Ritron RIT17-445 UHF TRANSCEIVER User Manual SST 454 THEORY OF OPERATION

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Document Title	SST-454 THEORY OF OPERATION
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®
DTX-445-MRM
Rev. A
RITRON
DTX-445
PROGRAMMABLE UHF
FM TRANSCEIVER MODULE
MAINTENANCE & OPERATING MANUAL
FOR USE ONLY BY AUTHORIZED SERVICE/MAINTENANCE PERSONNEL
TABLE OF CONTENTS
SECTION
TOPIC
1.
INTRODUCTION
GENERAL
Model Identification
FCC REGULATIONS
Licensing
Exposure to Radio Frequency Energy
FCC Label
MAINTENANCE INFORMATION
Surface Mount Repairs
Precautions for handling CMOS
Synthesizer shield
DTX-445 SPECIFICATIONS
GENERAL
RECEIVER
TRANSMITTER
3.
SETUP
OPERATION
INSTALATION
10
10
10
4.
SUB-D 15 PIN CONNECTOR
10
5.
PROGRAMMING THE RADIO
PROGRAMMING THE RADIO USING A PC COMPUTER
Using the Programming Software
Computer Software Copyrights
12
12
12
DTX-445 THEORY OF OPERATION
OVERVIEW
POWER SUPPLY AND VOLTAGE DISTRIBUTION
REFERENCE OSCILLATOR
SYNTHESIZER
RECEIVER
Receiver Front End
FM Receiver Subsystem
Voice and Tone Conditioning
TRANSMITTER
Voice and Tone Conditioning in Transmitter
RF Path
MICROCONTROLLER
13
13
13
13
14
14
14
14
15
15
16
17
DTX-445 ALIGNMENT PROCEDURE
RECOMMENDED TEST EQUIPMENT
RADIO PREPARATION
RADIO ADJUSTMENTS
18
18
18
2.
6.
7.
PAGE
INTRODUCTION
General
RITRON's DTX-445 transceiver module operates in one of a number of frequency bands. Typical
radio parameters such as frequency, power, deviation, deviation balance, squelch level and input and
output gain are PC adjustable. The transceiver is a single board unit with components on one side and pin
for pin compatible with the DTX-442.
The unit supports voice through a microphone input and a nominal one watt speaker output or data through
the auxiliary in and auxiliary out ports. Each radio can be dealer or factory programmed to contain a unique set
of eight operating frequencies and sub-audible tones. When all three channel select inputs are tied to ground
the radio operates on channel 1. The channel selection is done in a binary manner on the CS2, CS1 and CS0
inputs. Separate RX and TX Quiet Call (CTCSS) or Digital Quiet call (DCS) tones can be programmed per
channel. Transmitter wide or narrow deviation can be programmed on a per channel basis. The unit is factory
set up to transmit 2 or 8 watts when operating at 12.5 VDC. A 5 watt maximum power version is also available.
The standby current drain at 12.5 VDC is typically about 20 mA.
Model Identification
The DTX-445 is available in an aluminum encased version with a BNC connector or a board-only
version with or without shield. The shielded board model protects the components as well as adds
stiffness to the unit, yielding good micro-phonic performance. The board only version can have one of a
variety of RF connectors.
The model number form is: “ DTX-445-ABCDE ”
Where:
A is frequency band:
H =
400.5
to
G=
411
to
0 =
450
to
416.5 MHz
429 MHz
470 MHz
B is the connector type:
B =
BNC
C =
BNC on flying coaxial cable
M=
SMB
X =
MCX
S =
SMA
C designates the receiver IF bandwidth:
N =
Narrow
W=
Wide
D designates the maximum RF power output:
5 =
5 watt
8 =
8 watt
E designates the case:
D =
deletion of case
E =
enclosure
S =
shield
Examples:
DTX-445-GBW5E
411 to 429 MHz wideband receiver in case with BNC connector
DTX-445-OSN8S
450 to 470 MHz narrowband receiver with SMA connector and shield
Units without cases can be delivered with a vertical or right angle female DB-15 connector.
Contact the RITRON sales department for further details.
Enclosed version
Shielded Version
FCC REGULATIONS
Licensing
The FCC requires the radio operator to obtain a station license for the radios before using them to transmit, but
does not require an operating license or permit.
The station licensee is responsible for ensuring that transmitter power, frequency and deviation are within the
limits specified by the station license. The station licensee is also responsible for proper operation and maintenance of
the radio equipment. This includes checking the transmitter frequency and deviation periodically, using appropriate
methods.
Exposure to Radio Frequency Energy
RF ENERGY EXPOSURE AWARENESS AND CONTROL INFORMATION, AND OPERATIONAL INSTRUCTIONS
FOR FCC OCCUPATIONAL USE REQUIREMENTS
BEFORE USING YOUR MOBILE 2-WAY RADIO, READ THIS IMPORTANT RF
ENERGY AWARENESS AND CONTROL INFORMATION AND OPERATIONAL
INSTRUCTIONS TO ENSURE COMPLIANCE WITH THE FCC’S RF EXPOSURE GUIDELINES.
NOTICE: This radio is intended for use in occupational/controlled conditions, where users have full knowledge of their
exposure and can exercise control over their exposure to meet FCC limits. This radio device is NOT authorized for
general population, consumer, or any other use.
This 2-way radio uses electromagnetic energy in the radio frequency (RF) spectrum to provide communications
between two or more users over a distance.
It uses radio frequency (RF) energy or radio waves to send and receive calls. RF energy is one form of electromagnetic
energy. Other forms include, but are not limited to, electric power, sunlight and x-rays. RF energy, however, should not
be confused with these other forms of electromagnetic energy, which when used improperly can cause biological
damage. Very high levels of x-rays, for example, can damage tissues and genetic material.
