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Motorola Pr400 Detailed 6881096c25 B Manual

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    Page 151

    Page 151 6881096C25-BJune, 2005 438-470 MHz UHF Theory Of Operation: Keypad 9-7 C267, and varactor D261. High-port audio modulation from the synthesizer IC is applied as VCO_MOD to varactor D262 which modulates the transmit VCO. Figure 9-5. UHF VCO Block Diagram 9.5 Keypad The keypad block diagram is shown in Figure 9-6. Pressing a key creates two distinct voltages KEYPAD_ROW and KEYPAD_COL. These voltages are sent directly to the radio’s microprocessor on the main board. The microprocessor then interprets... 
    6881096C25-BJune, 2005
438-470 MHz UHF Theory Of Operation: Keypad 9-7
C267, and varactor D261. High-port audio modulation from the synthesizer IC is applied as 
VCO_MOD to varactor D262 which modulates the transmit VCO.
Figure 9-5.  UHF VCO Block Diagram
9.5 Keypad
The keypad block diagram is shown in Figure 9-6. Pressing a key creates two distinct voltages 
KEYPAD_ROW and KEYPAD_COL. These voltages are sent directly to the radio’s microprocessor 
on the main board. The microprocessor then interprets...

    Page 152

    Page 152 June, 20056881096C25-B Notes: 9-8438-470 MHz UHF Theory Of Operation: Keypad 
    June, 20056881096C25-B
Notes:
9-8438-470 MHz UHF Theory Of Operation: Keypad

    Page 153

    Page 153 Chapter 10 465-495 MHz UHF Theory Of Operation 10.1 Introduction This chapter provides a detailed theory of operation for the radio components. Schematic diagrams for the circuits described in the following paragraphs are located in Chapter 12 of this manual. 10.2 UHF Receiver The UHF receiver covers the range of 465-495 MHz and provides switchable IF bandwidth for use with 20/25/30 kHz or 12.5 kHz channel spacing systems. The receiver is divided into two major blocks, as shown in Figure 10-1. • Front... 
    Chapter 10 465-495 MHz UHF Theory Of Operation
10.1 Introduction
This chapter provides a detailed theory of operation for the radio components. Schematic diagrams 
for the circuits described in the following paragraphs are located in Chapter 12 of this manual.
10.2 UHF Receiver
The UHF receiver covers the range of 465-495 MHz and provides switchable IF bandwidth for use 
with 20/25/30 kHz or 12.5 kHz channel spacing systems. The receiver is divided into two major 
blocks, as shown in Figure 10-1.
• Front...

    Page 154

    Page 154 June, 20056881096C25-B 10-2465-495 MHz UHF Theory Of Operation: UHF Receiver The output of the RF amplifier is applied to the interstage filter, a fixed-tuned 4-pole Butterworth shunt-coupled resonator design having a 3 dB bandwidth of 68 MHz centered at 480 MHz, and insertion loss of 3.3 dB. This filter yields an image rejection of 55 dB at 405.3 MHz, assisted by a transmission-zero at 300 MHz implemented by C524 for the reasons mentioned above. The output of the interstage filter is connected to the... 
    June, 20056881096C25-B
10-2465-495 MHz UHF Theory Of Operation: UHF Receiver
The output of the RF amplifier is applied to the interstage filter, a fixed-tuned 4-pole Butterworth 
shunt-coupled resonator design having a 3 dB bandwidth of 68 MHz centered at 480 MHz, and 
insertion loss of 3.3 dB. This filter yields an image rejection of 55 dB at 405.3 MHz, assisted by a 
transmission-zero at 300 MHz implemented by C524 for the reasons mentioned above.
The output of the interstage filter is connected to the...

    Page 155

    Page 155 6881096C25-BJune, 2005 465-495 MHz UHF Theory Of Operation: UHF Transmitter 10-3 10.3 UHF Transmitter The UHF transmitter covers the range of 465-495 MHz. Depending on model, the output power of the transmitter is either switchable on a per-channel basis between high power (4 watts) and low power (1 watt), or is factory preset to 2 watts. The transmitter is divided into four major blocks as shown in Figure 10-2. • Power Amplifier • Harmonic Filter • Antenna Matching Network • Power Control. Figure... 
    6881096C25-BJune, 2005
465-495 MHz UHF Theory Of Operation: UHF Transmitter 10-3
10.3 UHF Transmitter
The UHF transmitter covers the range of 465-495 MHz. Depending on model, the output power of the 
transmitter is either switchable on a per-channel basis between high power (4 watts) and low power 
(1 watt), or is factory preset to 2 watts. The transmitter is divided into four major blocks as shown in 
Figure 10-2.
• Power Amplifier
• Harmonic Filter 
• Antenna Matching Network
• Power Control.
Figure...

