RU2474964C1 - Hf-vhf radio stations test bench - Google Patents

Abstract

FIELD: radio engineering.

SUBSTANCE: invention can be used for testing radio stations of short-wave (HF) and ultra-short wave (VHF) ranges. HF-VHF radio station bench test consists of a dot-and-dash code sensor including a keyboard, and electronic unit and headphones, telephone radio channel quality evaluation unit including a telephone test signal sensor, a telephone test signal receiver and a counter of number of errors in the communication channel, a telegraph sensor including a device for shaping the transmitting combination of telegraph signal and analysing the received combination of telegraph signal, typesetter of transmitting combination of telegraph signal and device for processing, analysing and displaying the received combination of telegraph signal, switch of low-frequency (LF) channels, radio modem, receiving test radio circuit, which includes the first and the second receiving antennae, the first high-frequency (HF) switch, attenuator, signal separation unit, radio receiver of the tested channel (TC), radio receiver of reference channel (RC) of single reception and radio receiver of RC of double reception, which transmits the test radio circuit including TC radio transmitter, RC radio transmitter, the second HF switch, transmitting short-wave (HF) antenna and transmitting ultra-short wave (VHF) antenna.

EFFECT: improvement of characteristics of developed means of HF and VHF radio communication by means of integral evaluation of communication channel quality; reduction of development and manufacture time of new radio stations.

1 dwg

Description

The invention relates to radio engineering, in particular to radio communication systems, and can be used to test short-wave (KB) and ultra-short-wave (VHF) radio stations.

Known radio communication devices of various wavelengths (LW, KB and VHF), which are increasingly used to provide radio communications in the interests of various ministries and departments. At the same time, to ensure high-quality radio communications using these tools, tests are carried out by checking their tactical and technical characteristics for compliance with specified requirements.

The tactical and technical characteristics of HF-VHF radio stations are usually checked during preliminary (factory) and state tests, and laboratory measuring devices are used to measure individual parameters of radio stations. However, they do not provide an integrated assessment of the quality of KB or VHF radio communications, taking into account the medium of propagation of radio waves. The organization of such tests requires significant material and financial costs. Upon receipt of negative results, the radio stations are finalized and then repeated tests of the indicated radio facilities are carried out, which additionally requires material and financial resources.

The question of testing KB radio facilities is particularly acute, since the characteristics of the channels they form due to a sharp change in the propagation parameters of radio waves in this range are unstable.

If there are stands similar to the proposed one, the technical characteristics of the developed KB and VHF radio stations for compliance with the specified requirements are checked with their help, which helps to eliminate repeated tests and, accordingly, reduces costs.

The aim of the invention is to reduce the development time of radio stations by providing an integrated assessment of the quality of the characteristics of the measured channels KB and VHF radio stations in the face of a sharp change in the parameters of the medium of propagation of radio waves.

This goal is achieved in that the test bench for HF-VHF radio stations consists of a Morse code sensor, which includes a keyboard, electronic unit and head phones connected in series, a telephone radio channel quality assessment unit, including a telephone test signal sensor, and a telephone test receiver -signal and counter of the number of errors in the communication channel, telegraph sensor, including a device for generating transmitting and analysis of the received combination of telegraph signal, dialing device for transmitting telegraph signal combinations and a device for processing, analyzing and displaying the received telegraph signal combination, low-frequency (LF) channel switch, radio modem, receiving test radio path including the first and second receiving antennas, the first high-frequency (HF) switch, attenuator, signal separation unit, the radio channel of the tested channel (IR), the radio channel of the reference channel (OK) of single reception and the radio receiver OK of dual reception, transmitting a test radio path, including a radio IR transmitter, OK radio transmitter, second RF switch, transmitting short-wave (KB) antenna and transmitting ultra-short-wave (VHF) antenna, while the input-output of the electronic block of the Morse code sensor is connected to the first input-output of the low-frequency channel switch, the output of the telephone test signal sensor at the junction C1-I is connected to the first input of the switch of the low-frequency channels, the first output of which is connected to the input of the receiver of the telephone test signal, the output of which is connected to the input of the counter of the number of errors in the radio channel, analog input-output by radio the dema is connected to the second input-output of the low-frequency channel switch, the third input-output of which is connected to the digital input-output of the radio modem, the fourth input-output of the low-frequency channel switch at the junction C1-TG is connected to the input-output of the device for generating and analyzing the received telegraph signal combination telegraph sensor, the input of which at the junction of C1-TG is connected to the output of the dialing device of the transmitting combination of the telegraph signal, and the input of the device for processing, analyzing and displaying the received combination of the telegraph signal at the junction C1-TG is connected to the output of the device for transmitting and analyzing the received combination of the telegraph signal, the first output of the IR radio at the junction C1-I is connected to the second input of the low-frequency channel switch, the third input of which at the junction C1-TG is connected to the second output of the IR radio, the first output of the single-reception OK radio receiver at the C1-TG junction is connected to the fourth input of the low-frequency channel switch, the radio modem input at the C1-TG interface is connected to the second output of the single-reception OK radio receiver, the first and second inputs of which are sub are connected respectively to the first and second outputs of the dual reception OK radio receiver, the outputs of the first and second receiving antennas are connected respectively to the first and second high-frequency inputs of the first RF switch, the first and second high-frequency outputs of which are connected to the inputs of the attenuator and the dual reception OK radio receiver respectively, the attenuator output is connected with the input of the signal separation unit, the first and second outputs of which are connected respectively to the input of the IR radio receiver and to the third input of the radio receiver OK for single reception, the second output of the LF channel switch at the C1-TG junction is connected to the first input of the IR radio transmitter, the second input of which at the C1-TG junction is connected to the third output of the LF channel switch, the fourth output of which at the C1-TG junction is connected to the first input of the radio transmitter OK, the outputs of the IR transmitter and the OK transmitter are connected respectively to the first and second inputs of the second RF switch, the first and second outputs of which are connected to the inputs of the transmitting KB antenna and the transmitting VHF antenna, respectively.