Experts in science, engineering, medicine, health and industry work with organizations to develop standards for
exposure to RF energy. These standards provide recommended levels of RF exposure for both workers and the general
public. These recommended RF exposure levels include substantial margins of protection. All 2-way radios marketed in
North America are designed, manufactured and tested to ensure they meet government established RF exposure
levels. In addition, manufacturers also recommend specific operating instructions to users of 2-way radios. These
instructions are important because they inform users about RF energy exposure and provide simple procedures on how
to control it. Please refer to the following websites for more information on what RF energy exposure is and how to
control your exposure to assure compliance with established RF exposure limits.
http://www.fcc.gov/oet/rfsafety/rf-faqs.html
http://www.osha.gov/SLTC/radiofrequencyradiation/index.html
Federal Communications Commission Regulations
The FCC rules require manufacturers to comply with the FCC RF energy exposure limits for mobile 2-way radios before
they can be marketed in the U.S. When 2-way radios are used as a consequence of employment, the FCC requires
users to be fully aware of and able to control their exposure to meet occupational requirements. Exposure awareness
can be facilitated by the use of a label directing users to specific user awareness information.
Your Ritron 2-way radio has an RF exposure product label. Also, this Ritron DTX-445 user manual includes information
and operating instructions required to control your RF exposure and to satisfy compliance requirements.
Compliance with RF Exposure Standards
Your Ritron two-way radio is designed and tested to comply with a number of national and international standards and
guidelines (listed below) regarding human exposure to radio frequency electromagnetic energy. This radio complies with
the IEEE and ICNIRP exposure limits for occupational/controlled RF exposure environment at duty factors of up to 50%
talk and 50% listen and is authorized by the FCC for occupational use. In terms of measuring RF energy for compliance
with the FCC exposure guidelines, your radio antenna radiates measurable RF energy only while it is transmitting
(during talking), not when it is receiving (listening) or in standby mode. Your Ritron two-way radio complies with the
following RF energy exposure standards and guidelines:
• United States Federal Communications Commission, Code of Federal Regulations; 47 CFR §§ 2 sub-part J.
• American National Standards Institute (ANSI) / Institute of Electrical and Electronic Engineers (IEEE) C95. 1-1992.
• Institute of Electrical and Electronic Engineers (IEEE) C95.1-1999 Edition.
Copyright Telecommunications Industry Association
To control exposure to yourself and others and ensure compliance with the
occupational/controlled environment exposure limits always adhere to the following procedures:
Guidelines:
• User awareness instructions should accompany device when transferred to other users.
• Do not use this device if the operational requirements described herein are not met.
Instructions:
Transmit only when people in the vicinity are at least the recommended minimum lateral distance away, as shown in
Table 1, from a properly installed antenna according to installation instructions.
NOTE - Table 1 lists the recommended minimum lateral distance for bystanders in an uncontrolled environment from
transmitting types of antennas (i.e., monopoles over a ground plane, or dipoles) at several different ranges of rated
radio power for mobile radios installed on a vehicle.
Table 1. Rated Power and Recommended Lateral Distance
Antenna
Model
Rated Power of
Mobile Two-way Radio
Recommended Minimum Lateral
Distance from Transmitting Antenna
Ram1545
10 watts or less
6.7 inches (17 cm)
Cushcraft PE-457-6
10 watts or less
22 inches (56 cm)
Antennas
• Install vertical omni directional antennas above a suitable ground plane taking into account the recommended
minimum lateral distances in table 1. The antenna installation should additionally be in accordance with:
a.) The requirements of the antenna manufacturer/supplier.
b.) Instructions in the Radio Installation Manual, including minimum antenna cable lengths.
c.) The installation manual should provide specific information of how to install the antennas to facilitate recommended
operating distances to all potentially exposed persons.
Contact Information
For additional information on exposure requirements or other information, contact Ritron at (317) 846-1201 or
www.ritron.com.
FCC Label
An FCC label must be visible on the unit as installed in its final configuration. If the DTX-445 is to be installed in an
enclosure, the installer must ensure that either the FCC label on the unit is visible through a door, window or other
opening, or add a label to the outside of the enclosure. If a label is to be added to the outside of the enclosure, the label
must be of a type which is not easily removed or damaged and contain wording: Contains FCC ID: AIERIT17-445.
MAINTENANCE INFORMATION
Surface Mount Repair
RITRON surface mount products require special equipment and servicing techniques. Improper servicing
techniques can cause permanent damage to the printed circuit board and/or components, which is not covered by
RITRON’s warranty. If you are not completely familiar with surface mounted component repair techniques, RITRON
recommends that you defer repair to qualified service personnel.
Precautions for Handling CMOS Devices
This radio contains complementary metal-oxide semiconductor (CMOS) devices, which require special handling
techniques. CMOS circuits are susceptible to damage by electrostatic or high voltage charges. Damage can be latent,
with no failure appearing until weeks or months later. For this reason, take special precautions any time you
disassemble the radio. Follow the precautions below, which are even more critical in low humidity environments.
1)
2)
3)
4)
5)
6)
7)
Storage/transport - CMOS devices that will be stored or transported must be placed in conductive material so that
all exposed leads are shorted together. CMOS devices must not be inserted into conventional plastic “snow” or
plastic trays of the type that are used for other semiconductors.
Grounding - All CMOS devices must be placed on a grounded bench surface. The technician that will work on the
radio/CMOS circuit must be grounded before handling the radio. Normally, the technician wears a conductive wrist
strap in series with a 100K Ohm resistor to ground.
Clothing - Do not wear nylon clothing while handling CMOS circuits.
Power off - Remove power before connecting, removing or soldering a PC board that contains CMOS devices.
Power/voltage transients - Do not insert or remove CMOS devices with power applied. Check all power supplies to
be used for testing CMOS devices, making sure that no voltage transients are present.
