nal to a fixed frequency first IF signal of 46.350 MHz. The RF signal from the bandpass filter is applied to the first mixer Q3. This signal is mixed with the first LO signal from VCO Q23 and buffers Q28 and Q30 to produce the IF signal.

The 46.350 MHz first IF signal then passes through a pair of crystal filters (FI1A/B) which sup- press out-of-band signals. The filtered signal is then amplified by first IF amplifier Q4 and applied to second IF system IC1.

5.5.4SECOND IF AND DEMODULATOR CIRCUITS

The second mixer circuit converts the 46.350 MHz first IF signal to a 450 kHz second IF signal. A double-conversion superheterodyne receiver like this improves the image rejection ratio and provides a stable receiver gain.

FM IF system IC1 contains second mixer, limiter amplifier, quadrature detector, active filter and noise amplifier circuits (see Figure 5-4). The first IF signal from IF amplifier Q4 is applied to IC1, pin 16 which is the input to the second mixer section. The 46.350 MHz first IF signal is mixed with the 45.900 MHz second LO signal to produce the 450 kHz second IF signal. The PLL reference frequency of 15.300 MHz is tripled to produce the 45.900 MHz second LO signal.

The second IF signal is fed out of IC1 on pin 3 and applied to ceramic filters FI2 and FI3 with narrow band operation or only FI2 with wideband operation (bypassing FI3). It is then fed back into IC1 on pin 5