A comparative analysis with the available technical solutions showed that in the proposed test bench for HF-VHF radio stations, a new set of elements was obtained, which is unknown in the patent and technical literature at the time of filing the application for the invention.

Thus, the inventive stand for testing HF-VHF radio stations meets the criteria of the invention of "novelty." Comparison of the proposed solution with other technical solutions shows that the resulting set contributes to the manifestation of new properties of the device, reduces the time spent on developing radio stations and improves the quality of the characteristics of the measured channels KB and VHF radio stations under conditions of a sharp change in the parameters of the medium of propagation of radio waves, providing the opportunity to choose the best characteristics and development on their basis of promising radio stations that meet modern requirements. This allows us to conclude that the technical solution meets the criterion of "significant differences".

This solution is significantly different from the known solutions in the art, does not explicitly follow from the prior art and has an inventive step. In addition, it is industrially applicable, which is confirmed by the development of documentation for this device, the manufacture of the stand and its testing.

The drawing shows a structural electrical diagram of the stand for testing HF-VHF radio stations.

The test bench for HF-VHF radio stations consists of a Morse code sensor 1, which includes a keyboard 2, an electronic unit 3 and head phones 4, a telephone radio channel quality assessment unit 5, which includes a telephone test signal sensor 6, a telephone test receiver 7 the signal and the counter of the number of errors in the radio communication channel, telegraph sensor 9, including a device 10 for generating a transmitting and analyzing a received combination of telegraph signal, a dial-up device 11 for transmitting a combination of telegraph signal and a device 12 Operation, analysis and display of the received combination of telegraph signal; switch 13 low-frequency channels, radio modem 14, receiving test radio path 15, which includes the first 16 and second 17 receiving antennas, the first high-frequency switch 18, attenuator 19, the signal separation unit 20, the IR receiver 21, the radio receiver 22 OK single reception and the radio 23 OK dual reception, transmitting a test radio path 24, including an IR transmitter 25, an OK transmitter 26, a second RF switch 27, a KB transmitting antenna 28, and a VHF transmitting antenna 29.

The output of the keyboard 2 of the sensor 1 of the Morse code is connected to the input of the electronic unit 3, the output of which is connected to the input of the headphones 4. The input-output of the electronic unit 3 is connected to the first input-output of the switch 13 low-frequency channels. The output of the sensor 6 of the telephone test signal of the telephone radio channel quality assessment unit 5 at the junction C1-I made in accordance with GOST 27832-87 is connected to the first input of the switch 13 low-frequency channels, the first output of which is connected to the input of the receiver 7 of the telephone test signal the output of which is connected to the input of the counter 8 of the number of errors in the communication channel.

The second input-output of the switch 13 LF channels at the junction C1-TG is connected to the input-output of the device 10 for transmitting and analyzing the received combination of the telegraph signal of the telegraph sensor 9, the input of which at the junction C1-TG is connected to the output of the dialing device 11 of the transmitting combination, and the input the device 12 for processing, analyzing and displaying the received combination at the junction C1-TG is connected to the output of the device 10 for transmitting and analyzing the received combination of the telegraph signal.