Soldering - Use a grounded soldering iron for soldering CMOS circuitry.
Lead-straightening tools - When straightening CMOS leads, provide ground straps for the tool used.
Synthesizer and RF Power Amplifier Shield
The synthesizer or power amplifier shield should not be removed unless a component must be replaced. This
shield is soldered to the main PC board. Sucking or wicking the solder up around the perimeter can remove the shield. If
this should prove difficult a side cutter can cut the top off after which the walls can be removed. A replacement shield
will then be needed and is available from RITRON.
DTX-445 SPECIFICATIONS
GENERAL
FCC ID:
IC ID:
AIERIT17-445
1084A-RIT17445
FCC Rule Parts:
IC Rule Parts:
90
RSS-119
Frequency Range:
400.6 – 416.5*, 411 – 429*, or 450 - 470 MHz
RF Channels:
8 Independent TX/RX frequencies
Frequencies unusable in 406.6 – 416.5 MHz band:
Frequencies unusable
in 411 - 429 MHz band
Unusable 6.25 kHz steps:
Frequencies unusable
in 450 – 470 MHz band
Unusable 6.25 kHz steps:
None- all 6.25 kHz steps available
RX
417.60000
418.03750
418.04375
418.05625
418.06250
TX
417.58750
417.59375
417.60625
417.61250
RX
460.80000
461.23750
461.24375
461.25625
461.26250
TX
460.78750
460.79375
460.80625
460.81250
Frequency Stability:
+/-1.5 PPM (-30° to +60° C)
Tone/Code Signaling:
CTCSS (Quiet Call) and DCS
Power Supply:
9 to 17 VDC
Current Drain:
RX Standby:
Transmit:
Transmit:
23 mA at 12.5 VDC
1.8 Amp @ 8 Watts at 12.5 VDC
1.8 Amp @ 10 Watts at 14 VDC
Dimensions & weight:
Board only version:
Shielded version:
Encased version:
4.75” x 2.8”x .625” 2.1 oz
4.75” x 2.8”x .625” 3.4 oz.
5.7” x 3” x 1.375”
7.3 oz.
Antenna Fitting:
BNC female with encased version. Other options available on board only version.
Transmitter Duty Cycle:
With supply below 13.5 volts:
8 W board only model - 100 % with added heat sink** maintained at 25° C
8 W encased model - 33 % with case end cap*** maintained at 25° C
5 W encased model - 50 % with case end cap*** maintained at 25° C
(with heat sink or case end cap above 25° C, degrades linearly to 0% at 60° C)
* pending model
** a heatsink can be added to the board only versions using the two holes next to the RF PA shield.
*** case end cap refers to aluminum extrusion end cap on opposite side from connectors.
DTX-445 SPECIFICATIONS
Sensitivity (12 dB SINAD):
RECEIVER
25 kHz Wide band
0.25 µV
12.5 kHz Narrow band
0.25 µV
Adjacent channel:
-67 dB
-60 dB
Spurious rejection:
-70 dB
-70 dB
Image rejection:
-75 dB
-75 dB
Intermodulation:
-67 dB
-67 dB
FM hum and noise:
-43 dB
-37 dB
Conducted spurious:
-57 dBm
-57 dBm
Receiver attack time (TX to RX):
< 10 ms
< 10 ms
Noise squelch attack time:
(for 20 dB quieting)
RSSI squelch attack time:
< 15 ms
< 15 ms
< 5 ms
< 5 ms
RSSI squelch sensitivity:
PC adjustable; factory set for –106 dBm
Noise squelch sensitivity:
PC adjustable; factory set for –121 dBm
AUX OUT frequency response:
AUX OUT level range:
12 - 2500 Hz @ +1 / -3 dB
0 to 3 Volts peak-to-peak
Audio Speaker Output
Audio Speaker freq response:
>700 mW into 8 Ω, with less than 5 % THD ( 0 to 2.5 Vrms)
de-emphasized 6 dB/octave from 400 to 2500 Hz
RF Power Output:
TRANSMITTER
2.0 watts @ 12.5 VDC < .9 A
8.0 watts @ 12.5 VDC < 1.8 A
10.0 watts @ 14 VDC < 1.8 A
Voice Emission Designator:
15K0F3E
10K0F3E
Data Emissions Designator for external modem:
9K8F1D
Deviation:
+/- 5.00 kHz
+/- 2.50 kHz
Transmitter attack time:
< 10 ms
< 10 ms
FM Hum and Noise:
-45 dB
-40 dB
Audio Distortion:
<5%
<5%
Spurious and Harmonics:
-25 dBm max
Aux In frequency response:
Aux In level range:
8 Hz to 2500 Hz @ +1 / -3 dB
0.1 to 5 V peak-to-peak
Microphone freq response:
Microphone level:
pre-emphasized 6 dB/octave from 300 to 2500 Hz
25 mV rms for nominal +/- 3 kHz deviation on wideband channel
SETUP
OPERATION
The DTX-445 uses two connectors for operation and one for factory use. The sub D-15 contains signal, control and
power lines and the RF connector receives low level signals and transmits power. The third connector on the unit is
used for initial factory flash programming of the unit. The radio’s eight transmit and receive frequencies are programmed
via a PC. Pins 1, 2 and 3 of the DB-15 connector select the channel. The receiver bandwidth is fixed in either a wide or
narrow bandwidth and ordered as such from the factory. The transmitter can be programmed for either wide or
narrowband deviation on a channel by channel basis. A monitor input activates both speaker and auxiliary outputs,
allowing a modem to continually search for a signal. A high/low RF power control pin allows selection of transmitter
power level. Separate microphone and auxiliary inputs allow either pre-emphasized voice or flat data to be transmitted.
