SU1182547A1 - Device for simulating multichannel communication system - Google Patents

Abstract

A DEVICE FOR MODELING A MULTI-CHANNEL COMMUNICATION SYSTEM containing a clock generator, a time setting element, AND element, random sequence sensor and a pulse modulator time, the output of the clock generator is connected to the input time of the setting element and to the first input of the element, the second input of which is connected to output, home is the time of the master element, and the output with the control input is the time of the pulse modulator and the sensor input of a random sequence, the output of which is connected to the information input of the time a pulse modulator, rpyrlny noise generating channels. characterized in that, in order to increase the accuracy of modeling, it additionally contains an attenuator, an envelope former executed in the form of a filter on surface acoustic waves, a control attenuator, a switch, a digital-to-analog converter, a 1-cell formation unit fulfilled in the form of successively connected switches and a digital -analogue converter and series-connected noise generator, bandpass amplifier and controlled attenuator, a group of voltage sensors, and each channel The interference measurement consists of a master element time, a clock generator, an And element, a random sequence sensor, a pulse modulator time, a key, a filter on surface acoustic waves and a controlled attenuator, a memory unit and a digital-analog converter, and the clock pulse output . in each channel form oVA (L noise is connected to the first input from the element And through time the master element - to the second input of the element And, the output of which is connected to the first time of the pulse modulator in the input and through the random sequence sensor - to the second input time pulse00 modulator, the output of which is connected to the information input of the key, the 2nd output of which is connected through the filter on the acoustic-acoustic waves to the input of the controlled attenuator, the control input of which is connected to the output of the digital-analogue converter, the input of which is connected to the output of the memory block of this interference shaping channel, the outputs of the controlled attenuators of all interference formation channels are connected to the cjrMMaTopa input group, the output of which is connected to the input of the attenuator whose output is the output of the device, the output of each voltage sensor is connected to control key input

Description

of the corresponding channel of interference, the output time of the driver element is connected to the inputs of the memory blocks. All channels of formation of interference, the output time of the pulse modulator through the filter on the surface-acoustic waves of the envelope former is connected to the input of the controlled attenuator, the output of which is connected to the first input of the adder, the output of the switch through the digital-to-analog converter is connected to

the control input of the controlled attenuator, the output of the noise generator of the noise shaping unit is connected to the input of the controlled attenuator of the noise shaping unit whose output is connected to the second input of the adder, the output switch of the noise shaping unit is connected to the control input of the control attenuator through a digital-to-analog converter connected to the control input of the control attenuator noise shaping unit.

