Tait TEL0060 Base Station Transmitter User Manual 8c500 bk

Tait Limited Base Station Transmitter 8c500 bk

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CI
M800 SL2
Part C
T854 Transmitter
This part of the manual is divided into six sections, as listed below. There is a detailed
table of contents at the start of each section.
Section
Title
General Information
Circuit Operation
Initial Tuning & Adjustment
Functional Testing
Fault Finding
PCB Information
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CII
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M800 SL2
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T854 General Information
M800 SL2
C1.1
T854 General Information
This section provides a brief description of the T854 transmitter, along with detailed
specifications and a list of types available.
The following topics are covered in this section.
Section
Title
Page
1.1
Introduction
1.7
1.2
Specifications
1.8
1.2.1
Introduction
1.8
1.2.2
General
1.8
1.2.3
RF Section
1.9
1.2.4
1.2.4.1
1.2.4.2
1.2.4.3
Audio Processor
Inputs
Modulation Characteristics
CTCSS
1.10
1.10
1.11
1.11
1.2.5
Microcontroller
1.11
1.2.6
1.2.6.1
1.2.6.2
1.2.6.3
Test Standards
European Telecommunication Standard
DTI CEPT Recommendation T/R-24-01
Telecommunications Industry Association
1.12
1.12
1.12
1.12
1.3
Product Codes
1.13
1.4
T854 Standard Product Range
1.14
Figure
Title
Page
1.1
T854 Main Circuit Block Identification
1.4
1.2
T854 Front Panel Controls
1.4
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C1.2
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T854 General Information
M800 SL2
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M800 SL2
T854 General Information
C1.3
Figure 1.1 T854 Main Circuit Block Identification
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C1.4
T854 General Information
M800 SL2
Figure 1.2 T854 Front Panel Controls
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T854 General Information
M800 SL2
1.1
C1.5
Introduction
The T854 is a synthesised, microprocessor controlled FM base station transmitter
designed for single or multichannel operation in the 400 to 520MHz frequency range1
with a standard power output of 25W. The RF section of the transmitter comprises a frequency synthesiser which provides 100mW of frequency modulated RF drive to a two
stage, wide band output driver followed by a 25W power supply. A thermal shutdown
feature is provided in the T854 in case operating temperatures exceed acceptable levels.
The T854 is rated for continuous operation.
The T854 is rated for a continuous output power of 25W at +60°C. This is achieved via a
high capacity heatsink, electric fan and shroud. The fan draws air across the heatsink to
dissipate the heat. The heatsink replaces one of the usual T800 covers.
A wide selection of audio characteristics may be obtained from the audio processor.
Optional circuit blocks are an audio compressor and a pre-emphasis stage. They can be
bypassed or linked to one or both audio inputs, and then back into the remaining audio
circuitry in almost any combination. All audio processor options are link selectable.
The synthesiser frequency is programmed via the serial communications port. Eight
channel select lines are accessible via an optional D-range connector (D-range 2 T800-03-0000) at the rear of the set.
All components except those of the VCO are mounted on a single PCB. This is secured
to a die-cast chassis which is divided into compartments to individually shield each section of circuitry. Access to the PCB is primarily through the top cover of the radio, as all
components are mounted on the top side of the PCB. There is provision within the chassis to mount small option PCBs.
The front panel controls include line sensitivity, microphone socket and carrier switch.
This switch turns on the carrier (unmodulated) as an aid to servicing.
The T854 is designed to be part of the slimline frame.
1. Although capable of operating over the 400-520MHz frequency range, the T854 and
T857 have an 8MHz switching range (see Section 1.2.3 and Section 3.1).
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C1.6
T854 General Information
1.2
Specifications
1.2.1
Introduction
M800 SL2
The performance figures given are minimum figures, unless otherwise indicated, for
equipment tuned with the maximum switching range and operating at standard room
temperature (+22°C to +28°C) and standard test voltage (13.8V DC).
Where applicable, the test methods used to obtain the following performance figures
are those described in the EIA and ETS specifications. However, there are several
parameters for which performance according to the CEPT specification is given. Refer
to Section 1.2.6 for details of test standards.
Details of test methods and the conditions which apply for Type Approval testing in all
countries can be obtained from Tait Electronics Ltd.
The terms "wide bandwidth", "mid bandwidth" and "narrow bandwidth" used in this
and following sections are defined in the following table.
Channel Spacing
Modulation
100% Deviation
Receiver
IF Bandwidth
Wide Bandwidth
25kHz
±5.0kHz
15.0kHz
Mid Bandwidth
20kHz
±4.0kHz
12.0kHz
12.5kHz
±2.5kHz
7.5kHz
Narrow Bandwidth
1.2.2
General
Number Of Channels
.. 128 (standard)1
Supply Voltage:
Operating Voltage
Standard Test Voltage
Polarity
Polarity Protection
Line Keying Supply (if required)
..
..
..
..
..
10.8 to 16V DC
13.8V DC
negative earth only
crowbar diode
-50V DC
Supply Current:
Transmit
Standby
- T854
- T854
Operating Temperature Range
.. 5.5A (typical)
.. 165mA (typical)
.. -20°C to +60°C
1. Additional channels may be factory programmed. Contact your nearest Tait Dealer or
Customer Service Organisation.
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T854 General Information
M800 SL2
C1.7
Overall Dimensions:
Height
Width
Depth
.. 132mm
.. 480mm
.. 335mm
Weight with Tone Remote
Weight without Tone Remote
.. 16kg
.. 13kg
Time-Out Timer (optional)
.. 0 to 5 minutes1 adjustable in 10 second steps
Tail Timer
.. 0 to 5 seconds adjustable in 100ms2
steps
Transmit Key Time
.. <30ms
Transmit Lockout Timer
.. 0 to 1 minute adjustable in 10 second
steps
1.2.3
RF Section
Frequency Range
.. 400-520MHz (refer to Section 1.4 and
Section 1.5)
Modulation Type
.. FM
Frequency Increment
.. 5 or 6.25kHz
Switching Range
.. 8MHz (i.e. ±4MHz from the centre
frequency)
Load Impedance
.. 50 ohms
Frequency Stability
(see also Section 1.4 and Section 1.5)
.. ±1ppm, -20°C to +60°C
Adjacent Channel Power (full deviation):
Wide Bandwidth (WB)
(±25kHz/15kHz B/W)
.. -75dBc
Mid Bandwidth (MB)
(±20kHz/12kHz B/W)
.. -70dBc
Narrow Bandwidth (NB)
(±12.5kHz/7.5kHz B/W)
.. -65dBc
Transmitter Switching
.. complies with ETS 300 113
1. Adjustable from 0 to 10 minutes in PGM800Win version 2.12 and later.
2. Adjustable in 20ms steps in PGM800Win version 2.12 and later.
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C1.8
T854 General Information
M800 SL2
Transmitter Side Band Noise:
(no modulation, 15kHz bandwidth)
At ±25kHz
At ±1MHz
Intermodulation
.. -95dBc
.. -105dBc
.. -40dBc with interfering signal of
-30dBc
.. -70dBc with 25dB isolation
& interfering signal of -30dBc
(PA with output isolator)
T854 Mismatch Capability:
Ruggedness
Stability
.. refer to your nearest Tait Dealer or
Customer Service Organisation
.. 3:1 VSWR (all phase angles)
Radiated Spurious Emissions:
Transmit
Standby
.. -36dBm to 1GHz
-30dBm 1GHz to 4GHz
.. -57dBm to 1GHz
-47dBm 1GHz to 4GHz
Conducted Spurious Emissions: (T854 Only)
Transmit
Standby
.. -36dBm to 1GHz
-30dBm 1GHz to 4GHz
.. -57dBm to 1GHz
-47dBm 1GHz to 4GHz
Power Output:
T854
- Rated Power
- Range Of Adjustment
Duty Cycle ..
1.2.4
Audio Processor
1.2.4.1
Inputs
Inputs Available
.. 25W (see Duty Cycle)
.. 5-25W
100% @ 25W at +60°C
.. line, microphone and CTCSS
Line Input:
Impedance
Sensitivity (60% modulation @ 1kHz)With Compressor
Without Compressor
.. 600 ohms (balanced)
.. -50dBm
.. -30dBm
Microphone Input:
Impedance
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.. 600 ohms
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T854 General Information
M800 SL2
Sensitivity (60% modulation @ 1kHz)With Compressor
Without Compressor
1.2.4.2
C1.9
.. -70dBm
.. -50dBm
Modulation Characteristics
Frequency Response
(below limiting)
.. flat or pre-emphasised (optional)
Line And Microphone Inputs:
Pre-emphasised ResponseBandwidth
Below Limiting
Flat Response
.. 300Hz to 3kHz (WB & MB)
.. 300Hz to 2.55kHz (NB)
.. within +1, -3dB of a 6dB/octave
pre-emphasis characteristic
.. within +1, -2dB of output at 1kHz
Above Limiting Response
.. within +1, -2dB of a flat response
(ref. 1kHz)
Distortion
.. 2% max.
Hum And Noise:
Wide Bandwidth
Mid Bandwidth
Narrow Bandwidth
.. -55dB (300Hz to 3kHz [EIA]) typical
.. -54dB (CEPT)
.. -50dB (CEPT)
Compressor (optional):
Attack Time
Decay Time
Range
1.2.4.3
.. 10ms
.. 800ms
.. 50dB
CTCSS
Standard Tones
.. all 37 EIA group A, B and C tones
plus 13 commonly used tones
Frequency Error
(from EIA tones)
.. 0.08% max.
Generated Tone Distortion
.. 1.2% max.
Generated Tone Flatness
.. flat across 67 to 250.3Hz to within 1dB
Modulation Level
.. adjustable
Modulated Distortion
.. <5%
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T854 General Information
1.2.5
Microcontroller
M800 SL2
Auxiliary Ports:
Open Drain Type
Vds max.
1.2.6
.. capable of sinking 2.25mA via 2k2Ω
.. 5V
Test Standards
Where applicable, this equipment is tested in accordance with the following standards.
1.2.6.1
European Telecommunication Standard
ETS 300 086 January 1991
Radio equipment and systems; land mobile service; technical characteristics and test
conditions for radio equipment with an internal or external RF connector intended primarily for analogue speech.
ETS 300 113 March 1996
Radio equipment and systems; land mobile service; technical characteristics and test
conditions for radio equipment intended for the transmission of data (and speech) and
having an antenna connector.
ETS 300 219 October 1993
Radio equipment and systems; land mobile service; technical characteristics and test
conditions for radio equipment transmitting signals to initiate a specific response in the
receiver.
ETS 300 279 February 1996
Radio equipment and systems; electromagnetic compatibility (EMC) standard for private land mobile radio (PMR) and ancillary equipment (speech and/or non-speech).
1.2.6.2
DTI CEPT Recommendation T/R-24-01
Annex I: 1988
Technical characteristics and test conditions for radio equipment in the land mobile
service intended primarily for analogue speech.
Annex II: 1988
Technical characteristics of radio equipment in the land mobile service with regard to
quality and stability of transmission.
1.2.6.3
Telecommunications Industry Association
ANSI/TIA/EIA-603-1992
Land mobile FM or PM communications equipment measurement and performance
standards.
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T854 General Information
M800 SL2
1.3
C1.11
Product Codes
The three groups of digits in the T850 Series II product code provide information about
the model, type and options fitted, according to the conventions described below. Consult your nearest Tait Dealer or Customer Service Organisation for more information
regarding the availability of specific models, types and options.
