ICOM IC-F3061T 用户手册
Power
amp.
amp.
ALC
amp.
amp.
Drive
amp.
amp.
+
–
HV
“ISENS”
• APC CIRCUIT
to the anntena
“T2”
“TMUT”
from TX/RX switch
(MAIN UNIT; D14, D15)
(MAIN UNIT; D14, D15)
T5V
Q604, Q605
Q602
Pre-
drive
amp.
drive
amp.
Q603
IC601
Q601
to the receive circuits
LPF
LPF
ANT
SW
Current
detector
D604
Power detecter
D605
Q606
The output AF signals are then passed through the Digital/
Analog switch (IC14, pins 12, 14) and applied to the AF mixer
(IC9, pin 6) where the MIC signals and Tone signals are mixed
with (while CTCSS/DTCS are in use) via the PM/FM switch
(IC13, pins 12, 14).
Analog switch (IC14, pins 12, 14) and applied to the AF mixer
(IC9, pin 6) where the MIC signals and Tone signals are mixed
with (while CTCSS/DTCS are in use) via the PM/FM switch
(IC13, pins 12, 14).
The CTCSS and DTCS signals are generated by the CPU
(IC18) and output from pins 89−91. The output signals are
passed through the 3 registers (R263–R265) to change its wave
form. The wave form changed CTCSS/DTCS signals are passed
through the LPF (IC17, pins 1, 3) and the D/A converter (IC4,
pins 21, 22) for level adjustment. The level adjusted CTCSS/
DTCS signals are then applied to the AF mixer (IC9, pin 6).
(IC18) and output from pins 89−91. The output signals are
passed through the 3 registers (R263–R265) to change its wave
form. The wave form changed CTCSS/DTCS signals are passed
through the LPF (IC17, pins 1, 3) and the D/A converter (IC4,
pins 21, 22) for level adjustment. The level adjusted CTCSS/
DTCS signals are then applied to the AF mixer (IC9, pin 6).
2/5 tone and DTMF signals are
generated by the CPU (IC18)
and output from pin 43. The output signals are passed through
two LPF's (IC17, pins 8, 10 and pins 5, 7), then applied to the AF
mixer (IC9, pin 6).
two LPF's (IC17, pins 8, 10 and pins 5, 7), then applied to the AF
mixer (IC9, pin 6).
The mixed AF signals are output from pin 7 of the AF mixer
(IC9) and passed through the D/A converter (IC4, pins 3, 4)
for level adjustment (=deviation adjustment), then applied to
the modulation circuit (D9) as the modulation signals. The
modulation signals are also applied to the reference frequency
oscillator (X1) via D/A converter (IC4, pins 11, 12) and AF
amplifi er (IC21, pins 1, 4).
(IC9) and passed through the D/A converter (IC4, pins 3, 4)
for level adjustment (=deviation adjustment), then applied to
the modulation circuit (D9) as the modulation signals. The
modulation signals are also applied to the reference frequency
oscillator (X1) via D/A converter (IC4, pins 11, 12) and AF
amplifi er (IC21, pins 1, 4).
5-2-2 MODULATION CIRCUIT (MAIN UNIT)
The modulation signals from the microphone amplifi er circuits
are applied to the D9, and modulate the VCO oscillating
signal by changing the reactance of D9. The modulated VCO
output signal is buffer-amplifi ed by Q4 and Q6, then applied to
transmit amplifi ers as a transmit signal via the TX/RX switch
(D14 is ON, D15 is OFF).
The modulation signals from the microphone amplifi er circuits
are applied to the D9, and modulate the VCO oscillating
signal by changing the reactance of D9. The modulated VCO
output signal is buffer-amplifi ed by Q4 and Q6, then applied to
transmit amplifi ers as a transmit signal via the TX/RX switch
(D14 is ON, D15 is OFF).
5-2-3 TRANSMIT AMPLIFIERS (RF UNIT)
The transmit signal from the TX/RX switch (MAIN UNIT; D14
is ON, D15 is OFF) is amplifi ed to the transmit output level by
pre-driver (Q603), driver (Q602) and power (Q601) amplifi ers.
The transmit signal from the TX/RX switch (MAIN UNIT; D14
is ON, D15 is OFF) is amplifi ed to the transmit output level by
pre-driver (Q603), driver (Q602) and power (Q601) amplifi ers.
The power-amplified transmit signal is passed through the
two LPF’s (L607, L608, C620, C622−C624, C664 and L606,
C615−617) to filter off the harmonic components in the
transmit signal. The fi ltered transmit signal is passed through
the antenna switching circuit (D601 and D603 are ON), then
applied to the antenna connector (CHASSIS; J1) via another
LPF (L601−L603, C601, C602, C604−C606, C608, C609, C663).
two LPF’s (L607, L608, C620, C622−C624, C664 and L606,
C615−617) to filter off the harmonic components in the
transmit signal. The fi ltered transmit signal is passed through
the antenna switching circuit (D601 and D603 are ON), then
applied to the antenna connector (CHASSIS; J1) via another
LPF (L601−L603, C601, C602, C604−C606, C608, C609, C663).