1, The invention relates to communication technology and can be used to simulate discrete information transmission channels in the design and testing of automated control systems for discrete communication channels. The purpose of the invention is to improve the accuracy of modeling. The drawing shows a block diagram of the device. The simulation of the transmission path of multichannel digital systems with HRDC in the presence of structurally similar p mech and with different signal-to-noise ratio + noise in different channels of the group message frame is performed in the device as follows (Razom, the device includes a signal channel, noise band The xy channels and the adder. The devices simulate a group signal to the output of the envelope detector of the compressed LFM-VIM signal from the receiver of the repeater on the communication theme located on the flight lifting means (LPS). The group signal simulates As follows, the reference clock pulses from the pulse clock generator arrive at the AND element which is controlled by the time master element, the time master element forms guard intervals between the frame channels of a certain duration, Since the distance of the stations of the radio link transmitter system located on the LPS is different can vary as a result of moving LPS; between stations, in order to avoid overlapping, protective intervals are introduced, the value of which is determined by the accuracy of the communication synchronization system and. The group signal is formed by a random sequence sensor and time by a pulse modulator, the output of which forms a block digital signal with time pulse modulation (VIM). The blocks are combined into channels, which in turn make up the frame of the transmitted message. A block digital VIM signal is fed to an envelope shaping device that simulates the envelope of a compressed LFM-VIM signal from the output of the receiver's envelope detector. Next, the simulation signal is fed to a controlled attenuator, the output level of which is determined by the control voltage from the output of a digital-to-analog converter (DAC). connected to a programmable switch that sets the code level of the signal at the output of the controlled attenuator. The signal levels of all channels in the frame are simulated by the same discrete control of the output level. Such simulations are simplified for the sake of simplicity, since the radio link power station's energy is fairly uniform. Suppose now that there is a group of interference stations in the area of the communication system, each of which organizes a relay-type interference (structural-like interference), t . similar group signal with different power. Since the interference supply stations are spatially separated in the area of the communication system, and the receiving ante to the repeater has a narrow radiation pattern, for example, a phased antenna array with an electronic beam switch, which for each station of the communication system is the level of interference from one setting station the interference will be different (the group signal generated at the output of the transponder receiving antenna is considered). Therefore, each interfering channel of the device has an automatic control of the level of interference so that the oTHomeLgne signal / interference during you during the summation will change according to a certain law from channel to channel in the generated frame.e. Such control is carried out with the help of a digital-analogue converter, the changeable codes at the input of which are set by means of a permanent storage device (ROM) with a channel following frequency in the frame. The program specifying the interference levels in the frame channels is recorded in the ROM and thus determines the value of the signal-to-interference ratio in the frame channels that cycle from frame to frame. The presence of a group of interfering channels in a device allows you to create complex interfering situations at the output of the adder, and the presence of keys in each interfering channel allows you to turn it on or off by a signal from a group of voltage sensors. Using a noise channel and adder, fluctuating noise is mixed into the group signal. . Thus, the device simulates the transmission path of a multi-channel digital communication system with a VIM and with spatial-time channel separation, and the interference situation changes automatically from channel to channel according to a program that is set by the persistent storage devices and the control unit. The device allows solving various problems of determining the immunity of receiving devices of signals with VIM and characteristics of measuring a signal-to-interference noise level. noise shaping. 474 The device contains a generator of 1 clock pulses, time specifying element 2, element 3, sensor A of random sequence, time pulse modulator 5, shaper envelope 6, made in the form of a filter on surface-acoustic waves, attenuator 7, switches 8 and 9 , digital-to-analog converters 10 and 11, noise generating channels 12, voltage sensor group 13, noise generator-op 14, band-pass amplifier 15, control attenuator 16, adder 17, attenuator 18, device output 19. The output of the clock generator 1 is connected to the input of the time of the setting element 2 and to the first input of the element 3, the second input i oToporo is connected to the output of the time of the setting element 2, and the output to the second input of the time of the pulse modulator 5 and the input of the sensor 4 the output sequence, the output is connected to the first input by the pulse of the pulse modulator 5, the output (of which the envelope is connected to the first input of the controlled attenuator 7 through the shaper 6, the second input of which through the digital analog drive 10) is connected to the output of the program mimic switch 8 and the output - to the input of the adder 17, the other inputs of which are connected to the outputs of the noise-generating channels 12. The noise generator 14 is connected via a bandpass amplifier 15 to the first input of a controlled attenuator 16, the second input of which is connected via a digital-analogue converter 11 with an output of a programmable switch 9, and the output is connected to the input of the adder 17, the output of which is connected via an attenuator 18 to the output 19 of the device. Interference channel 12 contains a 20 clock pulse regenerator, a time setting element 21s element 22, a random sequence sensor 23, a time pulse module 24, a key 25, an envelope driver 26 and a controlled attenuator 27, a memory block 28, and a digital-to-analog converter 29. A switch 9, a digital-to-analog converter 11, a noise generator 14, a band-pass amplifier 15, and a controlled attenuator 16 form a block 30

The device works as follows.

The pulses of the reference clock frequency from the oscillator 1 clock pulses are fed to the element ii 3, which is controlled by the time of the setting element 2. The assignment of the time of the setting element is the formation of guard intervals between the channels in the group signal generated by the sensor, 4 random sequences and the time by the pulse modulator 5. -In modulator 5, randomly digitized digital inputs

1L, i / :; PG-SHULSY WITH TIME IMPULE: o4:, :: -: o, -NDII (VIM). From output 1, o., .. a compressed pinay-frequency modulated (LFM) signal at the output of a dispersive filter on surface acoustic waves (SAW). With Bb ,, i-u. shaper envelope 6 shaped bell-shaped .jb;: bi 1i, 1 step on the controlled einueVi ATN (jp 7, the output level of which is determined by the voltage from the DAC output 10. The programmable switch 8 sets the input signal level code 10 to input 10. Thus, The output of the controlled attenuator 7 simulates a group signal of the detected compressed. Chirp signals with VIM manipulation with the possibility of discrete control of the signal level. From the output of block 7, the group signal goes to the adder 17..