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T854 General Information
1.4
T854 Standard Product Range
M800 SL2
The following table lists the range of standard T854 types (i.e. no options fitted) available at the time this manual was published. Consult your nearest Tait Dealer or Customer Service Organisation for more information.
Frequency Range (MHz)
Deviation (kHz)
TCXO
±1ppm -20°C to +60°C
Transmitter Type: T854-
400-440
2.5
2.5
•
•
•
•
16-0000a
15-0000
13-0000
10-0000
Frequency Range (MHz)
Deviation (kHz)
TCXO
±1ppm -20°C to +60°C
Transmitter Type: T854-
440-480
2.5
2.5
•
•
•
•
26-0000a
25-0000
23-0000
20-0000
Frequency Range (MHz)
Deviation
TXCO
±1ppm -20° to +60°C
Transmitter Type: T854-
480-520
2.5
2.5
•
•
•
36-0000a
35-0000
30-0000
a. United States market only.
Caution:
T854-1X-XXXX Product Types
The 406 to 406.1MHz frequency range is reserved worldwide for use by
Distress Beacons. Do not program transmitters to operate in this frequency range.
You can identify the transmitter type by checking the product code printed on a label on
the rear of the chassis (Figure 1.1 in Part A shows typical labels). You can further verify
the transmitter type by checking the placement of an SMD resistor in the table that is
screen printed onto the PCB (refer to Section 6.1 for more details).
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T854 General Information
M800 SL2
T800 SL BSM Conventional Ordering Number System
System
Type
Frequency
Band
RF Output
Power
Channel
Spacing
Coaxial
Relay /
Duplexer
Power
Supply
3/13/02
Ancillary
Options
L A 1 W B 0 0
L = T800 SL BSM
(T800-56-X0XX)
A = 66 - 88 MHz
(T82x-xx-02xx)
B = 136 - 156 MHz
(T83x-1x-02xx)
C = 148 - 174 MHz
(T83x-2x-02xx)
D = 400 - 440 MHz
(T85x-1x-02xx)
E = 440 - 480 MHz
(T85x-2x-02xx)
F = 480 - 560 MHz
(T85x-3x-02xx)
P = 800 - 870 MHz
(T88x-1x-02xx)
* Q = 860 - 910 MHz (T88x-2x-02xx)
R = 890 - 960 MHz
(T88x-3x-02xx)
* = Not Available for US Market
1 = 25 Watts
4 = 5 Watts
*5 = 25 Watts (Cont)
* Only Available in Frequency
Bands
400-560Mhz
Copyright TEL
0=
4=
6=
7=
8=
9=
0 = No Duplexer Fitted
1 = 50 Watt Duplexer Kit
2 = Coaxial Relay Kit
No Ancillary Option
Multi-Channel Option (10 CH)
Cabinet Desktop 3U (Blk)
Cabinet Desktop 4U (Blk)
Cabinet Transportable 6U (Blk)
Tone Remote Module
C1.13
(T992-03-0002)
(T992-04-0002)
(T992-06-0002)
(T803-00-0000)
(T991-09-0001)+(T993-XX)
(T800-09-0002)
If Duplexer item code is set to (1), then Base/Repeater/
Slimline Requirement sheet must be completed. This is
required so correct Duplexer Frequency and Spacing can be
calculated.
T991-09-0001 is a 1U 19" Tray for Duplexer fitting.
B = BSM Kit with Power Supply
D = BSM Kit with External DC
N = 12.5 kHz
M = 20 kHz
W = 25 kHz
(T800-56-X0X2)
(T800-56-X0X4)
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C1.14
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T854 General Information
M800 SL2
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M800 SL2
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T854 General Information
C1.15
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C1.16
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T854 General Information
M800 SL2
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T854 Circuit Operation
M800 SL2
C2.1
T854 Circuit Operation
This section provides a basic description of the circuit operation of the T854 transmitter.
Unless otherwise specified, the term "PGM800Win" used in this and following sections refers to version 3.00 and later of the software.
Note:
Refer to Section 6 where the parts lists, grid reference index and diagrams will provide
detailed information on identifying and locating components and test points on the
main PCB. The parts list and diagrams for the VCO PCB are in Part E.
The following topics are covered in this section.
Section
Title
Page
2.1
Introduction
2.3
2.2
Microcontroller
2.4
2.3
Synthesised Local Oscillator
2.5
Two Point Modulation
2.6
VCO
2.7
VCO Supply
2.7
Audio Processor
2.8
2.5.1
General
2.8
2.5.2
Audio Inputs
2.8
2.5.3
Keying Inputs
2.9
2.5.4
Compressor (Automatic Level Control (ALC))
2.9
2.5.5
Outputs To Modulators
2.9
2.6
Power Supply & Regulator Circuits
2.10
2.7
Transmit Timers
2.11
2.8
T854 Drive Amplifier & PA
2.12
2.3.1
2.4
2.4.1
2.5
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C2.2
T854 Circuit Operation
Figure
M800 SL2
Title
Page
2.1
T854 High Level Block Diagram
2.3
2.3
T854 Microcontroller Block Diagram
2.4
2.4
T854 Synthesiser Block Diagram
2.5
2.5
T854 Two Point Modulation
2.6
2.6
T854 Audio Processor Block Diagram
2.8
2.7
T854 Power Supply & Regulators Block Diagram
2.10
2.8
T854 Transmit Timers
2.11
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T854 Circuit Operation
M800 SL2
2.1
C2.3
Introduction
The individual circuit blocks which make up the T854 are:
• synthesiser
• VCO
• audio processor
• drive amplifier
• voltage regulators.
Each of these circuit blocks is set in its own shielded compartment, formed as an integral part of the main chassis.
The configuration of the circuit blocks may be seen on a functional level in Figure 2.1 .
Refer to the circuit diagrams in Section 6.2 for more detail.
PIN
Switch
Reference
Oscillator
12.8MHz
Synthesiser
Drive
Amp.
+22dBm
Exciter
Output
(+30dBm to
+33dBm)
PA
Directional Low Pass
Coupler
Filter
Transmitter
Output
(25W)
Lock
Detect
Microphone
Power
Control
Audio
Processor
Line
Time
Delay
Transformer
Gate
Time
Delay
Ramp
Gen.
Time
Delay
VCO
Tx Reg
Figure 2.1 T854 High Level Block Diagram
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C2.4
T854 Circuit Operation
2.2
Microcontroller
M800 SL2
(Refer to the microcontroller circuit diagram (sheet 8) in Section 6.2 or 6.3.)
Watchdog
Reset
5V Digital
Regulator
5V
Reset
Microcontroller Cavity
Channel
Select
Port
12.8MHz
Clock
External
Serial
Port
CTCSS Tone
Microcontroller
Auxiliary
Output
Port
Dual Digital
Potentiometer
Converter
CTCSS
Encoder
EEPROM
Synthesiser
Figure 2.2 T854 Microcontroller Block Diagram
Overall system control of the T854 is accomplished by the use of a member of the 80C51
family of microcontrollers (IC810). It runs from internal ROM and RAM, thus leaving
all four ports free for input/output functions.
Non-volatile data storage is achieved by serial communication with a 16kBit EEPROM
(IC820). This serial bus is also used by the microcontroller to program the synthesiser
(IC740) and deviation control EPOTS (IC220).
The main tasks of the microcontroller are as follows:
• program the synthesiser and EPOT;
• interface with the PGM800Win programming software at 9600 baud via the
serial communication lines on D-range 1 (PL100) & D-range 2;
• monitor channel change inputs from D-range 2;
• generate timing waveforms for CTCSS encoding;
• coordinate and implement timing control of the exciter/transmitter.
• control the front panel "Supply" LED (refer to Section 5.3).
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T854 Circuit Operation
M800 SL2
2.3
C2.5
Synthesised Local Oscillator
(Refer to the synthesiser circuit diagram (sheet 7) in Section 6.2 or 6.3 and the VCO circuit diagram in Part E.)
VCO
Modulation
FREQUENCY SYNTHESISER IC
12.8MHz
Reference
Oscillator
Fixed
Divider
Reference
Divider
/64
Phase
Detector
Charge
Pump
Loop
Filter
VCO
Serial
Bus
Phase
Modulator
Clk
Data
En
Buffer
Σ
/R
fref
Ref
Mod
VCO PCB
Programmable
Divider
Prescaler
/N
64/65
Output
Buffer
+22dBm
L.O.
f in
Divider Buffer
Controller
Figure 2.3 T854 Synthesiser Block Diagram
The synthesiser (IC740) employs a phase-locked loop (PLL) to lock a voltage controlled
oscillator (VCO) to a given reference frequency. The synthesiser receives the divider
information from the control microprocessor via a 3 wire serial bus (clock, data, enable).
When the data has been latched in, the synthesiser processes the incoming signals from
the VCO buffer (fin) and the phase modulator (fref).
A reference oscillator at 12.8MHz (=IC700) is buffered (IC710 pins 3 & 4) and divided
down to 200kHz (IC730). This 200kHz square wave is then summed with the modulating audio and passed to an integrator (IC720 pins 9 & 8, Q710, Q720). This produces a
ramping waveform which is centred around a DC level determined by the incoming
audio. IC720 pins 5 & 6 perform as a comparator, ultimately producing a phase-modulated 200kHz square wave. This is followed by another phase shifting stage (IC720 pins
3 & 4, Q730, Q740), before being divided down to 6.25kHz or 5kHz within the synthesiser IC (IC740).
A buffered output of the VCO (Q795) is divided with a prescaler and programmable
divider which is incorporated into the synthesiser chip (IC740). This signal is compared
with the phase modulated reference signal at the phase detector (also part of the synthesiser chip). The phase detector outputs drive a balanced charge pump circuit (Q760,
Q770, Q775, Q780, Q785) and active loop filter (IC750 pins 5, 6 & 7, Q790) which produces a DC voltage between 0V and 20V to tune the VCO. This VCO control line is further filtered to attenuate noise and other spurious signals. Note that the VCO frequency
increases with increasing control voltage.
If the synthesiser loop loses lock, a pulsed signal appears at LD (pin 2) of IC740. This
signal is filtered and buffered by IC750 pins 1, 2 & 3, producing the Lock-Detect signal
used to shut off the power supply to the drive amplifier. IC750 pin 1 is at 20V when the
synthesiser is out of lock.
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C2.6
T854 Circuit Operation
2.3.1
Two Point Modulation
M800 SL2
Frequency modulation occurs by modulating both the VCO input and the synthesiser
reference input. This process is called two point modulation and ensures a flat modulation response from 67Hz to 3kHz (2.55kHz for narrow bandwidth).
The PLL has a fast response time, allowing a Tx key-up time of <30ms. Because of this
fast response time the PLL sees lower modulation frequencies superimposed on the
VCO as an error and corrects for it, resulting in no modulation on the carrier. At modulation frequencies greater than 300Hz the loop cannot correct fast enough and modulation is seen on the carrier. The response of the loop to VCO modulation is shown by f2
in Figure 2.4 below.
To achieve low frequency modulation, the reference oscillator is also modulated so that
the phase detector of IC740 detects no frequency error under modulation. Thus, the
synthesiser loop will not attempt to correct for modulation and the audio frequency
response of the transmitter remains unaffected. The response of the loop to reference
frequency modulation is shown by f1 in Figure 2.4.