Only one input should be driven at a time. Separate speaker and auxiliary outputs allow either de-emphasized voice or
flat data output. A carrier detect output is pulled high when the channel is busy. Alternately, the MON ITOR input can be
used as a carrier and tone detector output. Adjacent to the DB-15 connector, a dual colored LED appears on the sub D15 edge of the board. It has the following functions:
Bright RED while transmitting
Bright GREEN when carrier is present on channel
Bright blinking RED when PLL is unlocked, PA overheats or TX regulator voltage not present while attempting to
transmit
Dull blinking red when receiver PLL is unlocked or TX regulator remains on in receive mode.
INSTALLATION
The antenna should be installed in a location to minimize radiation to the DTX-445 board and DB-15 connector
harness. Antenna positioning is also important in minimizing interference to the receiver. PCs and motors are notorious
producers of electrical noise. In a noisy environment the receiver squelch level can be raised to avoid spurious
reception.
To maximize transmission power, the power supply cable should be of sufficient gauge to minimize voltage drop.
Measuring the voltage between pin 6 and pin 15 on the DB-15 connector while transmitting will show the actual radio
voltage. For higher duty transmitter cycles, heating of the board should be considered. An external heat sink can be
added to the bottom of the board only version using the two mounting holes on both sides of the RF PA shield. On the
shielded board model the shield will help heat sink the unit. On the encased model the heat is conducted out of the
aluminum end cap opposite the connectors. When transmitting with higher duty cycle usage at elevated ambient
temperatures, without heat sinking, the internal board heat may push the reference oscillator Y301 temperature higher
than the 60 ºC specified limit for 1.5 ppm operation. Some form of additional cooling must be employed to avoid this
situation. Operating at voltages higher than 14 volts with high duty cycle usage can generate additional heat from the
regulator. The transmitter voltage regulator regulates the voltage to around 13.5 volts. The regulator will dissipate power
while transmitting when the supply voltage exceeds 14 volts. A thermistor, or temperature sensitive resistor, monitoring
the voltage regulator temperature will trigger a transmitter shutdown with excessive heat. Also, a thermistor monitoring
the final RF FET will trigger a transmitter shutdown if it overheats.
10
SUB D 15 PIN CONNECTOR
The DTX-445 is equiped with a 15 pin female sub D connector with the following functions:
Pin#
10
11
12
13
14
15
Function
Least significant channel select bit (CS0)
Channel select 1 (CS1)
Most significant channel select (CS2)
Microphone input
High/ low power select (pull low to get low power)
+ 9 to 17 VDC input
Auxilary input
Auxilary ouput
PC programing port
Volume control (RSSI option)
Auxilary monitor input (pull to ground to open squelch). Can be used for tone detect, see below.
Speaker output
Carrier detect output (pulls to 3.3 VDC through internal 390 ohms)
PTT (pull to ground to transmit)
Ground
Channel Select (pins 2,1,0)
Three lines control the channel selection; CS2, CS1, CS0. The inputs have binary weighting of 4, 2 and 1 respectively.
They are internally pulled up in the microcontroller. Tying an input to ground gives it a zero weighting. Thus, if no inputs
are tied low channel eight is selected (7 binary).
Microphone (pin 4)
An electret microphone can be connected to the microphone input at pin 4. An internal 33 k ohm resistor tied to +3.3
VDC on the DTX-445 supplies power to the microphone. An internal 1k ohm resistor connected to pin 14 allows PTT
when the microphone PTT is pressed. The microphone sensitivity can be adjusted with the AUX_IN gain pot.
High/ Low Power Input (pin 5)
Pulling this input to ground will yield about 2 watts of transmit power. Unconnected it will transmit up to 10 watts. Actual
power output will depend on supply voltage and programmed setting.
Power Input (pin 6)
A power source of 9 to 17 VDC with 2 Amp capability should be connected here. Once power is applied to pin 6 of the
radio, the microcontroller will start and load the receive frequency of the channel designated by CS2, CS1 and CS0
(pins 3, 2 and 1).
Auxiliary Input (pin 7)
This input has a frequency response from 8 Hz to 2500 Hz. The input gain is set up at the factory to produce +/- 3 kHz
deviation (1.5 kHz for narrowband channel) when a 300 mV peak-peak signal is applied. The gain can be adjusted by
the programmer for other input levels. Gain is PC adjusted by a 256 position 100k ohm e-pot. Higher voltage level
inputs need lower gain and therefore have coarser tuning per pot position. Recommended range is 100 to 1000 mV
peak-to-peak.
Auxiliary Output (pin 8)
An output loading of 600 ohms or greater should be applied to this output. With a 600 ohm load the output exhibits a
frequency response of 12 Hz to 2500 Hz. Higher load impedances will lower the low end frequency response. The
output is adjustable via the programmer. It is preset at the factory to give 1 volt peak to peak output when receiving a +/3 kHz (1.5 kHz for narrowband channel) deviated signal. Output range is 0 to 3 V peak-to-peak.
Programming Port (pin 9)
This line is a bi-directional programming port to be connected to a RITRON programming cable. The other end of the
programming cable connects to the PC’s serial port 25 pin D-sub connector. The appropriate DTX-445 programming
software must be run for configuring the transceiver (See programming the radio on page 10).
External Volume Potentiometer (pin 10)
11
Connecting a 10K pot to ground at this point will allow the speaker volume to be adjusted. For maximum range the
internal AUX_OUT gain should be set to a value that allows maximum volume with acceptable distortion when the pot is
set at 10K. Optionally, this pin can be used as an RSSI output. If desired, contact the factory.
Monitor Input (pin 11)
Normally the AUX_OUT and SPEAKER_ OUT are switched on only when a carrier with required tone, if
programmed, is detected. Bringing this input to ground will force the auxiliary and speaker outputs on. Alternately,
the monitor input can be used as an output. It gets pulled low when a carrier with correct tone is detected. The
following circuitry can be used as a carrier and tone detect output. Pin 11 can still be pulled low to monitor the
channel. Notice the high impedance 470 k ohm buffer resistor. Too low of resistance will turn the audio on.
