SU813681A1 - Frequency nanipulator - Google Patents

Description

. one

The invention relates to radar technology, in particular, to systems for simulating impulse noise of radar stations with given statistical characteristics as functions of the distribution of pulse durations, pulse intervals, amplitudes and pulse filling frequencies and can be used when setting up protection devices against mutual impulse noise of radar stations , as well as radar processing devices.

A noise simulator is known that contains a type of noise switch connected in series, a random pulse shaper and a break modulator, a controlled attenuator and mixer connected in series, as well as a random interval driver, an input unit for distribution functions, a high-frequency generator, a band-pass filter and a synchro-generator, the output of which connected to the clock inputs of the input unit of the distribution functions and the random interval generator, the first control input of which is connected to the output ohm pulse shaper of random duration, first control input

which is connected to the first output of the input unit of distribution functions 1,

However, this device does not provide high accuracy of impulse noise simulation with specified statistical characteristics as functions of the distribution of the pulse duration, the intervals between pulses, the amplitudes and the frequencies of the pulses.

The purpose of the invention is to improve the accuracy of the simulation of impulse noise with given statistical characteristics.

For this, in imitation 1: an interference ort containing a series-connected noise type switch, a shaper of random duration and a break modulator, a series-connected controlled attenuator and a mixer, as well as a random interval shaper, a distribution function input unit, a high-frequency generator, a band-pass filter and a synchronous generator, the output of which is connected to the clock inputs of the block-input of distribution functions and the random interval generator, the first control -j input of which is connected to the output of a pulse generator of random duration, the first control input is connected to the first output of the input block of distribution functions, the serially connected first random number generator and the first digital-to-analog converter, and the second digital-analog converter and the controlled high-frequency generator are entered in series, the output of which is connected to the input of the controlled attenuator, the control input of which is connected to the output of the first digital the analog converter, while the clock input of the pulse generator of random duration is connected to the output of the synchronous generator, the second control input to the first output of the random frequency generator, the second output of which is connected to the signal inputs of the first and second random number generators, the control inputs of which are connected respectively to the second to the third outputs of the input unit of distribution functions, the fourth output of which is connected to the second control input of the random interval generator, the output The high frequency generator is connected to another mixer input, the output of which is connected to the input of a bandpass filter, the output of which is connected to another input of the break modulator, the output of which is the output of a noise simulator.

The drawing shows a structural electrical circuit of the proposed interference simulator.

The interference simulator contains a noise type switch 1, a pulse generator of random duration 2, a break 3 modulator, a synchronous generator 4, a random interval 5 driver, a band-pass filter b, a distribution function input unit 7 consisting of a control unit 8 and a photo-reading unit 9, a mixer 10 high frequency generator 11, controlled attenuator 12, digital to analogue converters 13 and 14, random number generators 15 and 16, controlled high frequency generator 17.

Interference simulator works as follows.

The sync pulse 4 triggers the photo-reading unit 9 of the input unit of the distribution functions 7 and the codes of the distribution functions of the random pulsed flow recorded on the puncture tape are read by the block 9 and through the control unit 8 are inserted into the functional probabilistic converters of the pulse generator of random duration 2, the generator of the random interval 5 and random number generators 15 and 16. Noise type 1 trigger switch / em random pulse generator

of duration 2, which, according to the clock pulses of the synchronous generator 4, generates a pulse of random duration, which arrives at the modulator 3, and the falling edge of this pulse triggers the generator of random intervals 5. According to the clock pulses of the synchronous generator defining the interval discreteness, the generator of random intervals 5 produces pulses at random times that trigger a pulse generator of random duration 2 and random number generators 15 and 16. The generator is random numbers 16 at the time of arrival of the pulses from the shaper 5 generates a number, distributed according to a probability recorded tnostnom inverter generator 1 frequency distribution law filling random pulse stream. From the output of the generator 16, the random numbers are fed to the digital-to-analog converter 14, where they are converted to analog voltage and fed to a voltage-tunable high-frequency generator 17. The random number generator 15 generates numbers distributed according to the distribution law written in the generator 15 amplitudes of impulse noise. The random numbers of the generator 15 are converted into analog voltage of the digital-to-analog-to-LED converter 13. Depending on the magnitude of the random voltage, attenuation of attenuator 12 is set and, accordingly, the oscillation amplitude of the controlled high-frequency generator 17 at the input of the mixer 10. Mixer 10 and the high-frequency oscillator 11 transform the control frequency high frequency oscillator 17 within the required range defined by the bandpass filter 6. The voltage of a random frequency and amplitude ode bandpass filter 6 is modulated random stream of video pulses formed shaper mi. 2 and 5. The stream of radio pulses at the output of the modulator 3 has a random pulse duration, the interval between pulses, the amplitude and the frequency of filling of the pulses, distributed in accordance with specified statistical laws.

Claims (1)

By increasing the number of independent simulated parameters of a pulsed stream to four (duration interval, amplitude, frequency), the functionality of a pulsed interference flow simulator with given statistical characteristics is expanded, which allows testing devices from mutual pulse interference from radar stations at both video frequency and and on. intermediate or high frequency. The use of computer technology improves the accuracy of generating random radio pulse streams with given statistical characteristics. An interference simulator comprising a series-connected noise switch, a random pulse shaper and a interrupt modulator, a controlled attenuator and a mixer in series, also a random interval shaper, a distribution function input unit, a high-frequency generator, a band-pass filter and a clock generator, an output which is connected to the clock inputs of the input unit of the distribution functions - and the random interval generator, the first control input of which is connected With the output of a pulse generator of random duration, the first control input of which is connected to the first output of the input block of the distribution function, distinguished by the fact that, in order to improve the accuracy of simulating impulse noise with given statistical characteristics, the first random number generator and the first a digital-to-analog converter, as well as serially connected second random number generator, a second digital-to-analog converter, and controlled high-frequency r a generator, the output of which is connected to the input of the controlled attenuator, the control input of which is connected to the output of the first digital-to-analog converter, while the clock input of the generator of pulses of random duration is connected to the output of the synchronous generator, the second control input - to the first output of the generator of random intervals, The second output of which is connected to the signal inputs of the first and second random number generators, the control inputs of which are connected respectively to the second and third. the outputs of the input unit of distribution functions, the fourth output of which is connected to the second control input of the random interval generator, the output of the high-frequency generator is connected to another input of the mixer, the output of which is connected to the input of a band-pass filter whose output is connected to another input of the break modulator whose output is noise simulator output. Sources of information taken into account during the examination 1. USSR Author's Certificate No. 556394, cl. G 01 S 7/40, 1973 (prototype). z