Motorola ASTRO MT 1500, Руководство по обслуживанию, Страница: 106 / 817

August 16, 2007 6816985H01-B
4.3-4 UHF2 Detailed Theories of Operation: Transmitter
4.3.4.2 Back End
In the ABACUS IC (U401) , the first IF frequency is amplified and then down-converted to the second
IF frequency (2.25 MHz). At this point, the analog signal is converted into two digital bit streams by a
sigma-delta A/D converter. The bit streams are then digitally filtered, mixed down to baseband, and
filtered again. The output data stream is then sent to the Patriot IC, where it is decoded to produce
the recovered audio.
The ABACUS IC (U401) is electronically programmable. The amount of filtering, which is dependent
on the radio channel spacing and signal type, is controlled by the microcomputer. Additional filtering,
which used to be provided externally by a conventional ceramic filter, is replaced by internal digital
filters in the ABACUS IC.
The ABACUS IC contains a feedback Automatic Gain Control (AGC) circuit to expand the dynamic
range of the sigma-delta converter. The differential output data contains the quadrature (I and Q)
information in 16-bit words, the AGC information in a 9-bit word, imbedded word sync information,
and fill bits. Two synthesizers are available on the chip for second LO and sampling clock (18 MHz)
generation.
The second LO/VCO is a Colpitts oscillator built around transistor Q401. Varactor diode (D402) in the
VCO is used to adjust the VCO frequency. The control signal for the varactor is derived from a loop
filter consisting of C440, R417, C441, R418, and C480. The sampling clock is derived from a
negative resistance generator (on the chip) available at CLKP, CLKN, and an external tank circuit
(L403, C423, and D401). The loop filter for the clock is realized by C448, R408, and C425.
4.3.5 Transmitter
The RF power amplifier (PA) consists of
• an RF driver ( U101 ) and
• a Silicon N-Channel MOSFET type transistor RF power amplifier ( Q101 ).
RF input drive level of approxi3dBm is supplied from the transmit VCO buffer. This input
drive level is applied to pin 16 (RFIN) of
U101 . The dc power is applied to pins 6, 7, and 14 of U101
and to the drain of Q101 via a filtered RAW_B+. Power control is achieved by varying the dc bias
(and thus the gain) at pin 1 of U101 and the gate of Q101 . The amplified RF signal leaves the RF
final PA ( Q101 ) at the drain and is applied to the discrete directional coupler via an impedance
match. The RF signal passes through the coupler, a discrete antenna switch, and a discrete
harmonic filter before finally reaching the antenna launch connector.
A portion of the forward RF power is sampled by the directional coupler, applied to the diode (D172)
for rectification, and the resulting dc signal is fed back to pin 1 of the Power Control IC (PCIC, U102).
This dc signal is representative of the forward RF power being passed through the directional
coupler. The dc signal is used by the PCIC to regulate the transmitted RF power level.
The PCIC is the heart of the power control loop. The rectified feedback is internally compared to an
internal Digital-to-Analog Converter (DAC) output voltage in the PCIC to determine the amount of DC
bias voltage at pin 4. This voltage at pin 4 of the PCIC controls the gain (and thus the output power,
as explained above) of the RF driver (
U101 ) and the RF power amplifier ( Q101 ) via a fixed resistor
divider network.
U103 senses the temperature of the printed circuit board (PCB) near the RF Power Amplifier ( Q101 )
and provides a dc level representative of this temperature to pin 30 of the PCIC. The PCIC uses this
input to cut back the output power level after a certain temperature threshold is reached. This
ensures (1) radio integrity while transmitting in extreme ambient conditions hotter than the radio’s
operating temperature range and (2) acts as a safety feature to prevent any thermal runaway fault
conditions.