External circuit to use AUX_MON input as Tone Detect output
Vdc
15 k
15 k
Tone detect = 0
470 k
Pin 11
Tone detect = Vdc
Speaker (pin 12)
An 8 ohm or higher speaker should be connected to pin 12. One watt of audio power is possible. The speaker volume is
set via the programmer AUX_OUT gain. The output signal can be further attenuated by a fixed or variable resistor from
pin 10 to ground to attenuate the audio.
Carrier Detect Output (pin 13)
This line will be pulled to 3.3 volts through an internal 390 ohm resistor when a carrier is present. This output is carrier
detect only. It gets pulled high at the same time the green LED lights.
Push-To-Talk (pin 14)
Pulling the PTT input low activates the transmitter, and must be held low while transmitting. Alternately, a microphone
with a PTT switch (switched to ground through < 3 k ohm) can be connected to pin 4 to activate transmission. A
programmable time-out-timer will shut down transmission when PTT is held down too long.
12
PROGRAMMING THE RADIO
PROGRAMMING THE RADIO USING A PC COMPUTER
RITRON’s programming kit, DTXL-PCPK-2.2, allows programming of the DTX-445 model radios using a PC
compatible computer.
The PC Programming Kit Includes:
1) Ritron Transceiver programming software, DTXL-PCPS-2.2, which is contained on a CD-ROM.
2) Ritron PC to radio adapter cable, 9/RTC-PAS, which is terminated at one end with a DB-25F connector, at the other
end with a 6 pin modular plug.
3) Another cable, DTXP-PAC, with a modular jack (which mates to the previous cable) on one end with a DB-15M on
the other end to mate to the radio. Power leads are also provided. Red is positive.
The PC Programming Kit Requires: A PC compatible computer with Windows 95 or later. The computer must have an
RS-232 serial port available. A hard disk drive is recommended.
Programming the DTX-445: To program the DTX-445 do the following:
1) Connect the PC’s RS-232 port to 9/RTC-PAS and DTXP-PAC programming cable. Connect DTXP-PAC to DTX-445
2) Apply 9 to 17 VDC power to pin 6 of the DB-15 (Red wire)
3) Insert disk. View the disk contents and double click on setup.exe. Follow the instructions on screen. When finished
the software will be resident on the PC’s hard disk.
Using the Programming Software
Upon starting the software with a radio connected to the programming cable and powered up, the PC will read the
radio data. A form then appears identifying the radio and displaying all channel information. If no radio is connected
when the software is started a form appears asking the operator to select a model. When a model is selected default
parameters for that model are displayed. These parameters can be programmed into a radio or a previously defined file
can be recalled and loaded. To program a radio click radio on the menu bar and then click program radio. To read the
radio contents click radio on the menu bar and then read radio. Allow several seconds for the reading to take place. To
change a parameter click a white field or double click the channel field to access it. Files can be saved and opened
using the File menu option.
Channel features can be programmed differently on each channel. One channel can have wide band deviation (+/5 kHz) on the transmitter and another narrow band (+/- 2.5 kHz). The receiver remains fixed. It can be ordered with wide
or narrowband filters. Transmit and receive frequencies and also QC or DQC tones on a channel can be different. A
channel can also be moved or deleted. A transmit time out timer of up to 254 seconds can be programmed. Entering
255 will disable the time out timer. An ID string of up to 72 characters can be entered to allow PC programmers to
identify radios.
Computer Software Copyrights
The RITRON, Inc. products described in this manual include copyrighted RITRON, inc. computer programs. Laws
in the United States and other countries grant to RITRON, inc. certain exclusive rights in its copyrighted computer
programs, including the exclusive right to distribute copies of the programs, make reproductions of the programs, and
prepare derivative works based on the programs. Accordingly, any computer programs contained in RITRON, inc.
products may not be copied or reproduced in any manner without the express written permission of RITRON. The
purchase of RITRON, inc. products does not grant any license or rights under the copyrights or other intellectual
property of RITRON, inc., except for the non-exclusive, royalty fee license to use that arises in the sale of a product, or
as addressed in a written agreement between RITRON, inc. and the purchaser of RITRON, inc. products.
13
DTX-445 THEORY OF OPERATION
POWER SUPPLY AND VOLTAGE DISTRIBUTION
The DTX-445 is powered by a 9 to 17 VDC external power supply. F601 is a 3A reset able fuse in series with
J301 for short circuit or reverse connection protection. If reverse voltage is applied, F601 will temporarily “blow” open
when excess current flows through D601. Disconnect the supply to reset the fuse. Reconnect power correctly and
proceed. An input voltage below 17 VDC must be maintained.
The DTX-445 is designed to consume low current by using a switching DC/DC converter called a buck converter.
Receiver standby current is less than 20 mA at 13.8 volts. In the receive mode current drain goes up as the voltage
goes down. The buck converter outputs about 40 mA at 6.2 volts. The conversion efficiency of the buck converter is
about 85%. Lowering the supply voltage will cause more current to be drawn from the supply. The buck converter’s
output of 6.2 volts feeds a 3.3 volt low drop out regulator U602. The 3.3 volt regulator supplies the logic and audio
processing ICs. A voltage regulator consisting of Q209, Q210 and Q214 limits the RF final PA and audio PA voltages to
+14 volts. This circuitry is enabled by Q211 only when transmitting. An 8 volt regulator consisting of Q204 and Q205
supply power to the VCO buffer stages Q402, Q404 and Q203 during transmission. When supply voltages greater than
14 volts are used the internal regulator can get hot with prolonged transmissions.