The reference modulation is controlled by a 256-step 10k electronic potentiometer
(EPOT) which is adjustable via PGM800Win. The EPOT is made up of 256 resistive sections (representing approximately 39Ω each) which can be individually addressed by
the microcontroller. Each section can be switched in or out of circuit to achieve the
required total resistance, thus giving control of the reference modulation.
f1
f2
TCXO
VCO
Deviation
Frequency
Figure 2.4 T854 Two Point Modulation
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T854 Circuit Operation
M800 SL2
2.4
C2.7
VCO
(Refer to the VCO circuit diagram in Part E.)
The VCO transistor (Q1) operates in a common emitter configuration, with an LC tank
circuit coupled between its gate and drain to provide the feedback necessary for oscillation. The VCO control voltage from the loop filter (IC750) is applied to the varicaps
(D1-D2) to facilitate tuning within an 8MHz band of frequencies. A trimcap (C6) is used
for coarse tuning of the VCO. The output from the oscillator circuit drives a cascode
amplifier stage (Q2, Q3) which supplies +10dBm (typically) to a further stage of amplification, Q5. This is the final amplifier on the VCO PCB, and delivers +20dBm (typically)
to the exciter drive amplifier.
A low level "sniff" is taken from the input to Q5 and used to drive the divider buffer for
the synthesiser (IC740).
The VCO operates at the actual output frequency of the exciter, i.e. there are no multiplier stages. It is modulated by superimposing the audio signal onto the control voltage
and by phase modulating the reference signal.
2.4.1
VCO Supply
The VCO is supplied from two switched +9V supplies under the control of the Tx-Reg.
supply.
The VCO and buffer amplifier are supplied from one +9V switched supply by Q540 via
the C multiplier (Q550, C530 on the T854 and C550 on the T857).
The output amplifier is supplied from the other +9V supply by Q520, Q530, and Q510.
A delay circuit holds the VCO on for a short time after the Tx-Reg. supply has been
switched off. This is to allow the RF power circuits (both exciter and PA) to ramp down
in the correct manner before the VCO is switched off.
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C2.8
T854 Circuit Operation
2.5
Audio Processor
M800 SL2
(Refer to the audio processor circuit diagram (sheet 2) in Section 6.2 or 6.3.)
Carrier
Opto-coupler
Opto-Key
Tx Enable
Constant Current Sink
Tx Key
PTT
Link 4
PL205
mic.
Line Input
Compressor
Output
Inhibit
Inputs
Microphone
Input
Output
Microphone
Pre-amp.
line
Limiter
Set Deviation
Link 5
PL210
Digital Pot. (EPOT)
Σ
Preemphasis
Multiplexer
Audio 1
Link 3
PL215
Audio 2
Link 4
PL220
CTCSS
Low Pass
Filter
Ref. Mod. Adjust
Digital Pot. (EPOT)
Integrator
Buffer
Output
To VCO
Ref.
Mod.
Figure 2.5 T854 Audio Processor Block Diagram
2.5.1
General
The audio processor comprises several link selectable circuit blocks which may be configured in a variety of combinations to suit individual requirements. The pre-emphasis
network and compressor may be linked individually or cascaded between either or both
audio inputs and the limiter.
Refer to Section 3.5.1 for linking details.
2.5.2
Audio Inputs
Two audio inputs are available: one from a 600 ohm balanced (or unbalanced) line, and
the other from a local microphone. The microphone signal is passed first to a pre-amplifier (Q210) and ultimately to a multiplexer (IC240), but in between may pass through
the compressor (depending on the linking details). The line transformer is also connected to the multiplexer and is disabled by the microphone PTT switch.
A third input for external CTCSS tones is also provided.
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T854 Circuit Operation
M800 SL2
2.5.3
C2.9
Keying Inputs
There are four ways to key the exciter:
• pulling the Tx-Key line low (pin 13 on D-range 1 [PL100]) at the rear of the set);
• pushing the "Carrier" button on the front panel - this will inhibit all audio;
• using the PTT button on the local microphone, disabling audio from the line;
• via the opto-key inputs (pins 11 and 12 on D-range 1 [PL100]) when electrical
isolation is required. This features a constant current sink (Q270) to ensure reliable activation of the opto-coupler (IC250) at low keying voltages.
2.5.4
Compressor (Automatic Level Control (ALC))
The input signal is fed via a current controlled attenuator (Q230, Q220) to a high gain
stage (IC230) from which the output signal is taken. This signal is passed to a comparator (IC230) which toggles whenever the audio signal exceeds a DC threshold determined by RV220. Thus, the comparator produces a square wave whose mark-space
ratio is determined by the amplitude of the audio signal. This square wave pumps up
the reservoir capacitor (C233) which controls the attenuator (Q230, Q220), thus completing the feedback loop.
The compression level is set by adjustment of the comparator threshold (RV220).
Note:
Although the high dynamic range of the compressor allows the use of very
low audio signal levels, such conditions will be accompanied by a degradation of the signal-to-noise ratio. Very low audio input levels should therefore be avoided where possible.
2.5.5
Outputs To Modulators
The output signal from the limiter (IC210, IC230) is summed with a CTCSS tone at a
summing amplifier (IC260). The signal is then low pass filtered (IC260) and split to supply the two modulators.
Since the VCO modulator is a true frequency modulator, its audio is simply buffered
(IC260). The reference modulator, however, is a phase modulator and its audio must
first be integrated (IC210).
It is vital that the audio levels to the modulators are accurately set, relative to each
other. Hence the inclusion of level adjustment in the reference modulator path. Once
set, adjustments to absolute deviation may be made only by IC220, a 256-step 10k electronic potentiometer (EPOT), which is controlled via PGM800Win. The EPOT is made
up of 256 resistive sections (representing approximately 39Ω each) which can be individually addressed by the microcontroller. Each section can be switched in or out of circuit to achieve the required total resistance, thus adjusting the absolute deviation level.
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C2.10
T854 Circuit Operation
2.6
Power Supply & Regulator Circuits
M800 SL2
(Refer to the regulators circuit diagram (sheet 6) in Section 6.2 or 6.3.)
Figure 2.6 T854 Power Supply & Regulators Block Diagram
+9V
Buffer
Power
Switch
Microcontroller
Tx Enable
IC 370
Tx Reg.
9v Ex
9v Reg
Watchdog
Timer
13.8V Nom.
From Rear
D-Range
DC
Amp
5V
Reg
Crowbar
Diode
13.8V
Nom.
5V
5V Dig
Reg
Switching
PS
9V
20V
LVI
µP
µP
Reset
5V Dig
The T854 are designed to operate from a 10.8-16V DC supply (13.8V nominal). A 5.3V
regulator (IC630) runs directly from the 13.8V rail, driving much of the synthesiser circuitry. It is also used as the reference for a DC amplifier (IC640, Q630, Q620) which provides a medium current capability 9V supply. The T854 has a regulator (IC370) which
produces 9V for use in the exciter and audio circuits.
A switching power supply (Q660, Q670) runs from the 9V supply and provides a low
current capability +20V supply. This is used to drive the synthesiser loop filter (IC750),
giving a VCO control voltage range of up to 20V.
Ultimate control of the transmitter is via the Tx-Reg. supply, switched from 9V by Q610.
This is enabled via the Tx-Enable signal from the audio processor, and microprocessor.
A crowbar diode is fitted for protection against connection to a power supply of incorrect polarity. It also provides transient overvoltage protection.
Note:
01/03/02
A fuse must be fitted in the power supply line for the diode to provide effective protection.
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T854 Circuit Operation
M800 SL2
2.7
C2.11
Transmit Timers
The transmit tail timer, transmit timeout timer and transmit lockout timer can all be set
from PGM800Win. The fields for setting these are found on the system information
page. These three timers operate as follows (refer also to Figure 2.7):
Timer
Function
Adjustment
Transmit Tail
Sets the tail time during which the
transmitter stays keyed after the external key source has been removed.
0-5 seconds in 100ms
stepsa
Transmit Timeout
Sets the maximum continuous transmission time. Once the timer has
timed out, the transmitter must be
keyed again, unless prevented by the
transmit lockout timer.
0-300 secondsb in 10
second steps
Transmit Lockout
Sets the period of time that must
elapse after a timeout before the transmitter can re-transmit. Once the timer
has timed out, the transmitter can be
keyed again.
0-60 seconds in 10
second steps
a. Adjustable in 20ms steps in PGM800Win version 2.12 and later.
b. Adjustable from 0 to 600 seconds in PGM800Win version 2.12 and later.
Tx-Enable
On
Tx-Reg.
Tx-Enable
Tail Time
On
Tx-Reg.
Lockout Time
Timeout
Time
Figure 2.7 T854 Transmit Timers
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C2.12
T854 Circuit Operation
2.8
T854 Drive Amplifier & PA
M800 SL2
(Refer to Figure 2.1 and the exciter and PA circuit diagrams (sheets 3 & 4) in Section 6.2.)
The output power of the PA is maintained at a constant level via a power control loop
applied to the two-stage, wide band exciter amplifier (Q337, Q336). The forward and
reverse RF power levels are sensed via a dual directional coupler and detector diodes
(D440, D420 in the PA cavity). The detected DC signals are buffered (IC330 pins 3 & 5)
and then summed with the ’power control’ level and fed to the control integrator (IC350
pin 6).
Forward and reflected power signals are summed so that, under high
VSWR, the power control will turn the output RF level down.
Note:
To reduce the spurious output level when the synthesiser is out-of-lock, the Tx-Reg. and
Lock-Detect signals are gated to inhibit the PA control circuit and to switch off the RF
signal at the input to the drive amplifier. This is achieved by a PIN switch attenuator
(D340, D380, D360).
Cyclic keying control is provided by additional circuitry consisting of several time
delay, ramp and gate stages:
• Q330, IC350
power ramping
• Q326, Q325
Tx-Reg. and Lock-Detect gate
• Q335, Q340, Q345
delay and PIN switch drive.
This is to allow the RF power circuits (both exciter and PA) to ramp up and down in a
controlled manner so that minimal adjacent channel interference is generated during
the transition.
The output of the wide band amplifier is approximately 1W (+30dBm) for an input of
100mW (+20dBm) from the VCO, when the power control is set to maximum.
A temperature sensor (R481) is provided so that the RF output power can be reduced to
a preset level when a set temperature is exceeded. This is a protection circuit (IC350 pin
1, Q320) to prevent overheating.
#R517, #R518 and #R519 form an attenuator to provide good VCO/exciter isolation as
well as the correct exciter drive level.
The attenuator (#R395, #R396 and #R397) aids in producing the correct exciter drive
level to the PA over the three frequency ranges.
The RF output from the exciter is fed to the driver stage (Q410) and then to the final
(Q420). DC is fed to the final via a low pass filter with special low frequency decoupling. CV475 tunes the output matching across the entire band.
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M800 SL2
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T854 Circuit Operation
C2.13
01/03/02
C2.14
01/03/02
T854 Circuit Operation
M800 SL2
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T854 Initial Tuning & Adjustment
M800 SL2
C3.1
T854 Initial Tuning & Adjustment
Caution:
This equipment contains CMOS devices which are susceptible to damage from static charges. Refer to Section 1.2 in Part A for more information on anti-static procedures when handling these devices.
The following section describes both short and full tuning and adjustment procedures
and provides information on:
• channel programming
• selecting required audio links
• synthesiser alignment
• PA alignment
• modulator adjustment
• limiter adjustment
• setting line level
• compressor adjustment
• timer adjustment.
Unless otherwise specified, the term "PGM800Win" used in this and following sections refers to version 3.00 and later of the software.
Note:
Refer to Figure 4.4 and Figure 4.5 which show the location of the main tuning and
adjustment controls. Refer also to Section 6 where the parts lists, grid reference index
and diagrams will provide detailed information on identifying and locating components and test points on the main PCB. The parts list and diagrams for the VCO PCB are
in Part E.