The analog input-output of the radio modem 14 is connected to the third input-output of the switch 13 low-frequency channels, the fourth input-output of which is connected to a discrete input-output of the radio modem 14.

The high-frequency outputs of the first 16 and second 17 receiving antennas of the receiving test radio path 15 are connected respectively to the first and second high-frequency inputs of the first high-frequency switch 18, the first and second high-frequency outputs of which are connected to the inputs of the attenuator 19 and the dual-reception radio receiver 23 OK, respectively. The output of the attenuator 19 is connected to the input of the signal separation unit 20, the first and second outputs of which are connected to the inputs of the IR receiver 21 and the receiver 22 OK, respectively. The first output of the IR receiver 21 at the C1-I junction is connected to the second input of the LF channel switch 13, the third input of which at the C1-TG junction is connected to the second output of the IR receiver 21.

The first output of the radio receiver 22 OK single reception at the junction C1-TG is connected to the fourth input of the switch 13 LF channels, the input of the radio modem 14 at the junction C1-TCH is connected to the second output of the radio receiver 22 OK the single reception, the first and second inputs of which are connected respectively to the first and second the outputs of the radio 23 OK dual reception.

The second output of the switch 13 LF channels at the junction of C1-TG is connected to the first input of the radio transmitter 25 of the IR transmitting test radio path 24, the second input of which at the junction of C1-TG is connected to the third output of the switch 13 of the LF channels, the fourth output of which at the junction of C1-TG is connected to the first input of the radio transmitter 26 OK. The outputs of the IR transmitter 25 and the OK transmitter 26 are connected respectively to the first and second inputs of the second RF switch 27, the first and second outputs of which are connected to the inputs of the transmitting KB antenna 28 and the transmitting VHF antenna 29, respectively.

The Morse code sensor 1 as part of the keyboard 2, electronic unit 3 and headphones 4 is designed to generate, transmit and receive codograms when organizing auditory radio communications via KB radio channels.

Sensor 1 provides the transmission of alphabetic and digital texts with a Morse code with an information transfer rate of 10 to 40 groups / min, the uniformity of the transmitted dashes, dots, and the intervals between them within the sign and the tonal control of the transmitted characters using headphones 4.

Unit 5 for assessing the quality of the telephone radio channel as part of the sensor 6 and receiver 7 of the telephone test signal and counter 8 for the number of errors in the communication channel is used to generate a telephone test signal, exchange information on the tested channels KB and VHF radio stations and calculate the number of errors in the communication channel with light indication of the result of quality assessment.

As block 5 can be used commercially available equipment type AT-3029. It is designed to calculate errors when transmitting discrete information over communication channels and for use as a simulator of a binary symmetric channel. The AT-3029 equipment provides:

transmitting and receiving “points”, “zeros”, “ones”, binary sequence recursors with a maximum capacity of 2 ⁴ - 1, 2 ⁹ - 1, 2 ¹⁵ - 1 bit;

transmission and reception of test signals at speeds of 100, 300, 600, 1200, 2400, 4800, 9600, 16000, 32000, 48000 bit / s;

counting the number of distorted characters in the test signal using the built-in counter for measurement sessions of 10 ³ , 10 ⁴ , 10 ⁵ , 10 ⁶ , 10 ⁷ clock periods and displaying them on digital indicators;

counting the number of measurement sessions.

The telegraph sensor 9 as part of a device 10 for transmitting and analyzing a received combination of a telegraph signal, a dialing device 11 for a transmitting combination and a device 12 for processing, analyzing and displaying a received combination is designed to test radio channels when organizing direct-printing telegraph communication by transmitting, receiving and analyzing received telegraph information on KB radio channel. It provides the transmission of one telegraph information stream at speeds of 50, 100, 150, 200, 300, 500, 600, 1000, 1200, 2400, 4800, 9600 bit / s, broadcasts to the radio channel at the junction of C1-TG and receives combinations from the radio channel and signals "push", "click", "point" and various recurrences (from 7 to 511 characters).

The switch 13 low-frequency channels is designed for connecting and switching low-frequency circuits, as well as for switching low-frequency signals depending on the types and modes of operation from terminal devices, transmitting and receiving paths, pairing signal levels of various devices.

The LF channel switch provides the connection of all low-frequency circuits from all elements of the stand and their switching when switching the operating modes of the stand from the test to the reference channel and vice versa, and also provides oscillographic control of all circuits.