    Page 156

    Page 156 June, 20056881096C25-B 10-4465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry 10.3.4 Antenna Matching Network The harmonic filter presents a 50Ω impedance to antenna jack J140. A matching network, made up of C140-C141 and L140, is used to match the antenna impedance to the harmonic filter. This optimizes the performance of the transmitter and receiver into the impedance presented by the antenna, significantly improving the antennas efficiency. 10.3.5 Power Control The power... 
    June, 20056881096C25-B
10-4465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry
10.3.4 Antenna Matching Network
The harmonic filter presents a 50Ω impedance to antenna jack J140. A matching network, made up of 
C140-C141 and L140, is used to match the antenna impedance to the harmonic filter. This optimizes 
the performance of the transmitter and receiver into the impedance presented by the antenna, 
significantly improving the antennas efficiency.
10.3.5 Power Control
The power...

    Page 157

    Page 157 6881096C25-BJune, 2005 465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry 10-5 SPI_CLK, and SYNTH_CS (chip select) lines (U409 pins 100, 1 and 47 respectively). A logic high (3 V) from U201 pin 4 indicates to the microprocessor that the synthesizer is locked. Figure 10-3. UHF Frequency Generation Unit Block Diagram Transmit modulation from the ASFICcmp (U451 pin 40) is applied to U201 pin 10 (MOD_IN). An electronic attenuator in the ASFICcmp adjusts overall transmitter deviation... 
    6881096C25-BJune, 2005
465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry 10-5
SPI_CLK, and SYNTH_CS (chip select) lines (U409 pins 100, 1 and 47 respectively). A logic high 
(3 V) from U201 pin 4 indicates to the microprocessor that the synthesizer is locked.
Figure 10-3.  UHF Frequency Generation Unit Block Diagram
Transmit modulation from the ASFICcmp (U451 pin 40) is applied to U201 pin 10 (MOD_IN). An 
electronic attenuator in the ASFICcmp adjusts overall transmitter deviation...

    Page 158

    Page 158 June, 20056881096C25-B 10-6465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry One of the auxiliary outputs of the synthesizer IC (AUX3, U201 pin 2) provides the TRB signal which determines the operating mode of the VCO, either receive or transmit. Figure 10-4. UHF Synthesizer Block Diagram 10.4.2 Voltage Controlled Oscillator (VCO) The VCOBIC (U251), shown in Figure 10-5, in conjunction with the Fractional-N synthesizer (U201) generates RF in both the receive and the transmit... 
    June, 20056881096C25-B
10-6465-495 MHz UHF Theory Of Operation: UHF Frequency Generation Circuitry
One of the auxiliary outputs of the synthesizer IC (AUX3, U201 pin 2) provides the TRB signal which 
determines the operating mode of the VCO, either receive or transmit.
Figure 10-4.  UHF Synthesizer Block Diagram
10.4.2 Voltage Controlled Oscillator (VCO)
The VCOBIC (U251), shown in Figure 10-5, in conjunction with the Fractional-N synthesizer (U201) 
generates RF in both the receive and the transmit...

    Page 159

    Page 159 6881096C25-BJune, 2005 465-495 MHz UHF Theory Of Operation: Keypad 10-7 C267, and varactor D261. High-port audio modulation from the synthesizer IC is applied as VCO_MOD to varactor D262 which modulates the transmit VCO. Figure 10-5. UHF VCO Block Diagram 10.5 Keypad The keypad block diagram is shown in Figure 10-6. Pressing a key creates two distinct voltages KEYPAD_ROW and KEYPAD_COL. These voltages are sent directly to the radio’s microprocessor on the main board. The microprocessor then... 
    6881096C25-BJune, 2005
465-495 MHz UHF Theory Of Operation: Keypad 10-7
C267, and varactor D261. High-port audio modulation from the synthesizer IC is applied as 
VCO_MOD to varactor D262 which modulates the transmit VCO.
Figure 10-5.  UHF VCO Block Diagram
10.5 Keypad
The keypad block diagram is shown in Figure 10-6. Pressing a key creates two distinct voltages 
KEYPAD_ROW and KEYPAD_COL. These voltages are sent directly to the radio’s microprocessor 
on the main board. The microprocessor then...

    Page 160

    Page 160 June, 20056881096C25-B Notes: 10-8465-495 MHz UHF Theory Of Operation: Keypad 
    June, 20056881096C25-B
Notes:
10-8465-495 MHz UHF Theory Of Operation: Keypad
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