Section
Title
Page
3.1
Introduction
3.3
3.2
Channel Programming
3.3
3.3
Test Equipment Required
3.4
3.4
Short Tuning Procedure
3.5
3.4.1
Introduction
3.5
3.4.2
Synthesiser Alignment
3.5
3.4.3
Output Power Adjustment
3.5
3.4.4
Two Point Modulation Adjustment
3.6
3.4.5
CTCSS Encoder (If Used)
3.7
3.4.6
FM Deviation (Limiter) Adjustment
3.7
3.4.7
Line-in Level Adjustment
3.7
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C3.2
T854 Initial Tuning & Adjustment
Section
3.5
M800 SL2
Title
Page
Audio Processor Links
3.8
3.5.1
Link Details
3.8
3.5.2
Typical Options
3.8
3.6
Synthesiser Alignment
3.9
3.7
PA Alignment
3.10
3.8
Thermal Shutdown
3.10
3.9
Audio Processor & CTCSS
3.11
3.9.1
Two Point Modulation
3.11
3.9.2
Modulator Adjustment
3.11
3.9.3
CTCSS Encoder (If Used)
3.12
3.9.4
Limiter Adjustment
3.12
3.9.5
Line Level Without Compressor
3.13
3.9.6
3.9.6.1
3.9.6.2
3.9.6.3
Compressor
Compressor On Line Input Only
Compressor On Microphone Input Only
Compressor On Both Line & Microphone Inputs
3.13
3.13
3.13
3.14
Figure
Title
Page
3.1
T854 Test Equipment Set-up With T800-01-0010
3.4
3.2
T854 Test Equipment Set-up Without T800-01-0010
3.4
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T854 Initial Tuning & Adjustment
M800 SL2
3.1
C3.3
Introduction
When you receive your T854 transmitter it will be run up and working on a particular
frequency (the "default channel")1. If you want to switch to a frequency that is within
the 8MHz switching range (i.e. ±4MHz from the factory programmed frequency), you
should only need to reprogram the transmitter/exciter with the PGM800Win software
(refer to the PGM800Win programming kit and Section 3.2 below).
However, if you want to switch to a frequency outside the 8MHz switching range, you
will have to reprogram and re-tune the transmitter/exciter to ensure correct operation.
In this case you should carry out the short tuning procedure described in Section 3.4.
If you have carried out repairs or other major adjustments, you must carry out the full
tuning and adjustment procedure described in this section (except for Section 3.4).
3.2
Channel Programming
You can program up to 128 channel frequencies into the transmitter/exciter’s EEPROM
memory (IC820) by using the PGM800Win software package and an IBM PC. You can
also use PGM800Win to select the transmitter/exciter’s current operating frequency (or
"default channel").
If the transmitter/exciter is installed in a rack frame, you can program it via the programming port in the speaker panel. However, you can also program the transmitter/
exciter before it is installed in a rack frame as follows:
• by using a T800-01-0010 calibration test unit;
• via D-range 1;
• via D-range 2 (standard T800-03-0000 auxiliary D-range only);
• via SK805 (internal Micromatch connector).
If you do not use the T800-01-0010, you will have to connect the PC to the transmitter/
exciter via a module programming interface (such as the T800-01-0004).
For a full description of the channel programming procedure, refer to the PGM800Win
programming software user’s manual.
Note:
When an auxiliary D-range kit (D-range 2 - T800-03-0000) is fitted, you can
also select a channel with an external switch, such as the DIP switch on the
rack frame backplane PCB. Refer to Part C in the T800 Series Ancillary
Equipment Service Manual (M800-00-101 or later issue) or consult your
nearest Tait Dealer or Customer Service Organisation for further details.
1. Use the "Read Module" function in PGM800Win to find out what the default channel is.
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C3.4
T854 Initial Tuning & Adjustment
3.3
Test Equipment Required
M800 SL2
You will need the following test equipment:
• computer with PGM800Win installed
• T800 programming kit
• module programming interface (e.g. T800-01-0004 - optional)
• 13.8V power supply
• digital multimeter
• audio signal generator
• RF power meter
• audio voltmeter x 2
or RF test set (optional)
• modulation meter
• oscilloscope (digital preferred)
• 20dB or 40dB pad
• T800-01-0010 calibration test unit (optional)
Figure 3.1 and Figure 3.2 show typical test equipment set-ups.
+13.8V
Frequency
Counter
20dB pad: exciter
40dB pad: transmitter
PSU
-Ve
Line I/P
600 Ω
Audio
Generator
CTCSS I/P
T800
Calibration
Test Unit
RF O/P
Exciter/
Transmitter
Modulation
Meter
AF O/P
Audio
Voltmeter
RF Power
Meter
Audio
Voltmeter
Oscilloscope
PGM800Win
Figure 3.1 T854 Test Equipment Set-up With T800-01-0010
+13.8V
-Ve
Line I/P
600 Ω
Audio
Generator
Frequency
Counter
20dB pad: exciter
40dB pad: transmitter
PSU
Exciter/
Transmitter
RF O/P
Modulation
Meter
CTCSS I/P
AF O/P
Key
Audio
Voltmeter
RF Power
Meter
Serial
Com
Audio
Voltmeter
Oscilloscope
via module programming interface
(e.g. T800-01-0004)
PGM800Win
Figure 3.2 T854 Test Equipment Set-up Without T800-01-0010
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T854 Initial Tuning & Adjustment
M800 SL2
3.4
C3.5
Short Tuning Procedure
Use this procedure only if you want to reprogram the T854 to a frequency outside the
8MHz switching range and do not intend to carry out any other major adjustments or
repairs.
3.4.1
Introduction
Reprogram the operating frequency as described in the PGM800Win programming kit (refer to Section 3.2).
Remove the top cover (nearest the handle).
Set up the test equipment as described in Section 3.3.
Set the links in the audio processor section as required (refer to Section 3.5).
3.4.2
Synthesiser Alignment
•
Connect a high impedance voltmeter to the long lead of L1 in the VCO (this measures the synthesiser loop voltage).
•
Key the transmitter by earthing the Tx-Key line.
•
Single Channel
Tune VCO trimmer C6 for a synthesiser loop voltage of
10V.
Multichannel
Tune VCO trimmer C6 for a synthesiser loop voltage of
10V on the middle channel.
If there is no middle channel, tune C6 so that the channels
are symmetrically placed around a loop voltage of 10V.
All channels should lie within the upper and lower limits
of 16V and 3V respectively.
Do not attempt to program channels with a greater frequency separation than the specified switching range of
8MHz.
3.4.3
Output Power Adjustment
Connect an RF power meter with suitable attenuation to the output socket and
key the transmitter.
Turn RV310 (power control) fully clockwise.
Tune #CV475 (output power trim) for maximum output power and check that this
is >30W.
Adjust RV310 for the required output power (between 5 and 25W).
Readjust #CV475 to reduce the supply current by up to 0.5A.
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C3.6
T854 Initial Tuning & Adjustment
3.4.4
Two Point Modulation Adjustment
Note 1:
In this and following sections deviation settings are given first for wide
bandwidth sets, followed by settings in brackets for mid bandwidth sets ( )
and narrow bandwidth sets [ ].
Note 2:
The reference modulation and limiter adjustments are controlled by 256step electronic potentiometers (EPOTs), which are adjusted via the “Reference Modulation” and “Deviation” settings in PGM800Win. This allows the
two point modulation and deviation settings to be adjusted for each channel.
Note 3:
To optimise the modulation response across the switching range, repeat
steps 1-4 below for each channel that will be used (usually needed only for
data applications). In applications where the modulation response is less
critical (e.g. voice use only), carry out steps 1-4 below on the middle channel
and use the “EPOT Fill” option1 in PGM800Win to copy the value to the
other channels.
Note 4:
If you are using an RF test set, turn the low pass filter off and set the high
pass filter to 15kHz before beginning this procedure.
1.
M800 SL2
Inject an audio signal of 300Hz 1.5V rms (+5dBm) into the CTCSS input (D-range
1 (PL100) pin 8).
Key the transmitter by earthing the Tx-Key line.
2.
Adjust the output from the audio generator to obtain ±3kHz (±2.4kHz) [±1.5kHz]
deviation at 300Hz.
3.
Change the input frequency to 100Hz and, using PGM800Win, adjust the value of
the “Reference Modulation” EPOT setting for the current channel to obtain ±3kHz
(±2.4kHz) [±1.5kHz] deviation (you can use either the mouse or up and down
arrow keys).
4.
Change the input frequency back to 300Hz.
Repeat steps 2 and 3 above until the deviations achieved at the two input frequencies are within 0.2dB of each other. You will need to do this at least four times.
5.
Sweep the audio between 50 and 300Hz for peaks.
A peak between 50 and 300Hz will indicate a fault condition, i.e:
Note:
or
- incorrect set-up
- modulation circuitry fault.
The specification window is ±1dB relative to 150Hz from 67 to 260Hz.
1. Use the “EDIT FILL” button on the tool bar or go to “Edit”, “Fill”, “Epot Settings” on
the menu bar.
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T854 Initial Tuning & Adjustment
M800 SL2
3.4.5
C3.7
CTCSS Encoder (If Used)
Program a CTCSS tone on the default channel using PGM800Win.
If you are using an RF test set, turn off the 300Hz high pass filter.
Key the T854 with the front panel "Carrier" switch.
Adjust RV805 (CTCSS level adjust) to give ±500Hz (±350Hz) [±250Hz] deviation.
Set the maximum deviation as per Section 3.4.6.
3.4.6
FM Deviation (Limiter) Adjustment
Note:
If the T854 will be used over the whole 8MHz switching range, you must set
the deviation for each channel. However, if the module will be used on frequencies that cover only a 1MHz (or less) switching range, you can set the
deviation on the middle channel and use this value for all other channels
with the “EPOT Fill” option in PGM800Win.
Inject 1kHz at -10dBm into the line input (D-range 1 (PL100) pins 1 & 4; pins 2 & 3
shorted; refer to Section 2.2 of Part F).
Adjust RV210 (line sensitivity) fully clockwise and key the transmitter by earthing
the Tx-Key line. Using PGM800Win, adjust the value of the “Deviation” EPOT
setting for the current channel to obtain a deviation limit of ±4.7kHz (±3.8kHz)
[±2.3kHz] (you can use either the mouse or up and down arrow keys).
Sweep the audio frequency from 100Hz to 4kHz and ensure that the maximum
deviation does not exceed ±4.7kHz (±3.8kHz) [±2.3kHz]. Readjust “Deviation” if
necessary via PGM800Win.
3.4.7
Line-in Level Adjustment
Remove the CTCSS signal (if used).
Set the injected signal at the line input to the required line level (typically -10 to
-20dBm).
Adjust RV210 (line sensitivity) to provide ±3kHz (±2.4kHz) [±1.5kHz] deviation.
Reapply the CTCSS signal (if required).
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C3.8
T854 Initial Tuning & Adjustment
3.5
Audio Processor Links
3.5.1
Link Details
M800 SL2
Use the following table to set up the audio processor to the configuration you require.
You should set the audio processor links before carrying out any of the tuning and
adjustment procedures. The factory settings are shown in brackets [ ].