The radio modem 14 is designed to convert analog signals from terminal devices into tonal frequency signals in the range of 0.3-3.4 kHz, transmit and receive them over the radio channel KB of the radio station.

The radio modem 14 is designed to transmit binary information via a KB radio channel. It provides the transmission of one discrete information stream with speeds of 1200, 2400 bit / s, or two asynchronous streams with a speed of 1200 bit / s each when pairing at the C1-I interface, the exchange of official formalized commands between the operators serving the device, work in the channel band of the PM from 300 to 3400 Hz, channel output on a symmetrical connecting line with a resistance of 600 ± 100 Ohms and a maximum attenuation not exceeding 15 dB, operation in single and dual reception modes on spatial or frequency diversity channels Applying correcting encoding by the method of Wagner at speeds of 1200 and 2400 bit / s.

The first receiving antenna 16 of the receiving test radio path 15 is designed to receive radio signals in the wavelength range from 1.5 to 30 MHz. It is an antenna of the type vertical inclined dipole and contains two beams with a length of 20 meters each. The antenna beams are made of copper stranded antenna wire, section 7 mm. The antenna is suspended on a telescopic mast at a height of 9 meters.

The second receiving antenna 17 is a whip antenna of the ASh-4 type (a four-meter whip antenna) placed on a telescopic mast 12 meters high. It is designed to receive radio signals in the wavelength range from 1.5 to 80 MHz over a radio link with an increased communication range in dual reception mode.

The first RF switch 18 is intended for switching the first 16 and second 17 receiving antennas to the input of the attenuator 19 and issuing RF signals to the input of the dual reception OK 23 radio receiver. It is made in a shielded case using coaxial cables and RF switches.

The attenuator 19 is designed to introduce additional (up to 60 dB) attenuation into the receiving path for the purpose of artificially degrading the reception quality in the course of ongoing radio path tests.

Block 20 separation of signals is designed to connect the output of the first 16 or second 17 antennas to the inputs of two radios: radio 21 IR or radio 22 OK.

The general principles for constructing radio receivers used in the proposed stand for testing HF-VHF radio stations are described in a number of well-known sources [1, 2].

The IR 21 radio receiver is a radio receiver based on digital signal processing and the use of control processors. It can contain an antenna switch, a main selection filter, a main radio receiver path consisting of four receiving paths, a reference generator block, a vector sample block, a program interface block, and a control block.

The IR 21 radio receiver provides four-channel reception for each of the four antenna inputs (if there are four antennas, respectively), the organization of one to four receiving radio channels in compatibility mode with the radio receivers of the old park, spatial diversity reception with automatic interference compensation, digital signal processing and demodulation, signal generation for terminal equipment (terminal devices) of telephone and telegraph communication, as well as the ability to broadcast four information streams channel layer at the junction of 100 Base-TX.

The single-receive radio OK 22 includes a block of input circuits, a preselector, a main receiver path, a frequency synthesizer, a demodulator of telephone signals, a telegraph signal demodulator, a first block of output circuits and a second block of output circuits.

The dual reception OK 23 radio receiver comprises an input circuit block, a preselector, a receiver main path, a frequency synthesizer, a telegraph signal demodulator and a telephone signal demodulator.

As radio receivers 22 and 23, an automated radio receiver device of the R-170P type can be used, which contains a main reception path, a telephone and telegraph signal processing path, a frequency synthesis system, and a control and monitoring system. The processing line of telephone and telegraph signals includes a demodulator of telephone signals, a demodulator of telegraph signals and a demodulator of digital channels [3].

The R-170P radio receiver is designed to receive signals in the LW, KB, and VHF frequency bands when operating as part of similar radio facilities and on the main radio links. The antenna input of the receiver is designed to work with antennas ending with a coaxial cable with a wave impedance of 75 Ohms or in the KB range with a balanced cable with a wave impedance of 200 Ohms.

RPU contains the following main systems: the main reception path, the processing path of telephone and telegraph signals, a frequency synthesis system and a control and monitoring system.

In the main reception path, the signal from the output of the protection element is fed to the input of the preselector, which is designed to provide the required selectivity of the RPU along the mirror channel, along the first intermediate frequency and along the secondary reception channels.

Frequency conversion is carried out on two mixers. On the first mixer, the signals are converted to the first intermediate frequency, and on the second mixer, the first intermediate frequencies are converted using the second local oscillators to the second IF. The received information is sent to the terminal devices from the outputs of the demodulators.