REFERENCE OSCILLATOR
Reference oscillator Y301 is a temperature compensated, voltage controlled crystal oscillator (TCVCXO) operating
at 14.4 MHz. The output of the TCVCXO provides a reference for the frequency synthesizer U401 at Pin 8. The
reference oscillator also feeds pin 7 of the U301 microcontroller through a buffer amplifier Q303. The Y301 output is
also multiplied (tripled) up to 43.2 MHz by Q104 and its associated circuitry to provide the receiver second local
oscillator signal.
SYNTHESIZER
The DTX-445 radio is built around a single PLL synthesized voltage-controlled oscillator (VCO). When the receiver
or transmitter mode is switched, a new synthesizer operating frequency is selected. Microcontroller U301 clocks new
data into the U401 internal buffer in synchronization with clock pulses. The channel information is stored in the EE
memory of U301 and is loaded into RAM when the channel is selected. The single VCO operates from 406 to 470 MHz.
In receive mode, the synthesizer operates 43.65 MHz lower than the receive frequency. When transmitting, the voice or
data is applied to the modulation varactor diode CR401. The loop filter C407, C408, C413, R402 and R405 transform
the pin 2 output signal to a DC voltage for application to the VCO tuning varactor CR402. The synthesizer system is
“locked” when the phase and frequency of both the reference and the divided VCO signal are the same. The VCO
control voltage can be measured with a DVM at test point 1 (TP1) on the bottom of the board below the synthesizer
shield.
RECEIVER
Receiver Front End
The signal from the antenna passes through the transmitter lowpass filter and then goes to the SAW bandpass
filter FL101. Q101 amplifies the signal about 11 dB before going through another SAW bandpass filter FL102 and the
mixer matching stage. The receiver is turned on by Q212 and Q213 supplying RX_3.3v when RXEN of U301 goes high.
The amplified received input signal is applied to the input of mixer U103. The 1st local oscillator signal from the
synthesizer is applied to the local oscillator input of the mixer. Y101 and Y103, a 43.65 MHz four-pole crystal filter forms
the first IF filtering. Q103 and associated components amplify the 43.65 MHz IF signal and apply it to the input of the
2nd mixer at Pin 16 of U101.
FM Receiver Subsystem
A multi-function integrated circuit, U101 and associated components form the FM-receiver subsystem. The
subsystem performs the functions of a 2nd mixer, IF amplifier and FM detector. The second local oscillator at 43.2 MHz
is applied to the 2nd local oscillator input at Pin 1 of U101. The 43.65 MHz signal at Pin 16 and the 2nd local oscillator
are mixed, with the resulting 450 kHz output signal appearing at Pin 3. This signal is filtered by a 450 kHz 6-pole
ceramic filter YF101 and applied to the input of the limiting IF amplifier at Pin 5. IC101 pin 6 de-couples the IF amplifier.
An internal quadrature detector, whose center frequency is determined by the 450 kHz quadrature resonator Y102
detects the FM IF signal. One input of the quadrature detector is connected internally to the IF signal from pin 11 while
the other input is the phase-shifted signal from Y102 at Pin 10. Demodulated audio appears at Pin 9, where a lowpass
14
filter formed around U303-C removes the spurious second IF output prior to application to the voice, tone and squelch
conditioning audio circuitry.
Two types of squelch circuits exist on the DTX-445, an RSSI squelch and a NOISE squelch. Both types can be
used simultaneously or either one or the other can be used. The RSSI (receive signal strength indicator) squelch, which
is typically set around –108 dBm, must be set to open at a higher level than the noise squelch. This is necessary since
the RSSI measures total power in the receiver IF bandpass. All background noise, which at VHF can be high, is seen as
signal. The advantage of the RSSI squelch is that it opens and closes the audio paths very quickly. The noise squelch
has the advantage that it can be set at a much lower level, typically –121 dBm for 12 dB SINAD. It takes longer to open
and close noise squelch. If both are used simultaneously, since they are ORed together at U301 pin 32, the squelch will
open quickly and close slowly for strong signals. The RITRON programmer can be used to adjust levels or turn one or
the other off. A dual colored LED will shine green when carrier is detected.
Voice and Tone Conditioning in Receiver
Three post demodulation paths are provided in the DTX-445. U303c provides DC level translation to bias
succeeding op amp stages at about 1.6 volts. The audio then gets de-emphasized by R366 and C364. The audio path
then goes through a fourth order 300 Hz highpass filter U308b and U308c. The 1 watt audio amp is turned on by Q304
and Q301.
The audio and data signals go through a programmable adjustable gain inverting buffer stage U303d, used to set
the output voltage.
Sub-audible signals go through a third order 250 Hz lowpass filter U303b. Pin 27 of U301 decodes the CTCSS or
DCS signal. In the case of CTCSS the processor, using an internal discrete Fourier transform, looks for the wanted
tone. Decode bandwidth is about +/-2 Hz.
Receiver Current Consumption
The radio will monitor the channel until a carrier becomes present. When an on channel carrier appears, the carrier
detect line (pin 13) will be pulled high through a 390 ohm resistor R309. If the correct CTCSS or DCS tone is present
the radio will unsquelch the speaker and auxiliary output lines. In standby mode the radio consumes 20 mA or less.
When unsquelched the audio PA is turned on. If only the auxiliary output and no voice is needed current consumption
can be reduced by disabling the audio PA. This is done by removing R383 and will bring current consumption down to
about 33 mA during receive. If a modem is used that is able to monitor the auxiliary output continually then AUX_MON
can be tied low. By disabling both RSSI and noise squelch, (both levels set high) the current can be reduced to 20 mA.
TRANSMITTER
Voice and Tone in Transmitter
In transmit mode two audio paths and one tone path exists. The microphone input is a high gain pre-emphasized
path. U308-D along with C359, C360, R363 and R374 form a 300 Hz high pass filter. This filters out audio voice
components that will disturb DQC decoding. R364 and C362 form the pre-emphasis network. Signal limiting occurs in
U305-A. “Splattered” higher frequency components are later filtered out by the fifth order 2500 Hz low pass filter
consisting of U304-C and D. Microphone gain can be adjusted with the AUX_IN e-pot.