Linka
Plug
PL205
PL210
PL215
PL220
Function
1-2
not connected
[3-4]
microphone pre-amp. output to compressor input
5-6
microphone pre-amp. output to multiplexer input
[1-2]
multiplexer output to pre-emphasis input
3-4
multiplexer output to limiter input
5-6
multiplexer output to compressor input
1-2
not connected
[3-4]
compressor output to multiplexer input
5-6
compressor output to limiter input
7-8
compressor output to pre-emphasis input
9-10
not connected
1-2
pre-emphasis output to multiplexer input
[3-4]
pre-emphasis output to limiter input
5-6
not connected
a. The letters in this column and in the table in Section 3.5.2 below refer to the identification
letters screen printed onto the PCB beside each pair of pins.
3.5.2
Typical Options
PL205
PL210
PL215
PL220
[3-4]
[1-2]
[3-4]
[3-4]
3-4
3-4
7-8
1-2
line and microphone compressed
and pre-emphasised
5-6
5-6
7-8
3-4
microphone pre-amp. compressed;
3-4
3-4
3-4
5-6
line and microphone flat response
microphone pre-amp. compressed
and pre-emphasised;
line input pre-emphasised
(standard set-up)
microphone pre-amp. compressed
and pre-emphasised;
line input unprocessed
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T854 Initial Tuning & Adjustment
M800 SL2
3.6
C3.9
Synthesiser Alignment
•
Ensure that the T854 has been programmed with the required frequencies using
PGM800Win software.
•
Single Channel
Select a channel using PGM800Win.
Multichannel
Select the middle channel via PGM800Win.
•
Connect a high impedance voltmeter to the long lead of L1 in the VCO (this measures the synthesiser loop voltage).
•
Key the transmitter by earthing the Tx-Key line.
Single Channel
Tune VCO trimmer C6 for a synthesiser loop voltage of
10V.
Multichannel
Tune VCO trimmer C6 for a synthesiser loop voltage of
10V on the middle channel.
If there is no middle channel, tune C6 so that the channels
are symmetrically placed around a loop voltage of 10V.
All channels should lie within the upper and lower limits
of 16V and 3V respectively.
Do not attempt to program channels with a greater frequency separation than the specified switching range
(8MHz).
•
Measure the exciter output frequency and adjust the TCXO (=IC700) trimmer if
required.
Caution:
Copyright TEL
This trimmer is susceptible to physical damage. Do not exert a downward force of more than 500g (1lb) when adjusting.
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C3.10
T854 Initial Tuning & Adjustment
3.7
PA Alignment
M800 SL2
Check that the exciter is connected to the PA with the coaxial link.
Connect an RF power meter to the PA output (use an appropriate attenuator as
necessary).
Turn RV310 (power control) fully clockwise.
Key the transmitter by earthing the Tx-Key line.
Tune #CV475 until maximum power is obtained. Check that the power exceeds
30W.
Adjust RV310 (power control) to 25W.
Readjust #CV475 to reduce the supply current by up to 0.5A.
3.8
Thermal Shutdown
Key the transmitter by earthing the Tx-Key line and set the output power to 25W
as described in Section 3.7.
Short L481 to ground.
Set RV330 (shutdown power level) for an output power of 5W.
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T854 Initial Tuning & Adjustment
M800 SL2
3.9
Audio Processor & CTCSS
3.9.1
Two Point Modulation
C3.11
The T854 utilise two point modulation to obtain a wide audio bandwidth independent
of the synthesiser loop filter response. This is achieved by simultaneously frequency
modulating the VCO and phase modulating the synthesiser reference frequency. The
relative signal levels fed to the two modulators are quite critical and cause interaction
when setting up.
Both modulating signals require readjustment when the exciter is shifted in frequency
greater than the switching range (i.e. ∆F>±4MHz).
Note 1:
In this and following sections deviation settings are given first for wide
bandwidth sets, followed by settings in brackets for mid bandwidth sets ( )
and narrow bandwidth sets [ ].
Note 2:
The reference modulation and limiter adjustments are controlled by 256step electronic potentiometers (EPOTs), which are adjusted via the “Reference Modulation” and “Deviation” settings in PGM800Win. This allows the
two point modulation and deviation settings to be adjusted for each channel.
Note 3:
To optimise the modulation response across the switching range, repeat
steps 1-4 below for each channel that will be used (usually needed only for
data applications). In applications where the modulation response is less
critical (e.g. voice use only), carry out steps 1-4 below on the middle channel
and use the “EPOT Fill” option1 in PGM800Win to copy the value to the
other channels.
Note 4:
If you are using an RF test set, turn the low pass filter off and set the high
pass filter to 15kHz before beginning this procedure.
3.9.2
Modulator Adjustment
1.
Inject an audio signal of 300Hz 1.5V rms (+5dBm) into the CTCSS input (D-range
1 (PL100) pin 8).
Key the transmitter by earthing the Tx-Key line.
2.
Adjust the output from the audio generator to obtain ±3kHz (±2.4kHz) [±1.5kHz]
deviation at 300Hz.
3.
Change the input frequency to 100Hz and, using PGM800Win, adjust the value of
the “Reference Modulation” EPOT setting for the current channel to obtain ±3kHz
(±2.4kHz) [±1.5kHz] deviation (you can use either the mouse or up and down
arrow keys).
1. Use the “EDIT FILL” button on the tool bar or go to “Edit”, “Fill”, “Epot Settings” on
the menu bar.
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01/03/02
C3.12
4.
T854 Initial Tuning & Adjustment
M800 SL2
Change the input frequency back to 300Hz.
Repeat steps 2 and 3 above until the deviations achieved at the two input frequencies are within 0.2dB of each other. You will need to do this at least four times.
5.
Sweep the audio between 50 and 300Hz for peaks.
A peak between 50 and 300Hz will indicate a fault condition, i.e:
Note:
or
- incorrect set-up
- modulation circuitry fault.
The specification window is ±1dB relative to 150Hz from 67 to 260Hz.
3.9.3
CTCSS Encoder (If Used)
Program a CTCSS tone on the default channel using PGM800Win.
If you are using an RF test set, turn off the 300Hz high pass filter.
Key the T854 with the front panel "Carrier" switch.
Adjust RV805 (CTCSS level adjust) to give ±500Hz (±350Hz) [±250Hz] deviation.
Set the maximum deviation as per Section 3.9.4.
3.9.4
Limiter Adjustment
Note:
If the T854 will be used over the whole 8MHz switching range, you must set
the deviation for each channel. However, if the module will be used on frequencies that cover only a 1MHz (or less) switching range, you can set the
deviation on the middle channel and use this value for all other channels
with the “EPOT Fill” option in PGM800Win.
Set the links in the audio processor section as required (refer to Section 3.5).
Inject 1kHz at -10dBm into the line input (D-range 1 (PL100) pins 1 & 4; and pins 2
& 3 shorted; refer to Section 2.2 of Part F).
Adjust RV210 (line sensitivity) fully clockwise and key the transmitter by earthing
the Tx-Key line. Using PGM800Win, adjust the value of the “Deviation” EPOT
setting for the current channel to obtain a deviation limit of ±4.7kHz (±3.8kHz)
[±2.3kHz] (you can use either the mouse or up and down arrow keys).
Sweep the audio frequency from 100Hz to 4kHz and ensure that the maximum
deviation does not exceed ±4.7kHz (±3.8kHz) [±2.3kHz]. Readjust “Deviation” if
necessary via PGM800Win.
01/03/02
Copyright TEL
T854 Initial Tuning & Adjustment
M800 SL2
3.9.5
C3.13
Line Level Without Compressor
This section assumes that the compressor is not used. If the compressor is required,
refer to Section 3.9.6.
Remove the CTCSS signal (if used).
Adjust the line sensitivity as follows:
• set the injected signal at the line input to the required line level (typically -10 to
-20dBm);
• adjust RV210 (line sensitivity) to provide ±3kHz (±2.4kHz) [±1.5kHz] deviation.
Reapply the CTCSS signal (if required).
3.9.6
Compressor
The compressor may be used on the line input only, the microphone input only, or on
both the line and microphone inputs. If the compressor is used, refer to one of the following sections as appropriate.
3.9.6.1
Compressor On Line Input Only
Set RV210 (line sensitivity) fully clockwise and key the transmitter by earthing the
Tx-Key line.
Reduce the line level to -50dBm at 1kHz and set RV220 (compression level) fully
clockwise.
Check that ±3kHz deviation (±2.4kHz) [±1.5kHz] is still available.
Slowly increase the audio input level until the demodulated waveform shows significant signs of clipping (approximately ±4.5kHz (±3.6kHz) [±2.3kHz] deviation).
Adjust RV220 anticlockwise until the demodulated waveform is just clipping
(approximately ±4kHz (±3.2kHz) [±2kHz] deviation).
Increase the input level to -10dBm and check that the test tone is still held just into
clipping. The input line level should be typically -10 to -20dBm.
3.9.6.2
Compressor On Microphone Input Only
Key the transmitter by earthing the Tx-Key line and plug a microphone jack into
the front panel socket.
Adjust RV220 (compression level) fully clockwise.
Acoustically couple the microphone to a tone box (1kHz) and close the PTT
switch.
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01/03/02
C3.14
T854 Initial Tuning & Adjustment
M800 SL2
Increase the audio level until the demodulated waveform shows significant signs
of clipping (approximately ±4.5kHz (±3.6kHz) [±2.3kHz] deviation).
Adjust RV220 anticlockwise until the demodulated waveform is just clipping
(approximately ±4kHz (±3.2khz) [±2kHz] deviation).
Increase the audio level by 10dB and verify that the test tone is held just into clipping.
Whistle steadily into the microphone, checking that approximately ±4kHz
(±3.2khz) [±2kHz] deviation is produced. The modulated waveform should be
basically sinusoidal.
Speak into the microphone, checking that the modulation peaks reach about
±5kHz (±4kHz) [±2.5kHz] deviation.
As the line is to be used without compression, set RV210 (line sensitivity) as
described in Section 3.9.5.
3.9.6.3
Compressor On Both Line & Microphone Inputs
Set up as described in Section 3.9.6.1.
01/03/02
Copyright TEL
T854 Functional Testing
M800 SL2
C4.1
T854 Functional Testing
Caution:
This equipment contains CMOS devices which are susceptible to damage from static charges. Refer to Section 1.2 in Part A for more information on anti-static procedures when handling these devices.
The following test procedures will confirm that the T854 has been tuned and adjusted
correctly and is fully operational.
Note 1:
In this and following sections deviation settings are given first for wide
bandwidth sets, followed by settings in brackets for mid bandwidth sets ( )
and narrow bandwidth sets [ ].
Note 2:
Unless otherwise specified, the term "PGM800Win" used in this and following sections refers to version 3.00 and later of the software.
Refer to Figure 4.4 and Figure 4.5 for the location of the main tuning and adjustment
controls, and to Section 3.3 for the test equipment set-up. Refer also to Section 6 where
the parts lists, grid reference index and diagrams will provide detailed information on
identifying and locating components and test points on the main PCB. The parts list
and diagrams for the VCO PCB are in Part E.
The following topics are covered in this section.
Section
Title
Page
4.1
Current Consumption
4.3
4.2
Output Power
4.3
4.3
Output Frequency
4.3
4.4
Timers
4.3
4.5
Frequency Response
4.4
4.6
Audio Level Input Sensitivity
4.7
Figure
Title
Page
4.1
T854 Transmit Timers
4.4
4.2
T854 Pre-emphasis Response
4.5
4.3
T854 Limiting Response
4.6
4.4
T854 Main Tuning & Adjustment Controls
4.9
4.5
T857 Main Tuning & Adjustment Controls
4.11
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01/03/02
C4.2
01/03/02
T854 Functional Testing
M800 SL2
Copyright TEL
T854 Functional Testing
M800 SL2
4.1
C4.3
Current Consumption
Connect the T854 to a 13.8V power supply.