Each of the IR transmitters 25 and 26 OK transmitting the test path 24 consists of a modulator, pathogens and power amplifier. The modulator modulates using low-frequency signals from terminal devices: Morse code sensor 1, unit 5 for assessing the quality of the telephone radio channel and telegraph sensor 9.

The signal from the output of the modulator after selection and correction of distortion is fed to pathogens. Using a crystal oscillator and a multiplier, a predetermined frequency with the required signal level is formed in the exciter. The power amplifier amplifies signals in a wide range of frequencies, including preset frequencies KB and VHF wave range.

The power amplifier is a broadband power amplifier made in the form of several amplification stages covered by feedback, providing the ability to control the output power modes (full and low power, tuning mode). It provides the formation of high-frequency oscillations (KB and VHF wave range) and their amplification to the required level in the transmission mode, the subsequent transmission of radio signals to antennas 28 and 29 for their radiation.

The proposed stand provides for the operation of radio transmitters with an output power of 1 kW. At the same time, the radio transmitters 25 and 26 provide for the possibility of adjusting the output power and operation using four gradations of the output power (25, 50, 75 and 100%), which are used when testing radio facilities for different communication ranges.

IR transmitter 25 is a radio transmitter based on digital signal conditioning and the use of control processors. It provides the transmission of information to the consumer in digital form, the organization of one to four transmitting radio channels, the work with terminal equipment (terminal devices) of telephone and telegraph communication with the receipt of digital information from it and the subsequent generation of a signal for a power amplifier of various classes of radiation, the main ones which are: auditory amplitude telegraphy, automatic two-channel frequency telegraphy with speeds of 150, 300 and 500 bit / s, automatic relative phase difference tele raffia with speeds of 50, 100, 300 and 500 bps, auditory single-band telephony and two-way telephony with two frequency bands 300-3400 Hz, auditory frequency telephony with the main carrier frequency and the output signal bandwidth from 300 to 3400 Hz and frequency deviation 5, 6 kHz.

As a radio transmitter 26 OK, radio transmitting devices of the R-161MB-1 and R-167M type can be used.

The R-161 MB-1 KB radio transmitter is designed to operate on stationary radio centers in the frequency range 1.5-30 MHz on radio links with a reflected wave of up to 2000 km and an earth wave of up to 70 km. This device provides information transfer with the following classes of radiation: auditory amplitude telegraphy and automatic single-channel frequency telegraphy at speeds of 50, 75, 100, 150, 300 and 500 bit / s, single-band and two-band telephony [4].

The R-167M radio transmission device is designed to operate in the VHF band on terrestrial radio waves up to 150 km and meteor communication radio links up to 1000 km. This device provides information transfer with radiation classes: auditory amplitude telegraphy, automatic single and two-channel frequency telegraphy with speeds of 50, 75, 100, 150, 300 and 500 bit / s, single-band and two-band telephony [5].

The second RF switch 27 is designed to switch the signals from the outputs of the IR transmitter 25 and the OK transmitter 26 to the inputs of the transmitting KB antenna 28 and the transmitting VHF antenna 29, respectively. It is made in a shielded case using coaxial cables and RF switches. Switching the output circuits of the transmitters is carried out manually using the rotary lever.

The KB transmit antenna 28 is a vertical oblique dipole and contains two beams of 13 meters each. The beams are made of copper stranded antenna wire, section 7 mm. The antenna is suspended on a mast 9 m high. The antenna is designed to provide alternate operation of 25 IR and 26 OK transmitters when transmitting messages during testing.

As the VHF transmitting antenna 29, whip antennas of the ASh-4 or ASh-10 type (ten-meter whip antenna) placed on a telescopic mast of various heights can be used.

The proposed stand provides the following types of work during testing of KB and VHF radio stations:

1) a hearing phone;

2) telephone communication in digital mode;

3) direct-printing telegraph.

At the same time, the following main operating modes of radio stations are provided in the stand:

1) reception and transmission for all types of work;

2) simplex;

3) two-frequency simplex;

4) duplex in the organization of telephone communications in digital mode.

The proposed stand is designed for route testing of developed and / or serial means of KB and VHF radio communications on KB radio paths with a length of up to 800 km by a spatial wave and on VHF radio paths with a length of up to 150 km by an earth wave or on VHF meteor radio links with a length of up to 1000 km.