In order to automatically change the level of structurally similar interference in the 1 canals 12 for generating interference, channel pulses from the output of the time of the driver element 2 are fed to memory blocks 28, the output of which forms interference level codes in each channel of the group message frame. The magnitude and sequence of level changes of structurally similar interference in the frame channels of each block 12 is determined by the program defined by the corresponding memory block 28. Synchronously with the change of code combinations and the level of interference there is a change in the level of control of the voltages at the outputs of the ILP 29. The structure of the formation of interference in blocks 12 is similar to the structure of the formation of the signal, but is independent in time. The pulses of the clock frequency from the generator of 20 clock pulses through the element 22, which is controlled by the time of the driver element 21, enter the sensor 23 of a random sequence. The frequency of the pulses produced by the oscillator 20 clock pulses is somewhat different from the frequency of the pulses of the oscillator 1 so that the interference signal slides along the group signal. From the output of the sensor 23 of a random sequence, the signal arrives at the modulator 24, where an interfering group signal with a VIM manipulation is formed. The generated interference through the key 25, which is controlled by the signal from the output of the voltage sensor of group 13, through the envelope shaper 26 enters the control attenuator 27, the transmission coefficient of which is determined by the level of the control voltage from the output of the DAC 29. Thus, the output of the channel 12 forming interference

an imitation of the action of the adversary, which creates by means of jamming stations a relayed interference in a space-time division multiplex communication system (RDCS), is produced. The level of interference in a separately taken frame channel is individual in order to simulate the spatial separation of stations in the communication system with the STRC and the directivity of the receiving antenna of the repeater located on the flight-lifting facility (satellite, airplane, balloon, airship). The amount of interference in the device is determined by the levels of control voltages supplied to the channels 12 from the outputs of the voltage sensors 13. Thus, it is possible to connect to the inputs of the adder 17 any combination of structurally similar interferences, each of which has an individual program for changing the interfering conditions in the frame channels. The noise generator 14 generates a wide-band fluctuation noise, which is fed to the band-pass amplifier 15 and the controlled attenuator 16. adder input 17. The required noise level at the input of the adder 17 is set using the programmable switch 9 and the digital display module 11. Attenuator 18 sets the level of the sum signal at the output of the device. Thus, the output of the device simulates the natural noise of the receiver and the complex interference situation that may occur at the output of the envelope detector of the compressed LFM-VIM signal from the receiver of the airborne transponder receiver in the communication system with the TACD in the presence of p system of the station group of the interference type retransmitted interference This makes it possible to solve problems of studying and evaluating the noise immunity and accuracy characteristics of devices for measuring the signal-to-noise ratio + noise required for building spatial filters in communication systems with PSTD.

Claims (1)

DEVICE FOR MODELING A MULTI-CHANNEL COMMUNICATION SYSTEM, comprising a clock pulse generator, a timing element, an I element, a random sequence sensor and a time pulse modulator, the output of a clock pulse generator is connected to the input of the timing element and to the first input of the elementΉ, the second input of which is connected to the output of the timing element, and the output with the control input of the time-pulse modulator and the input of the random sequence sensor, the output of which is connected to the time-pulse information input meat modulator, rpyrtny forming interference channels ,. characterized in that, in order to increase the accuracy of modeling, · it additionally contains an attenuator, an envelope shaper made in the form of a filter on surface-acoustic waves, a controlled attenuator, a switch, a digital-to-analog converter, a noise generating unit; made in the form of a series-connected switch and a digital-to-analog converter and a series-connected noise generator, a strip amplifier and a controlled attenuator, a group of voltage sensors, and each interference shaping channel consists of a timing element, a clock generator, an And element, a random sequence sensor, a pulse-time modulator, a key filter on surface acoustic waves and a controlled attenuator, 'memory block and digital-to-analog converter, with than the output of the clock pulse generator. in each channel of interference generation, it is connected to the first input of the And element and through the timing element to the second input of the And element, the output of which is connected to the first input of the time-pulse modulator and through the random sequence sensor to the second input-time of the pulse modulator, the output of which is connected with the information input of the key, the output of which through the filter on surface acoustic waves is connected to the input of the controlled attenuator, the control input of which is connected to the output for a digital-to-analog converter, the input of which is connected to the output of the memory block of this interference generating channel, the outputs of the controlled attenuators of all interference generating channels are connected to the adder input group, the output of which is connected to the attenuator input, the output of which is the device output, the output of each ⁴ voltage sensors is connected to the control key input with SU „1182547 of the corresponding interference generation channel, the output of the timing element is connected to the inputs of the memory blocks of all interference generation channels, the output of the time-pulse modulator through the filter on the surface-acoustic waves of the envelope shaper is connected to the input of the controlled attenuator, the output of which is connected to the first input of the adder, the switch output through the digital-to-analog converter is connected to the control input of the controlled attenuator, the output of the noise generator of the noise generating unit through a band amplifier the fir is connected to the input of the controlled attenuator of the noise generating unit, the output of which is connected to the second input of the adder, the output of the switch of the noise forming unit via a digital-to-analog converter is connected to the control input of the controlled attenuator of the noise generating unit. 1 .