Connect an RF power meter to the T854 output socket.
Check that the current in the 13.8V power cable is less than 150mA.
Key the T854 by earthing the Tx-Key line (the carrier "On" LED should light).
T854 Only:
Adjust RV310 (power control) to obtain 25W output power.
Check that the current is as follows:
T854
4.2
<5.5A
Output Power
Connect an RF power meter with suitable attenuation to the T854 output socket.
Key the T854 by earthing the Tx-Key line.
Check that:
T854
4.3
the output power adjusts to ≥25W with RV310 (power control)
turned fully clockwise
Output Frequency
Connect the T854 output to a frequency counter via an attenuator pad:
T854
T857
40dB pad
20dB pad.
Measure the output frequency and, if necessary, adjust the TCXO (=IC700) to trim
to the nominal frequency (±100Hz).
4.4
Timers
The transmit tail timer, transmit timeout timer and transmit lockout timer can all
be set from PGM800Win. The fields for setting these are found on the system
information page. These three timers operate as follows (refer also to Figure 4.1):
Timer
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Function
Adjustment
01/03/02
C4.4
T854 Functional Testing
M800 SL2
Transmit Tail
Sets the tail time during which the
transmitter stays keyed after the external key source has been removed.
0-5 seconds in 100ms
stepsa
Transmit Timeout
Sets the maximum continuous transmission time. Once the timer has
timed out, the transmitter must be
keyed again, unless prevented by the
transmit lockout timer.
0-300 secondsb in 10
second steps
Transmit Lockout
Sets the period of time that must
elapse after a timeout before the transmitter can re-transmit. Once the timer
has timed out, the transmitter can be
keyed again.
0-60 seconds in 10
second steps
a. Adjustable in 20ms steps in PGM800Win version 2.12 and later.
b. Adjustable in 20ms steps in PGM800Win version 2.12 and later.
Tx-Enable
On
Tx-Reg.
Tx-Enable
Tail Time
On
Tx-Reg.
Lockout Time
Timeout
Time
Figure 4.1 T854 Transmit Timers
4.5
Frequency Response
If the T854 has been correctly adjusted, the pre-emphasis and limiting responses should
closely match those shown in Figure 4.2 and Figure 4.3 respectively.
The limits shown on these graphs should not be exceeded.
Note:
•
If you are using an RF test set, turn off all filters.
•
Measure the pre-emphasis response as follows:
Reduce the line level to give ±1kHz (±0.8kHz) [±0.5kHz] deviation at 1kHz.
Sweep the modulation frequency.
The response should closely match that shown in Figure 4.2.
•
Measure the limiting response as follows:
Set the line level to give ±3kHz (±2.4kHz) [±1.5kHz] deviation at 1kHz.
Increase the line level 20dB and sweep the modulation frequency.
01/03/02
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T854 Functional Testing
M800 SL2
C4.5
The response should closely match that shown in Figure 4.3.
Wide Bandwidth
Peak + max. dev. = +1.0kHz @ 1000Hz
Peak - max. dev. = -1.0kHz @ 1000Hz
+10
+8
+6
Modulation Level (dB ref. to dev. @ 1kHz)
+4
+2
+0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
-22
100
200
300
500
1k
2k
3k
5k
10k
Frequency (Hz)
Mid Bandwidth
The mid bandwidth graph is the same shape as the wide bandwidth graph. The deviation figures are as follows:
peak + max. deviation = +0.8kHz
peak - max. deviation = -0.8kHz.
Narrow Bandwidth
Peak + max. dev. = +0.5kHz @ 1000Hz
Peak - max. dev. = -0.5kHz @ 1000Hz
+10
+8
+6
Modulation Level (dB ref. to dev. @ 1kHz)
+4
+2
+0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
-22
100
200
300
500
1k
2k
3k
5k
10k
Frequency (Hz)
Figure 4.2 T854 Pre-emphasis Response
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01/03/02
C4.6
T854 Functional Testing
M800 SL2
Wide Bandwidth
Peak + max. dev. = +4.9kHz @ 1500Hz
Peak - max. dev. = -4.4kHz @ 2500Hz
Above limiting (steady-state)
+10
+8
+6
Modulation Level (dB ref. to max. dev.)
+4
+2
+0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
-22
10
20
30
50
100
200
300
500
1k
2k
3k
5k
10k
Frequency (Hz)
Mid Bandwidth
The mid bandwidth graph is the same shape as the wide bandwidth graph. The deviation figures are as follows:
peak + max. deviation = +4kHz
peak - max. deviation = -4kHz.
Narrow Bandwidth
Peak + max. dev. = +2.4kHz @ 2000Hz
Peak - max. dev. = -2.5kHz @ 2000Hz
Above limiting (steady-state)
+10
+8
+6
Modulation Level (dB ref. to max. dev.)
+4
+2
+0
-2
-4
-6
-8
-10
-12
-14
-16
-18
-20
-22
10
20
30
50
100
200
300
500
1k
2k
3k
5k
10k
Frequency (Hz)
Figure 4.3 T854 Limiting Response
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T854 Functional Testing
M800 SL2
4.6
C4.7
Audio Level Input Sensitivity
•
Adjust RV210 (line sensitivity) fully clockwise.
•
Check that the input sensitivities are better than those specified below:
Line Input
Microphone Input
CTCSS Input
Note:
Copyright TEL
600 ohms, ±3kHz (±2.4kHz) [±1.5kHz] deviation at
1kHz:
with compressor
-50dBm
without compressor
-30dBm
600 ohms, ±3kHz (±2.4kHz) [±1.5kHz] deviation at
1kHz:
with compressor
-75dBm
without compressor
-55dBm
1kHz deviation at 150Hz
500mV rms
A degraded signal to noise ratio can be expected with the compressor
selected. The extent of the degradation is dependent on the audio input
level.
01/03/02
C4.8
T854 Functional Testing
M800 SL2
RV805
CTCSS
level adjust
#CV475
SK805
L1
=IC700
TCXO
R481
L481
C6
RV330
shutdown
power level
RV320
shutdown
temperature
RV310
power control
SW230
carrier
01/03/02
RV210
line sensitivity
RV220
compression level
PL205 PL220 PL215 PL210
Copyright TEL
T854 Fault Finding
M800 SL2
C5.1
T854 Fault Finding
Caution:
This equipment contains CMOS devices which are susceptible to damage from static charges. Refer to Section 1.2 in Part A for more information on anti-static procedures when handling these devices.
The following test procedures and fault finding flow charts may be used to help locate a
hardware problem, however they are by no means a complete fault finding procedure.
If you still cannot trace the fault after progressing through them in a logical manner,
contact your nearest Tait Dealer or Customer Service Organisation. If necessary, you
can get additional technical help from Customer Support, Radio Systems Division, Tait
Electronics Ltd, Christchurch, New Zealand (full contact details are on page 2).
Note 1:
In this and following sections deviation settings are given first for wide
bandwidth sets, followed by settings in brackets for mid bandwidth sets ( )
and narrow bandwidth sets [ ].
Note 2:
Unless otherwise specified, the term "PGM800Win" used in this and following sections refers to version 3.00 and later of the software.
Refer to Section 6 where the parts lists, grid reference index and diagrams will provide
detailed information on identifying and locating components and test points on the
main PCB. The parts list and diagrams for the VCO PCB are in Part E.
The following topics are covered in this section
Section
Title
Page
5.1
Visual Checks
5.3
5.2
Component Checks
5.3
5.3
Front Panel LED Indicator
5.3
5.4
DC Checks
5.4
5.4.1
Power Rails
5.4
5.4.2
VCO Locking
5.4
RF Checks
5.5
5.5.1
T854 Drive Power
5.5
5.5.2
T854 PA Output Power
5.5
5.5.3
T857 Output Power
5.5
5.5.4
Audio And Modulation
5.6
PGM800Win Generated Errors
5.7
5.5
5.6
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01/03/02
C5.2
T854 Fault Finding
Section
5.7
M800 SL2
Title
Page
Fault Finding Charts
5.8
5.7.1
5.7.1.1
5.7.1.2
5.7.1.3
Microcontroller
Basic Checks
Serial Communications
CTCSS Encode
5.8
5.8
5.9
5.10
5.7.2
Regulator
5.11
5.7.3
Synthesiser
5.12
5.7.4
T854 Drive Amplifier
5.15
5.7.5
T854 PA & Power Control
5.16
5.7.7
Audio Processor
5.18
To Replace The T854 PA Transistors (Q410 & Q420)
5.19
5.8
Figure
Title
Page
5.1
RF Diode Probe Circuit
5.5
5.2
Typical Transistor/Capacitor Spacing (Not To Scale)
5.19
01/03/02
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T854 Fault Finding
M800 SL2
5.1
C5.3
Visual Checks
Remove the top cover from the T854 and inspect the PCB for damaged or broken components, paying particular attention to the surface mounted devices (SMD's).
Check for defective solder joints. If repair or replacement is considered necessary, refer
to Section 3 of Part A.
5.2
Component Checks
If you suspect a transistor is faulty, you can assess its performance by measuring the forward and reverse resistance of the junctions. Unless the device is completely desoldered, first make sure that the transistor is not shunted by some circuit resistance. Use a
good quality EVM (e.g. Fluke 75) for taking the measurements (or a 20k ohm/V or better multimeter, using only the medium or low resistance ranges).
The collector current drawn by multi-junction transistors is a further guide to their performance.
If an IC is suspect, the most reliable check is to measure the DC operating voltages. Due
to the catastrophic nature of most IC failures, the pin voltages will usually be markedly
different from the recommended values in the presence of a fault. The recommended
values can be obtained from either the circuit diagram or the component data catalogue.
5.3
Front Panel LED Indicator
The green "Supply" LED on the T854 front panel will flash according to the conditions
described in the following table:
Flash Rate
Condition
fast
(a sec. on/a sec. off
approx.)
T854 is linked with PGM800Win
unequal
(a sec. on/1 sec. off
approx.)
microcontroller has detected an
internal communications error refer to Section 5.7.1
Where two or more conditions occur at the same time, the precedence is in the order
shown above (i.e. T854 linked has the highest priority, followed by internal error).
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01/03/02
C5.4
T854 Fault Finding
5.4
DC Checks
5.4.1
Power Rails
M800 SL2
Refer to the test points and options diagrams in Section 6 for test point locations, and to
the regulator fault finding chart (Section 5.7.2) for fault diagnosis.
Check the 13.8V (TP601) and 9V (TP602) supplies at their test points in the regulator compartment with a DMM.
Check the 5V (TP604) and 20V (TP603) rails at their respective test points in the
regulator compartment.
Check that Tx-Reg. (TP305 in the exciter compartment) comes up to 8.8V when the
exciter is keyed.
Check the +5V digital regulator output (TP607 in the regulator compartment).
T854 Only:
Check the 9V supply (IC370 pin 1) with a DMM.
Check for short circuits.
5.4.2
VCO Locking
Key the exciter.
Using a DMM, monitor the VCO control voltage between between L1 and PL14
pin1 on the VCO PCB.
If the synthesiser is locked and the VCO aligned, the voltage at this point should
be between 3 and 16V.
If the VCO is not locked, refer to the synthesiser fault finding chart (Section 5.7.3).
01/03/02
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T854 Fault Finding
M800 SL2
5.5
C5.5
RF Checks
In-circuit RF levels may be measured with an RF probe on which the earth lead has been
shortened to a minimum (i.e. 13mm). Refer to the circuit diagrams for typical levels.