At the same time, the stand provides:

transmission, reception and registration on the Morse code sensor of the received information of auditory wireless telegraphy (“hearing phone” or “hearing wireless telegraphy” mode);

transmission, reception, registration and analysis of messages (test) by telephone for various classes of radiation;

transmission, reception, registration and analysis of messages (test) in telegraph mode for various classes of radiation in the KB frequency range from 1.5 to 30 MHz;

transmission, reception, registration and analysis of messages (test) in the same operating modes and radiation classes in the VHF range from 20 to 80 MHz;

alternately connecting to the transmitting and receiving antennas the radio and radio transmitting devices of the test and reference channels;

alternately connecting to the inputs of the pathogens and the outputs of the receivers of the test and reference channels simulators of terminal equipment for telephone and telegraph communications, as well as equipment for auditory reception and transmission;

visual oscillographic control of transmitted and received messages (test) at any point of the LF path;

interfacing the RF junctions of radio receivers and radio transmitting devices for the operation of digital equipment with a C1-I junction using a radio modem over a single-band radio channel with information transfer rates of 1200/2400 bit / s;

switching through the HF switch of one of two radio transmitting devices (IR transmitter 25 or 26 OK transmitter) to transmit antennas KB and VHF;

connecting through the block 20 separation of signals to the first receiving antenna of one of the two radios (radio 21 IR or radio 22 OK);

the introduction of additional attenuation (up to 60 dB) into the tract using an attenuator 19.

The work of the proposed stand is based on the use of a comparative test method, the essence of which is as follows.

Initially, for all provided types and operating modes, using a set of source data, information is transmitted over the reference channel. Then, without changing the test conditions and the data set used, information is transmitted through the test channel.

In the process of transmitting information, the voltage and signal level are monitored at selected points in the information path using an external oscilloscope, built-in measuring instruments, and the channel quality is evaluated at the reception.

Evaluation of the quality of the communication channel for the operating mode “auditory telephone” (auditory radio telegraphy) is carried out by receiving information by ear using headphones 4 sensors 1 Morse code or using a mic phone headset connected to the output of the LF channel of the radio receivers (21 IR radios, 22 OK single reception or 23 OK double reception).

The quality of the channel when checking telephone communications in digital mode is evaluated by analyzing the information received by the receiver 7 of block 5 and counting the number of errors by counter 8. The number of distorted pulses (characters) is calculated and the result is displayed on digital indicators.

The main principles of testing HF-VHF radio stations, with the help of which radio lines are organized using the proposed stand, are as follows.

Tests are carried out using the comparative method. At the same time, tests of the channels of new equipment (new radio stations) are carried out jointly with the “reference channel”, which is used as existing or modernized equipment or equipment for which there is operational experience.

Tests are conducted at two to three capacities to determine the energy ratios of the compared radio links.

The essence of the method, which has been repeatedly used in practice, is that instead of fully implementing the equipment of all the compared options, the minimum necessary set of test signals is transmitted and the output signals of demodulators and signal and noise level measuring devices are recorded, while the parameters of the test signals (method and speed of manipulation , radiation duration, principles of choosing and changing the operating frequency, etc.) correspond to the parameters of the studied radio lines. The registered information is used further as initial data to select the required characteristics of functional units (preselector, etc.) to improve the developed or upgraded KB and VHF radio stations.

The stand is designed to test the operation of the test radio channel and compare the reception quality on this channel with the reception quality of the reference channel.

At the same time, in the receiving path, the high-frequency signal of the KB range from the output of the first 16 or second 17 receiving antennas via a coaxial cable through the high-frequency connector of the first RF switch 18 of the stand enters the receiving test radio path 15, where it is amplified, double frequency converted, and detected, as a result of which it turns out a low-frequency (LF) signal. The low-frequency signal is fed to the corresponding circuit of the switch 13 low-frequency channels for supply to various types of terminal devices: Morse code sensor 1, telephone radio channel quality assessment unit 5 and telegraph sensor 9.

When organizing a radio channel for transmitting / receiving information through it in the “auditory telephone” mode, it is carried out along a path that includes the input-output of the electronic unit 3 of the Morse code sensor 1, a switch 13 of low-frequency channels, a receive test radio path 15, and a transmitting radio test path 24.

When transmitting the signal from the output of the keyboard 2 through the electronic unit 3 of the sensor 1 Morse code is fed to the input of the switch 13 low-frequency channels. On the switch 13 low-frequency channels, the mode switch is set to the position “HEAR”.

From the output of the switch 13 low-frequency channels, the signal is fed to the input of the IR transmitter 25, which converts the codogram typed on the keyboard 2 into a high-frequency (HF) signal. The RF signal through the second RF switch 27 is fed to the input of the transmitting KB antenna 28 and is radiated by it.