5-2-4 APC CIRCUIT (RF UNIT)
The APC (Automatic Power Control) circuit stabilizes transmit
output power to prevent the transition of the transmit output
power level which is caused by load mismatching or heat
effect, etc. The APC circuit also selects transmit output power
from high, middle and low power.
The APC (Automatic Power Control) circuit stabilizes transmit
output power to prevent the transition of the transmit output
power level which is caused by load mismatching or heat
effect, etc. The APC circuit also selects transmit output power
from high, middle and low power.
A portion of the transmit signal is detected by the transmit power
detector (D604, D605) to produce a DC voltage corresponding to
the transmit output power level. The detected voltage is applied
to the APC amplifier (IC601, pin 3). The transmit power setting
voltage “T2” from the D/A converter (MAIN UNIT; IC20, pin 2) is
applied to another input terminal (pin 1) as the reference voltage.
detector (D604, D605) to produce a DC voltage corresponding to
the transmit output power level. The detected voltage is applied
to the APC amplifier (IC601, pin 3). The transmit power setting
voltage “T2” from the D/A converter (MAIN UNIT; IC20, pin 2) is
applied to another input terminal (pin 1) as the reference voltage.
The APC amplifi er compares the detected voltage and reference
voltage, and the difference of the voltage is output from pin 4.
The output voltage controls the bias of the drive (Q602) and
power (Q601) amplifiers to reduce/increase the gain of these
amplifi ers for stable transmit output power.
voltage, and the difference of the voltage is output from pin 4.
The output voltage controls the bias of the drive (Q602) and
power (Q601) amplifiers to reduce/increase the gain of these
amplifi ers for stable transmit output power.
The change of transmit output power is carried out by the
change of reference voltage "T2," and the transmit power
muting is carried out by the TX mute switch (Q606), using the
“TMUT” signal from the CPU (IC18, pin 13).
change of reference voltage "T2," and the transmit power
muting is carried out by the TX mute switch (Q606), using the
“TMUT” signal from the CPU (IC18, pin 13).
5-2-4 OVER CURRENT DETECTION CIRCUIT (RF UNIT)
The driving current of the drive (Q602) and power (Q601)
amplifiers is detected at the current detector (Q604, Q605)
by detecting the difference of voltage between both terminals
of R623. The detected voltage "ISENS" is applied to the CPU
(IC18, pin 47).
The driving current of the drive (Q602) and power (Q601)
amplifiers is detected at the current detector (Q604, Q605)
by detecting the difference of voltage between both terminals
of R623. The detected voltage "ISENS" is applied to the CPU
(IC18, pin 47).
In case of the over current, the CPU outputs "TMUT" signal
from pin 13 to TX mute switch (Q606) to stop the transmitting
for protection of transmit amplifi ers (Q601, Q602).
from pin 13 to TX mute switch (Q606) to stop the transmitting
for protection of transmit amplifi ers (Q601, Q602).
5-3 PLL CIRCUITS
5-3-1 VCO (Voltage Controlled Oscillator) CIRCUITS
(MAIN UNIT)
A VCO is a oscillator which its oscillating frequency is
controlled by adding voltage (lock voltage).
(MAIN UNIT)
A VCO is a oscillator which its oscillating frequency is
controlled by adding voltage (lock voltage).
This transceiver has 3 VCO’s; RX VCO1 (Q1, D1−D4), RX
VCO2 (Q2, D5−D8) and TX VCO (Q3, D10−D12). The RX
VCO1 oscillates the 1st LO signals for 155 MHz and higher,
and the RX VCO2 oscillates the 1st LO signals for 155 MHz
and lower frequencies. And the TX VCO oscillates the transmit
output signal.
VCO2 (Q2, D5−D8) and TX VCO (Q3, D10−D12). The RX
VCO1 oscillates the 1st LO signals for 155 MHz and higher,
and the RX VCO2 oscillates the 1st LO signals for 155 MHz
and lower frequencies. And the TX VCO oscillates the transmit
output signal.
• RX VCO1 and RX VCO2
The RX VCO1/RX VCO2 (Q1, D1−D4/Q2, D5−D8) oscillates
the 1st LO signals. The output signals are amplified by the
buffer amplifi ers (Q4, Q6), and applied to the 1st mixer (Q37)
via TX/RX switch (D14 is OFF, D15 is ON) and LPF (L38,
L39, C161−C164, C383, C384), to be mixed with the received
signals to produce the 46.35 MHz 1st IF signal.
The RX VCO1/RX VCO2 (Q1, D1−D4/Q2, D5−D8) oscillates
the 1st LO signals. The output signals are amplified by the
buffer amplifi ers (Q4, Q6), and applied to the 1st mixer (Q37)
via TX/RX switch (D14 is OFF, D15 is ON) and LPF (L38,
L39, C161−C164, C383, C384), to be mixed with the received
signals to produce the 46.35 MHz 1st IF signal.
• TX VCO
The TX VCO (Q3, D10−D12) oscillates the transmit signal.
The output signal is applied to the transmit amplifi ers via the
buffer amplifi ers (Q4, Q6) and TX/RX switch (D14 is ON, D15
is OFF).
The TX VCO (Q3, D10−D12) oscillates the transmit signal.
The output signal is applied to the transmit amplifi ers via the
buffer amplifi ers (Q4, Q6) and TX/RX switch (D14 is ON, D15
is OFF).
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