Figure 5.1 shows a suitable RF probe circuit..
1n
Probe
Coax
10k
DC to DVM or
Oscilloscope
1N6263
1n
100k
Earthing Clip
This unit is not suitable for use on high power RF circuits.
Figure 5.1 RF Diode Probe Circuit
5.5.1
T854 Drive Power
Refer to the drive amplifier fault finding chart (Section 5.7.4).
Ensure that the VCO locks (refer to Section 5.4.2).
Connect the drive output to a power meter and key the transmitter.
Check that the exciter output power (SK310) is >1.5W.
Note:
If the synthesiser is out of lock, the lock detector (synthesiser IC740 and
comparator IC750) will prevent the RF signal from reaching the PA by
switching the supply to the exciter amplifier (Q336, Q337).
5.5.2
T854 PA Output Power
Reconnect the drive output to the PA input.
Connect the PA to a power meter and key the transmitter.
Check that the output power is >30W with RV310 (power control) adjusted fully
clockwise.
5.5.3
Audio And Modulation
Refer to the audio processor fault finding chart (Section 5.7.6).
Set up the audio processor as described in Section 3.9.
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01/03/02
C5.6
T854 Fault Finding
M800 SL2
Check that the demodulated RF output has the frequency response referred to in
Section 4.5 with at least ±5kHz (±4kHz) [±2.5kHz] deviation available at 1kHz
modulating frequency.
If the above result is not achieved, either the two modulators are incorrectly adjusted or
a fault condition exists.
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T854 Fault Finding
M800 SL2
5.6
C5.7
PGM800Win Generated Errors
The following errors are those most likely to occur using PGM800Win. Refer to the
PGM800Win software user’s manual for a complete list of error messages.
Channel Switch Set
The programmed default channel change was not accepted by the base station because a
channel is selected externally. Try turning the external channel switch off to change the
default channel in PGM800Win.
Synth Out Of Lock
The synthesiser received incorrect data, or the data was corrupted. Enter a frequency
within the VCO switching range, or tune the VCO.
Internal Error
Data could not be read from the base station due to an internal error. Check for shorts
or open circuits on the SDA, SCK, SYNTH and EPOT lines. The SDA, SCK and SYNTH
are normally high, and the EPOT is normally low.
Write/Read To An Unlinked Module
The link to the module does not exist. Undefined error.
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01/03/02
C5.8
T854 Fault Finding
5.7
Fault Finding Charts
Note:
The standard test point designations used in this section are as follows:
TP601
TP602
TP603
TP604
M800 SL2
13.8V
9V
20V
5V
5.7.1
Microcontroller (IC810)
5.7.1.1
Basic Checks
Is the 12.8MHz clock
present on IC810 pin 21
(microcontroller)?
Check IC710.
Replace
IC810.
Is pin 30
pulsing?
Replace
IC650.
Pulsing
Check the
state of
pin 10.
High or open circuit
Low
Check state of
pins 36 to 43.
*digital storage oscilloscope
Pulsing
Static high/low
Replace IC810.
01/03/02
Use a DSO* to check
operation of IC650
(i.e. active high
pulse at power up).
Check state
of pin 35.
High
Replace
IC810.
Low/floating
Correct the fault causing
pin 35 to be low/floating.
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T854 Fault Finding
M800 SL2
5.7.1.2
C5.9
Serial Communication
Disconnect the
programming lead.
Is IC810 pin 11 high?
(microcontroller)
Low/floating
Check pin state.
Check the transistor
interface circuitry.
Noise
on pin
Check the SERIAL-COM
and AUDIO-1/2 links.
Connect the programming
lead and use PGM800Win
to read the rack/radio.
Check I/O pad P810
with a DSO*.
Does it swing from
0 to 5V?
*digital storage
oscilloscope
Check the transistor
interface circuitry
and/or replace the
programming lead.
Use PGM800Win
to send a POLL
command to the
radio.
Check IC810 pin 13
with a DSO. Is there
a response from IC810 after
a poll command is sent?
Replace
IC810.
Check the transistor
interface circuitry
and/or replace the
programming lead.
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01/03/02
C5.10
T854 Fault Finding
5.7.1.3
CTCSS Encode
Use PGM800Win to
select a channel
with a CTCSS tone
programmed.
M800 SL2
Cannot select a channel
Check serial communications.
(See separate flow chart).
Check IC810 pins 24, 25
& 26 (microcontroller).
Are there 5V square waves at
the CTCSS frequency?
No square waves or
uneven mark/space ratio
Replace IC810.
Check IC830 pins 1, 7 & 14.
Are there 9V square waves at
the CTCSS frequency?
No square waves or
uneven mark/space ratio
Check IC830 circuitry
and repair/replace.
Check IC830 pin 8.
Is there a sine wave
at the CTCSS frequency?
No tone
Check RV805.
Distorted tone
Check the filter circuit for bias
problems and/or short circuits.
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T854 Fault Finding
M800 SL2
5.7.2
C5.11
Regulator
Check for
overheating
components &
short circuits.
13.8V present on
IC630 pin 3?
Check continuity
from pin 9 of
D-range 1.
5.3V present on
IC630 pin 1?
Replace IC630.
9.0V present
on TP602?
Check Q630,
Q620 & IC640.
20V present
on TP603?
Check Q660 is
switching at
approx. 150kHz.
+5V present on
IC610 pin 1?
Check R615.
Replace IC610.
Key Tx.
8.8V present
on Tx reg. TP305?
Regulators OK.
0V present
on Q860 collector?
Replace Q610.
0.6V present on
Q860 base?
Check Q860 and
associated circuitry.
Regulators OK.
Check microcontroller
section.
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01/03/02
C5.12
T854 Fault Finding
5.7.3
Synthesiser
M800 SL2
Refer to the synthesiser circuit diagram (sheet 7) in Section 6 and the VCO circuit diagram in Part E.
No VCO RF output.
VCO out of lock.
9V present at
VCO Q4/Q5?
Check Tx reg.,
Q610 & 9V reg.
+5V present at
IC700, IC710,
IC740, IC720
& IC730?
Check biasing
resistors, Q4 & Q5.
20V present
on IC750 pin 8?
8.3V present
at VCO?
9V present on
Q795 divider buffer?
20V inverter
supply faulty.
Check 9V supply.
Check biasing
resistors, Q1,
Q2 & Q3.
Check Q5 C
multiplier
(synth).
DC V present at
VCO, Q1, Q2 & Q3?
Check 5V reg. &
supply resistor
to each IC.
DC V present
at Q4 & Q5?
DC V present
on Q795 emitter?
Check biasing
resistors & Q795.
Capacitors OK?
Check for cracks,
shorts, etc.
Replace
if faulty.
Does VCO trimmer
adjust for stable
control line
between 3 & 16V?
Replace VCO.
VCO freq. correct?
Recheck
programming
via PGM800Win.
Check VCO tuning
caps & trimmer.
VCO trimmer
freq. range OK?
Does VCO trimmer
adjust for required
frequency range
between 3 & 16V?
Check #C1, #C7, #C8,
C6 & D1-D2 in VCO.
Is 8MHz VCO range
achieved between
3 & 16V?
Synthesiser OK.
VCO OK.
Continued on the next page
01/03/02
Copyright TEL
T854 Fault Finding
M800 SL2
C5.13
Continued from previous page
Check microcontroller
section (IC810).
Replace synthesiser
(IC740).
Check phase detector output
pins (IC740 pins 3 & 4).
Are there very narrow pulses
(~50ns) at the reference frequency?
(i.e. 5kHz : 200µs period
6.25kHz : 160µs period)
*See Note below.
Check programming.
Check serial bus
when programming
i.e. clock/data/enable
activity (IC740 pins
18, 19 & 17).
Programming and
serial bus OK?
Is reference
clock present
at IC740 pin 20
(200kHz >4.5Vpp)?
Is the charge pump bias
voltage at the base of
Q760 & Q780 between
3.5 and 5V? (5V when locked)
Check Q760, Q780,
R766 & C765.
Check phase
modulator sections:
IC720, Q710, Q720,
D710, Q730, Q740,
D720.
Is reference
clock present
at IC730 pin 12
(200kHz >4.5Vpp)?
Is the voltage on C762,
R760, and R758 9V ±0.2V?
Check R762 & C762.
Check divider
IC730.
Is reference
clock present
at IC730 pin 1
(12.8MHz >4.0Vpp)?
Is the charge pump voltage
on Q790 gate between
3 and 8.5V? (6.5V ±0.2V locked)
Check charge pump components
(Q775 & Q780) and Q790.
Check TCXO (IC700)
and buffers (IC710).
Is the loop filter reference
voltage at C772 (+) 6.5V ±0.2V?
Check C772, R774, R772,
C770, R763 & Q790.
Check loop filter components
R775, C774, C776, R510,
C505, IC750. Is the supply
to IC750 +20V +4, -2V?
Check regulator circuitry.
Check the signal path from
the VCO to synthesiser.
Measure the frequency from
the VCO at IC740 pin 11 using
a frequency counter.
No signal
Check VCO.
Signal
Is the level >-10dBm?
Does the frequency adjust
as the VCO trimmer is
adjusted (out of lock)?
Replace synthesiser
(IC740).
Copyright TEL
Check divider buffer
circuit (Q795) and bias
voltages on Q795 emitter
(1.3V ±0.2V).
*Note:
When locked, both of these
are very narrow (~50ns).
If unlocked, one will be
very narrow (~50ns),
and the other wide (>15µs).
01/03/02
C5.14
T854 Fault Finding
M800 SL2
Noisy synth;
poor residual FM.
VCO phase locked?
3-16V present on
control line?
Go to B.
Correct DC V
present on Q1 VCO?
Check inductors,
biasing resistors
& Q1.
Loop filter &
components around
op. amp. (IC750) OK?
Replace if faulty.
Isolate audio
modulation on VCO;
still noisy?
Trace audio fault.
Change trimmer;
still noisy?
Change Q1;
still noisy?
Change TCXO;
still noisy?
Change varactors;
still noisy?
Replace VCO
assembly.
Synthesiser OK.
01/03/02
Copyright TEL
T854 Fault Finding
M800 SL2
5.7.4
C5.15
T854 Drive Amplifier
Key exciter
& lock
synthesiser.
10.5V on Q350
collector?
10.5V on Q355
collector?
10.5V on Q315
collector?
11.5V on
IC350 pin 7?
>2V RF at
VCO output?
Check continuity
of power rails
& DC paths to
Q365 & Q370.
13.8V on
IC350 pin 8?
Check VCO.
Check
regulators.
>1V RF
at R381?
Check attenuator
pad #R517, #R518,
#R519.
Check lock det.
path back to
synth. IC740,
IC750, Q325.
>0.5V RF at
Q350 base?
Check TP305
>+8V.
Check C355, C358,
C360, Q350, D340,
D380, D360, L320.
>5V RF at
C362, #R395?
Check 9V &
13.8V supplies.
Check temp.
shutdown
circuit.
Check TP320
<0.6V.
Check Q350.
Check Q310,
Q315 circuitry
& IC350.
>1V RF at
Q355 base?
Check signal
path between
Q350 & Q355.
>6V RF at
Q355 collector?
Check Q355.
Check signal
path to output
incl. output
socket (SK310).
Copyright TEL
01/03/02
C5.16
T854 Fault Finding
5.7.5
T854 PA & Power Control
M800 SL2
Normal operating conditions:
Set RV320
(power adjust)
fully clockwise;
synth. locked;
key Tx.