Reception of signals in the auditory telephone mode (“auditory telephone” or “auditory radio telegraphy” mode) is carried out along the path including: the first receiving antenna 16 (the antennas are switched on the first high-frequency switch 18), the first high-frequency switch 18, attenuator 19, separation unit 20 signals, then a radio receiver 21 IR or a radio receiver 22 OK single reception, switch 13 low-frequency channels, electronic unit 3 and headphones 4 sensor 1 Morse code.

The organization of the radio channel to ensure the transmission / reception of information in digital telephone communication is carried out along the path, including: unit 5 for assessing the quality of the telephone radio channel, switch 13 low-frequency channels, radio modem 14, receive test radio path 15 and transmit test radio path 24.

When transmitting, the signal from the output of the sensor 6 of the telephone test signal is fed to the input of the switch 13 low-frequency channels. From the output of the switch 13 low-frequency channels, the signal is fed to the input of the IR transmitter 25, which converts the telephone test signal dialed on the sensor 6 into a high-frequency signal. The RF signal through the second RF switch 27 is fed to the input of the transmitting KB antenna 28 and is radiated by it.

The telephone test signal in KB mode is received from the KB channel via a path including: the first receiving antenna 16 (the antennas are switched on the first RF switch 18), the first RF switch 18, the attenuator 19, the signal separation unit 20, and then the IR receiver 21 or a single reception OK radio receiver 22, a radio modem 14, a low-frequency channel switch 13, a telephone test signal receiver 7, a received test signal analyzer and an error count 8 in the communication channel of the telephone radio channel quality assessment unit 5.

The organization of the radio channel to ensure the transmission / reception of direct-printing telegraph information is carried out along the path, including: telegraph sensor 9, switch 13 low-frequency channels, receive test radio path 15 and transmit test radio path 24.

When transmitting information, the signal from the output of the dialing device 11 of the transmitting combination of the telegraph signal of the telegraph sensor 9 is fed to the input of the device 10 for generating the transmitting and analyzing the received combination of the telegraph signal, from the output of the device 10 the signals of the transmitting combination through the switch 13 of the low-frequency channels are fed to the modulating input of the radio transmitter 25 or 26 transmission test path 24. From the output of the radio transmitter 25 or 26, high-frequency oscillations through the second switch 27 are fed to the input of the transmitting KB antenna 28 and are being radiated by it.

Reception of the telegraph information radio channel from KB is carried out along the path including: the first receiving antenna 16 (the antennas are switched on the first high-frequency switch 18), the first high-frequency switch 18, the attenuator 19, the signal separation unit 20, then the infrared receiver 21 or the single-receive radio OK 22 , a switch 13 of the low-frequency channels, a device 10 for transmitting and analyzing a received combination of a telegraph signal and a device 12 for processing, analyzing and displaying a received combination of a telegraph signal.

The process of transmitting and receiving test signals along the reference and test channels is repeated many times. In this case, the number of communication sessions is counted and statistics are collected on the number of errors (distortion of pulses, symbols) in the test channel. Based on the results using well-known techniques, the reliability of the reception is calculated.

In dual reception mode, the stand operates as follows.

In this mode, signals from the correspondent transmitter are received by the first 16 and second 17 receiving antennas. The signals received by the first receiving antenna 16, through the first RF switch 18, the attenuator 19, and the signal separation unit 20, are input to the radio receiver 22 OK single reception, and the signals received by the second receiving antenna 17, through the first RF switch 18 are fed to the input of the radio 23 OK the dual reception and from its output, the received test signals from the correspondent are transmitted to another input of the radio 22. The received signals in the radio 22 OK are added up and the signal of the total channel is removed from its output, which through the switch 13 Torr is supplied to the LF channel unit 5 estimates the radio channel quality and a telegraph transmitter 9. Blocks 5 and 9 analyze the received signals and perform count the number of errors in the received information showing the result of counting at the relevant indicators.

The volume (number of characters) of test information for each session to obtain statistics on the distribution of errors when working at a fixed frequency for low error probabilities is determined using known relations. In this case, the number of test sessions required to estimate the average probability of message delivery is also calculated.

Using the data obtained, proposals are developed to improve the functional units of KB and VHF radio facilities that are part of the radio path of the channel under test.

The technical effect of using the proposed stand for testing HF-VHF radio stations is to reduce the time to check the technical parameters of the developed KB and VHF radio stations and reduce the cost of their production and serial production.