The AUX_IN, with a flat frequency response, goes through an inverting adjustable amp U303-A. The AUX_IN gain
should be adjusted so that with the desired signal level the required deviation is transmitted. With high level inputs
deviation limiting occurs in U303-A. The unit is preset in the factory to limit at +/- 5 kHz with high input levels and give
+/- 3 kHz (+/- 1.5kHz narrowband channel) deviation with 300 mV peak-to-peak input. Either the microphone input or
the AUX_IN input should be driven at any one time. The two combine in the U303-A limiter.
The CTCSS and DCS sub-audible tone are generated by the U301 pin 13. These tones are generated by the pulse
width modulated (PWM) output at pin 13 of the microcontroller. The 8 bit PWM output operates at 28.8 kHz. A third
order low pass filter consisting of R346, C332 and U304-B suppress harmonics higher than 300 Hz for QC and DQC
tones.
Both the VCO and the reference oscillator are modulated by all signals resulting in a nearly flat frequency response
from DC to 2500 Hz. The FM deviation of the VCO is set by the “deviation” potentiometer U307-C. The reference
oscillator’s deviation and VCO balance is adjusted by the “balance” pot U307-B. The balance pot is adjusted to give a
minimal tilt on an 800Hz generated waveform. The CTCSS deviation from 67 to 254 Hz lies between 600 and 900 Hz in
wideband mode.
15
RF Path and control
The VCO feeds pre-driver stages Q402 and Q404 which feeds the pre-driver Q203 and driver Q202. The final
Q201 is an FET device. The power supply to the Final power FET Q201 is turned on by a voltage regulator built around
Q209. The power supply to the driver is controlled by a feedback power controller. The power control circuitry maintains
a constant current supply to the final Q201 transistor. Q208 is monitoring current through the two paralleled 0.1 ohm
shunt resistors. U202 is a comparator op amp. Potentiometer U305b is used to set the power level. When the current
through the two 0.1 ohm resistors exceeds the level set by the power controller the output of Q208 increases. This in
turn causes U202 pin 4 output to drop forcing the voltage on the collector of Q206 to drop thereby reducing power. The
feedback power control voltage to the driver can be measured with a DVM at test point 2 (TP2) on the bottom of the
board below the RF PA shield.
A low-pass filter comprised of filter L202, L203, C204, C205 and C208 removes harmonics from the transmitter
output before applying the RF signal to the antenna. Two PIN diodes CR101 and CR201 along with associated
components form the antenna switching circuit. When transmitting both pin diodes are turned on. CR101 shunts
transmitting power to ground at the receiver input to prevent receiver overload. With the DTX-445 in receive mode no
voltage is applied to the PIN diodes and they do not conduct. This opens CR201 to prevent the transmitter amplifier
from affecting the receiver tuning. Incoming signals from the antenna pass through L101 to the receiver front end.
The dual colored LED will shine red when transmitting. If the transmit synthesizer does not lock the red LED will
flash on and off. The transmitter also exhibits good efficiency. The following table shows typical DTX-445 transmitter
and receiver performance when set to 10 watts.
Voltage
(Volts)
10
11
12
13
14
15
16
17
Power
(Watts)
4.75
6.25
7.6
8.5
9.3
10
10
10
10
Current
(Amps)
1.23
1.42
1.61
1.61
1.65
1.66
1.66
1.63
1.62
Efficiency
(%)
42.9
44.0
42.9
43.9
43.3
43.0
40.1
38.3
36.3
RX
current
(mA)
26
23.8
22.2
20.6
19.5
18.5
17.4
16.8
16.1
16
MICROCONTROLLER
The DTX-445 transceiver is electronically controlled by U301, an 8-bit flash programmable microcontroller. U301
has A/D inputs and PWM outputs for processing analog signals. Radio characteristics are stored in internal EE
memory. Its RS232 port is used in programming the radio’s personal characteristics such as frequencies and tones.
PIN
10
11
12
13
14
15
DESCRIPTION
Input is pulled LOW when the PTT input is grounded to initiate transmitter operation.
Input is pulled low when high/low power input is grounded. This produces a low RF output power.
GROUND
+3.3 VDC VCC supply voltage.
GROUND
+3.3 VDC VCC supply voltage
OSC1 is 14.4 MHz reference input from Y301.
Output goes high when audio PA is enabled.
Output SCL4 data line for controlling frequency and power e-pot.
Output drops low momentarily to produce synthesizer latch enable (LE) pulses.
Output goes low to enable receiver (/RXEN).
Output SCL3 data line for controlling AUX_IN and AUX_OUT gain e-pot.
TONE OUT generates the QC (CTCSS) or DQC (DCS) waveforms via an 8 bit PWM in transmit mode.
Output SCL2 data line for controlling DEVIATION and BALANCE e-pot.
DATA output sends serial data to frequency synthesizer U401 to program frequency information. Also used for
flash programming (MOSI)
16
CLK output sends serial data clock pulses to frequency synthesizer. Also used in flash programming (MISO).
17
Connects to pin 6 of J401. Grounding this defeats synthesizer unlock reloading for diagnosis.
Also outputs SCL1 data line for controlling NOISE and RSSI squelch e-pot.
18
AVCC gets +3.3 VDC for A/D convertors.
19
Input used to measure receiver RSSI.
20
AREF supplies the reference level for the A/D and is connected to the regulated +3.3 VDC.
21
AGND supplies A/D ground.
22
Input is normally low when PLL is locked.
23
Input is pulled low when the CS2 frequency bit input is tied to ground.