Forward power
Reverse power
IC350 pin 6
IC350 pin 5
IC350 pin 7
4.7V approx.
0.7V approx.
2.02V
2V
8.63V
Check Q410,
Q420 & circuitry,
LP filter.
Tx delivering
full power
(>30W)?
10.8V
at L310?
Check drive at
SK310 >1.5W.
Check +13.8V at
Q410 & Q420.
Refer to Drive Amp.
Fault Finding Chart.
<2V on
IC350 pin 6?
Check supply
circuitry.
Check IC330,
Q310, Q315
& circuitry,
+13.8V supply.
Check lock det. circuit;
TP305 should be >8V.
Check temp. shutdown
circuit (IC350);
TP320 should be <0.6V.
Check Q320, RV330.
Turn RV310 ccw.
Check power
drops to zero
slowly in a
controlled manner.
Does variation
of RV310
cause either
full power
or no power?
Check for break
in power sense
circuitry; directional
coupler D420,
D440 & circuitry.
Set RV310 so that
output power = 25W;
check L310 approx. 7.5V.
Momentarily remove
Tx load. Voltage at
L310 decreases to
approx. 5V?
01/03/02
Power control
circuitry OK.
Note:
c/w = clockwise
cc/w = counterclockwise
or anticlockwise
Copyright TEL
T854 Fault Finding
M800 SL2
5.7.6
C5.17
Audio Processor
Key exciter &
lock synthesiser.
Connect 1kHz audio
to external CTCSS input.
Does exciter
modulate?
Audio output at
IC260 pin 8?
Check audio path to
VCO control line.
Check alignment
of modulators.
Audio output at
IC260 pin 1?
Check buffer IC260
pins 8, 9 & 10.
Demodulated audio
frequency response
flat between 50 & 300Hz?
Audio output at
IC260 pin 7?
Check low pass
filter stage IC260
pins 1, 2 & 3.
Check low
pass filter
stage IC260
pins 1, 2 & 3.
Check stage IC260
pins 5, 6 & 7.
Audio frequency
response IC260
pin 1 flat 300Hz
to 2kHz?
Audio frequency
response IC210
pin 8 6dB/octave
slope?
Check integrator
IC210 pins 8, 9, & 10.
Audio superimposed
on 200kHz signal
IC720 pins 9 & 3 (synth)?
Check audio path
between integrator
& phase modulator.
200kHz clipped
triangle wave at
IC720 pins 8 & 4?
Check IC720, Q710, Q720,
Q730, Q740, D710, D720,
C727, C729, C724 & C725
Check loop filter
(IC750, pins 5, 6 & 7)
& associated
components.
Audio signal at
IC210 pin 14?
Check audio path between
limiter IC210 pin 14 &
summing amp. IC260 pin 7.
Select standard
audio configuration.
Audio signal at
IC230 pin 1?
Check IC210
pins 12, 13 & 14.
Demodulated
audio frequency
response as per
Section 4.5?
Audio signal at
IC230 pin 14?
Connect audio
to line input;
key exciter.
Does exciter
modulate?
Check IC230 pins 1, 2 & 3 or
audio path between preemphasis network & limiter.
Check IC230 pins 12, 13 & 14
or audio path between multiplexer
& pre-emphasis network.
Check pre-emphasis
network IC230 pins 12,
13 & 14 &/or low pass
filter IC260 pins 1, 2 & 3.
Audio signal at
IC240 pin 4?
IC240 pin 6
at 9V?
Check IC240 or audio
path between line transformer & multiplexer.
Audio processor
OK.
Copyright TEL
Check Q260 is not faulty or
being turned on inadvertently.
01/03/02
C5.18
T854 Fault Finding
5.8
To Replace The T854 PA Transistors
(Q410 & Q420)
M800 SL2
Caution:
Failure to comply with the following procedure can result in failure of
the device due to poor heatsinking, or worse, can endanger the health
of the assembler if the beryllium oxide die carrier is smashed during
assembly.
Caution:
As the location of certain components in the PA is critical to performance, it is important that any components removed or disturbed are
refitted in exactly the same position.
Before attempting to remove a transistor, measure the distance
between the capacitors and transistor body to the nearest 0.5mm (measurement "A" in Figure 5.2) so that the capacitors can be replaced in
exactly the same position. These measurements are shown in Figure
5.2 for the 6LFL package, however the same procedure applies for the
SOE (stud) package.
Caution:
Do not apply too much heat or pressure to the PCB pads and tracks as
you may damage them or lift them from the PCB, causing permanent
damage to the transmitter.
base
collector
measurement A
Figure 5.2 Typical Transistor/Capacitor Spacing (Not To Scale)
Desolder and remove the components from around the transistor.
Q420 Only:
Desolder and remove the two solder tags.
Desolder the transistor tabs by heating with a soldering iron and lifting away
from the PCB with a screwdriver or thin stainless steel spike, then remove the
device.
01/03/02
Copyright TEL
T854 Fault Finding
M800 SL2
Q410 Only:
C5.19
Unscrew the transistor stud nut and remove the device.
Remove any excess solder from the PCB pads with solder wick.
Trim the tabs of the replacement transistor so that the device sits neatly on the
PCB pads provided.
Lightly tin the underside of the transistor tabs. Remove any excess solder to leave
a thin, even layer on the tabs.
Apply a small amount of heatsink compound (Dow-Corning 340 or equivalent) to
the transistor mounting surface. Sufficient compound should be used to ensure
an even film over the entire mounting surface.
Place the transistor on the PCB in the correct orientation and ensure the tabs are
flush to the surface.
Q410 Only:
Caution:
Lightly solder one tab to the PCB, then torque down the retaining nut to the correct torque (0.7Nm/6in.lbf.).
Do not solder all the tabs before torquing down otherwise the device
may be broken.
Q420 Only:
Refit the solder tags.
Solder all transistor tabs to the PCB.
Replace each component in exactly the same position as noted previously.
Copyright TEL
01/03/02
C5.20
01/03/02
T854 Fault Finding
M800 SL2
Copyright TEL
T856/857 PCB Information
M800 SL2
C6.1.1
T854 PCB Information
Caution:
This equipment contains CMOS devices which are susceptible to damage from
static charges. Refer to Section 1.2 in Part A for more information on anti-static
procedures when handling these devices.
This section provides the following information on the T854 transmitter exciter:
• parts lists
• grid reference indexes
• mechanical assembly drawings
• PCB layouts
• test points & options connections drawings
• circuit diagrams.
Section
Title
IPN
Page
6.1
Introduction
6.2
T854 Transmitter PCB
220-01397-01
6.2.1
6.3
T857 Exciter PCB
220-01398-02
220-01398-04
6.3.1
6.3.29
Copyright TEL
6.1.3
01/03/02
C6.1.2
01/03/02
T856/857 PCB Information
M800 SL2
Copyright TEL
T856/857 PCB Information
M800 SL2
6.1
C6.1.3
Introduction
Product Type Identification
You can identify the transmitter or exciter type by checking the product code printed on a label on
the rear of the chassis (product codes are explained in Section 1.3 in this Part of the manual, and Figure 1.1 in Part A shows typical labels). You can further verify the product type by checking the
placement of an SMD resistor in the table that is screen printed onto the top side of the PCB, similar
to the example drawn below. In this example, the resistor indicates that the product was built as a
T854-10-XXXX.
856-30
856-10
856-20
856-
856-13
856-23
856-15
856-25
PRODUCT TYPE
Note:
PRODUCT TYPE
856-35
The only function of this resistor is to indicate the product type. It has no effect on the
circuitry or operation of the transmitter or exciter.
PCB Identification
All PCBs are identified by a unique 10 digit “internal part number” (IPN), e.g. 220-01390-02, which
is screen printed onto the PCB (usually on the top side), as shown in the example below:
The last 2 digits of this number define the issue status, which starts at 00 and increments through 01,
02, 03, etc. as the PCB is updated. Some issue PCBs never reach full production status and are therefore not included in this manual. A letter following the 10 digit IPN has no relevance in identifying
the PCB for service purposes.
Note:
Copyright TEL
It is important that you identify which issue PCB you are working on so that you can
refer to the appropriate set of PCB information.
01/03/02
C6.1.4
T856/857 PCB Information
M800 SL2
Parts Lists
The 10 digit numbers (000-00000-00) in this Parts List are “internal part numbers” (IPNs). We can
process your spare parts orders more efficiently and accurately if you quote the IPN and provide a
brief description of the part.
The components listed in this parts list are divided into two main types: those with a circuit reference (e.g. C2, D1, R121, etc.) and those without (miscellaneous and mechanical).
Those with a circuit reference are grouped in alphabetical order and then in numerical order within
each group. Each component entry comprises three or four columns, as shown below:
circuit reference lists components
in alphanumeric
order
variant column indicates that this is
a variant component
which is fitted only to
the product type listed
description gives a brief description
of the component
Internal Part Number order the component
by this number
The miscellaneous and mechanical section lists the variant and common parts in IPN order.
Parts List Amendments
At the front of the parts list is the Parts List Amendments box (an example of which is shown
below). This box contains a list of component changes which took place after the parts list and diagrams in this section were compiled. These changes (e.g. value changes, added/deleted components, etc.) are listed by circuit reference in alphanumeric order and supersede the information
given in the parts list or diagrams. Components without circuit references are listed in IPN order.
The number in brackets at the end of each entry refers to the Tait internal Change Order document.
IPN of new
component
Change Order
number
Parts List Amendments
R306
Changed from 180Ω to 560Ω (036-13560-00) to increase sensitivity (71003).
circuit reference
or IPN
description
of change
01/03/02
Copyright TEL
T856/857 PCB Information
M800 SL2
C6.1.5
Variant Components
A variant component is one that has the same circuit reference but different value or specification in
different product types. Where two products share the same PCB, the term “variant” is also used to
describe components unplaced in one product. Variant components have a character prefix, such as
“&”, “=” or “#”, before the circuit reference (e.g. &R100).
The table below explains the variant prefixes used in M800 SL2 products:
If the variant prefix is. . .
the component will. . .
change according to channel spacing
change according to frequency stability
change according to frequency range
change or be placed/unplaced for special applications
be unplaced in one product
(where two products share the same PCB)
Grid Reference Index
This section contains a component grid reference index to help you find components and labelled
pads on the PCB layouts and circuit diagrams. This index lists the components and pads in alphanumeric order, along with the appropriate alphanumeric grid references, as shown below:
components listed
in alphanumeric order
PCB layout
reference
circuit diagram
reference
component location
on the sheet
sheet number
component location
on the layer
layer number 1 = top side layer
2 = bottom side layer
Copyright TEL
01/03/02
C6.1.6
T856/857 PCB Information
M800 SL2
Using CAD Circuit Diagrams
Reading a CAD circuit diagram is similar to reading a road map, in that both have an alphanumeric
border. The circuit diagrams in this manual use letters to represent the horizontal axis, and numbers for the vertical axis. These circuit diagram “grid references” are useful in following a circuit
that is spread over two or more sheets.
When a line representing part of the circuitry is discontinued, a reference will be given at the end of
the line to indicate where the rest of the circuitry is located, as shown below. The first digit refers to
the sheet number and the last two characters refer to the location on that sheet of the continuation of
the circuit (e.g. 1R3).
DISCRIMINATOR
1R3
2R9
2R9
8A2
C371
%R338
100
10U
R339
100K
C369
100P
these grid references
show where the circuit
is continued
01/03/02
C301
4N7
R303
L310
33U
4R4
G S
IF-SIG
12
Copyright TEL

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