In the course of the experimental design work, a mock of the proposed stand was made, its operability was tested, and tests of developed and mass-produced KB radio facilities in the frequency range from 1.5 to 30 MHz, as well as VHF radio facilities in the frequency range from 30 to 80 MHz, were tested.

The practice of the tests showed that the use of the proposed stand to verify the tactical and technical characteristics of KB and VHF radio stations made it possible to significantly reduce the test time and, accordingly, to shorten the development and manufacturing time of new KB and VHF radio stations.

The calculations showed that the use of the test bench for HF-VHF radio stations leads to a reduction of approximately 1, 5 times in the development and manufacture of KB and VHF radio stations in industry, and also contributed to the reduction of material and financial costs for the development of new radio stations.

Information sources

1. Golovin O. V., Prostov S. P. Systems and devices for short-wave radio communication / Ed. Professor O.V. Golovina. - M .: Hot line - Telecom, 2006.

2. Golubev V.N. Optimization of the main path for receiving a radio receiver. - M.: Radio and Communications, 1982.

3. Automated radio receiver R-170P. Technical description TSL2.003.143 TO, 1991.

4. Radio transmitting device R-161MB-1. Technical description of Nuclear Energy 1.600.047 TO, 1983.

5. Radio transmitting device R-167M. Technical description YaH 1.100.012 TO, 1990.

Claims (1)

Test bench for HF-VHF radio stations, consisting of a Morse code sensor, which includes a keyboard, electronic unit and head phones connected in series, a telephone radio channel quality assessment unit, including a telephone test signal sensor, a telephone test signal receiver and a number counter errors in the communication channel, the telegraph sensor, which includes a device for transmitting and analyzing the received combination of the telegraph signal, a dial-up device for transmitting the combination of the telegraph signal and a triple of processing, analysis and display of the received combination of the telegraph signal, the low-frequency (LF) channel switch, the radio modem, the receiving test radio path, which includes the first and second receiving antennas, the first high-frequency (HF) switch, attenuator, signal separation unit, the radio channel of the channel under test ( IR), a single-channel reference channel (OK) radio and a dual-reception OK receiver transmitting a test radio path including an IR transmitter, an OK transmitter, a WTO oh RF switch, transmitting a short-wave (KB) antenna and transmitting an ultra-short-wave (VHF) antenna, while the input-output of the electronic block of the Morse code sensor is connected to the first input-output of the low-frequency channel switch, the output of the telephone test signal sensor at the C1-I junction is connected with the first input of the LF channel switch, the first output of which is connected to the input of the telephone test signal receiver, the output of which is connected to the input of the counter of the number of errors in the radio channel, the analogue input-output of the radio modem is connected to the second input-output the house of the switch for low-frequency channels, the third input-output of which is connected to the digital input-output of the radio modem, the fourth input-output of the switch of low-frequency channels at the junction C1-TG is connected to the input-output of the device for generating and analyzing the received combination of the telegraph signal of the telegraph sensor, the input of which is the C1-TG joint is connected to the output of the dialing device of the transmitting telegraph signal combination, and the input of the processing, analysis and display device of the received telegraph signal combination at the C1-TG joint is connected to the output of the In order to create transmitting and analyze the received combination of telegraph signal, the first output of the IR radio at the C1-I junction is connected to the second input of the LF channel commutator, the third input of which at the C1-TG junction is connected to the second output of the IR radio receiver, the first output of the single-receive radio OK C1-TG is connected to the fourth input of the LF channel switch, the input of the radio modem at the junction of C1-TG is connected to the second output of the single-reception OK radio receiver, the first and second inputs of which are connected respectively to the first and each output of the OK receiver of dual reception, the outputs of the first and second receiving antennas are connected respectively to the first and second high-frequency inputs of the first RF switch, the first and second high-frequency outputs of which are connected to the inputs of the attenuator and radio of the OK dual reception, the output of the attenuator is connected to the input of the signal separation unit , the first and second outputs of which are connected respectively to the input of the infrared radio receiver and to the third input of the radio receiver OK single reception, the second output the LF channel switch at the C1-TG junction is connected to the first input of the IR radio transmitter, the second input of which at the C1-TG junction is connected to the third output of the LF channel switch, the fourth output of which at the C1-TG junction is connected to the first input of the OK radio transmitter, the outputs of the IR and OK transmitter are connected respectively to the first and second inputs of the second RF switch, the first and second outputs of which are connected to the inputs of the transmitting KB antenna and the transmitting VHF antenna, respectively.