24
Input is pulled low when CS0 channel select bit is pulled low.
25
Output goes low to enable transmitter (/TXEN).
26
Input is pulled low when CS1 channel select bit is pulled low.
27
CTCSS IN is an A/D input decoding the CTCSS or DCS waveform.
28
Input is pulled low when radio is commanded to MONITOR channel.
29
RESET is held low to start the radio in a known state on power up.
30, 31 SERIAL DATA PORT links the microcontroller to communications from an external data terminal via
programming port pin 9 of J301. This allows programming of the DTX-445 EE memory used to store channel
frequency and configuration information.
32
CARDET gets pulled low when a RF carrier is detected.
17
DTX-445 ALIGNMENT PROCEDURE
Only an authorized RF service technician should perform test and alignment of the DTX-445. The unit is PC adjusted.
The factory has already adjusted C207 for RF power balance. Replacing the power FET or succeeding components
may require C207 to be readjusted.
RECOMMENDED TEST EQUIPMENT
1)
12.5 to 14 VDC 2 Amp current-limited power supply
3)
Oscilloscope
2)
RF Communications Test with:
- FM Deviation Meter
- RF Wattmeter
- Frequency Counter
- SINAD Measuring Device
4)
Sine wave generator around 800 Hz
5)
RITRON PC Programming Kit
RADIO PREPARATION
2)
3)
4)
5)
Connect the FM communications test set to the antenna connector.
Connect RITRON programming cable to radio and PC.
Apply 12.5 to 14 VDC to the red wire with the black to ground.
Run RITRON DTX software and read the radio.
RADIO ADJUSTMENT
The DTX-445 is preset at the factory for 8 Watts (or 5 watts) in high power and around 2 watts in low power at 12.5
VDC. The programming software includes help comments. If DTX needs to be changed or readjusted do the following:
1)
2)
3)
4)
5)
6)
7)
8)
9)
10)
11)
12)
13)
14)
15)
16)
17)
18)
Make sure that the unit is at room temperature and voltage between pin 6 and pin 15 is at least 12.5 VDC while
transmitting. There may be significant resistive losses causing voltage drop in the supply cable.
Set the RF communications test set to the transmit mode. Make sure equipment is calibrated including coax cable
and adapters. Note that a 1 dB cable loss will yield a 20% power loss.
Make sure the Hi/low power pin 5 is unconnected. This selects high power.
Run RITRON DTX LS programming software.
On the menu bar select Edit then Tune radio.
If starting from scratch, set up the radio in the order the buttons appear from top to bottom on the left: Frequency,
Mod Balance, Deviation, Power then User Set Up. Otherwise, adjust what is needed.
Click Frequency then Tune.
The frequency used in adjustment is displayed in the upper right corner.
Radio will transmit in center of band (460 MHz for DTX-445 O band). Adjust frequency by clicking arrows or by click
in space to right of sliding button (for up) or space left (for down). Button can also be dragged to position.
Adjusted transmitter frequency error should be less than +/-100 Hz. Click Save when done.
Adjust positive and negative corrections in the same way. This calibrates the reference oscillator.
If the reference oscillator ages and drifts in the future, only the center frequency should need trimming.
Apply an 800 Hz sine wave at sufficient level to AUX_IN input (pin 7). We want the sine wave to limit and appear as
a square wave when demodulated by the service monitor.
Click Mod Bal then Tune and adjust for flat top on square wave. Repeat for balance high frequency.
Click Deviation then Tune and adjust for +/- 5 kHz. Repeat for deviation high frequency.*
Click Power. Notice that low and high power can be set globally or on specific channels. The factory preset is global
with high power set at 8 watts (or 5 watts) for high and 2 watts for low at 460 MHz. The lower and upper power may
vary a bit. Variable cap C207 (seen in the hole in the PA shield) can be used to balance low to high frequency
power. Also, channel specific low high power settings can be programmed on channels 1 through 8.
Make your choice of what you want to adjust and adjust it. Keep in mind when you adjust low or high power in the
“all channels” section you write that same setting in all channels.
Click User Set Up. Here, you can adjust NOISE and RSSI squelch levels and AUX_IN and AUX_OUT gain. If both
RSSI and NOISE squelch are used simultaneously, the RSSI level must be set first with the NOISE squelch
disabled. Disable it by adjusting the level so high that the RF level never reaches it. The NOISE and RSSI squelch
levels work as an OR function. With either level exceeded, the audio will turn on. Set the RSSI level around -106
dBm and then the NOISE level around -120 dBm.** When adjusting AUX_IN level apply your desired signal level to
pin 7. The unit was factory preset with a 300 mVpp sine wave adjusted for +/- 3 kHz deviation. This same level will
produce +/- 1.5 kHz on a narrowband channel.
18
19) Remember to save all settings when tuning is finished.
NOTES:
*Sub audible tone deviation is automatically set to be within 600 to 900 Hz after this adjustment on wide band
channels. Maximum voice and tone deviation on wide band channels will then be 4800 to 5300 Hz. Narrow band tone
deviation will be 350 to 500 Hz with overall deviation of 2400 to 2650 Hz.
**The DTX-445 is capable of two squelch operating modes. Both can operate simultaneously. See the FM
Receiver Subsystem section for theory. The units can be configured as the user requires. When a low level signal
appears, the noise squelch opens when the carrier is –119 dBm or greater. When the signal appearing is –106 dBm or
greater the RSSI squelch opens the audio with an even faster attack time. The above levels are factory set levels.
Ambient noise will affect the level at which the RSSI should be set. The squelch level ideally should be set on the
desired frequency, in the actual location the radio will be used and connected to the desired antenna. The level should
be set high enough to reject most false signals. The squelch levels are the same for all channels.
If a very fast receiver decay time (or squelching after signal disappears) is needed the noise squelch should be
defeated by setting it to a high level.
19

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