User's Manual
2650 Watt VHF High Band Transmitter Chapter 4, Circuit Descriptions
435B, Rev. 0 4-23
that is connected to the plus input of
U1C, producing a peak of sync in the
signal. The output of U1C is connected to
intercarrier notch L3, which is adjusted to
filter out the aural and the 4.5-MHz
intercarrier frequencies. The visual-with-
sync output is fed to a peak-detector
circuit, consisting of CR5 and U2A, and
then fed through visual calibration control
R28 to amplifier U2B. The amplified
visual peak of sync output is connected
to J6, pins 2 and 3, which supply the
peak of sync visual level output to the
front panel meter for monitoring. R32
moves the pulse to where the sync
should be and R25 sets the visual
metering calibration with no sync
present.
4.1.9.3 Reflected Level Circuit
A reflected-power sample is applied to J3
of the visual/aural metering board and is
detected by diode detector CR7 and U3B.
The detected output is fed through
reflected calibration pot R39, which can
be adjusted to control the gain of U3C.
The output of U3C connects to J6, pin 7,
which supplies a reflected-power level
output to the front panel meter.
4.1.9.4 Voltages for Circuit Operation
The ±12 VDC is applied to the board at
J5. The +12 VDC is connected to J5, pin
3, and is isolated and filtered by L4 and
C34 before it is connected to the rest of
the board. The +12 VDC also connects to
U5, a 5-VDC regulator that provides the
voltage needed to operate U4. The -12
VDC is applied to J5, pin 1, and is
isolated and filtered by L5 and C35
before it is connected to the rest of the
board.
4.1.10 (A4-A14) Channel Oscillator
Assembly, Dual Oven (1145-1202;
Appendix D)
The channel oscillator assembly contains
the channel oscillator board (1145-1201)
that generates a stable frequency-
reference signal of approximately 100
MHz. The channel oscillator assembly is
an enclosure that provides temperature
stability for the crystal oscillator. An SMA
output at jack J1 and an RF sample at
BNC connector jack J2 are also part of
the assembly.
Adjustments can be made through access
holes in the top cover of the assembly.
These adjustments are set at the factory
and should not be tampered with unless
it is absolutely necessary and the proper,
calibrated equipment is available. R1 is
the temperature adjustment; C11 is the
course-frequency adjustment; C9 is the
fine-frequency adjustment; and C6, C18,
L2, and L4 are adjusted for the maximum
output of the frequency as measured at
jack J1.
The +12 VDC for the assembly enters
through FL1 and the circuit-ground
connection is made at E1.
4.1.11 (Optional) (A4-A13) EEPROM
FSK Identifier Board (1265-1308;
Appendix D)
The (Optional) FSK identifier board, with
EEPROM, generates a morse code
identification call sign by sending a bias
voltage to the IF attenuator board to
amplitude modulate the aural carrier.
This gives the station a means of
automatically repeating its identification
call sign, at a given time interval, to
meet FCC requirements.
The starting circuit is made up of U1B
and U1D, which are connected as a
flip-flop, with gate U1A used as the set
flip-flop. U1A automatically starts the
flip-flop each time U3 completes its
timing cycle. At the start of a cycle, U1B
enables clock U2. U2 applies the clock
pulses that set the speed, which is
adjusted by R2, for when the
identification code is sent to 12-bit binary
counter U4. R2, fully clockwise (CW), is
the fastest pulse train and R2, fully
counter-clockwise (CCW), is the slowest
pulse train. U4 provides binary outputs
that address EEPROM U5.