SU1156262A1 - Multichannel repeater - Google Patents

Abstract

A MULTI-CHANNEL REPEATER, contains a frequency division channel block, the outputs of which are connected to the inputs of corresponding frequency channels, each of which contains a series-connected high-frequency amplifier, a first mixer, a demodulator, as well as a modulator and a series-connected second mixer and output amplifier, whose output is output frequency channel and the output of the repeater, the master oscillator, the output of which through the frequency multiplier is connected to the first input of the frequency synthesis the torus, and through a frequency divider - with the second input of the frequency synthesizer, the output of which is connected to the inputs of the first and second blocks of heterodyne frequency formers, the outputs of which, respectively, connect .rV7.-, tov.; la Mb-: and ,. They are not connected to the heterodyne inputs of the first and second channel mixers, differing from the fact that, in order to increase the stability of the radio communication, the first electronic key, the second electronic key and the memory block of the third key in series and the third connected in series are inserted into each channel electronic key and bandpass filter, as well as a control unit, the first outputs of which are connected to the control inputs of the first and second electronic keys in each channel, the second outputs are connected to the control inputs of the unit pa m (L level and the third electronic key in each channel, and the input of the control unit is connected to the output of the frequency divider, the outputs of the frequency division of the channel are connected to the inputs of the first ELECTRONIC keys, which are the inputs of frequency channels, the output of the first electronic key in each frequency the channel is connected to the inputs of high frequency amplifiers, the outputs of the demodulators are among the ones with the inputs of the second electronic Od keys, the outputs of the memory blocks. These levels are connected via modulators to the inputs of third electronic switches, and the outputs of band-pass filters are connected to the inputs of second mixers.

Description

The invention relates to communication technology and can be used to organize a one-time retransmission; qi in communication systems with moving objects in the range of meter waves. A multichannel repeater is known, which contains a frequency separation unit, the outputs of which are connected to the inputs of the respective frequency channels, each of which contains a series-connected high-frequency amplifier, a first mixer, a demodulator, a modulator, a second mixer, an output amplifier, and a master oscillator tl1 -: However, this repeater has low radio stability. The closest in technical essence to the present invention is a multichannel transponder, containing a frequency division channel block, the outputs of which are connected to the inputs of the corresponding frequency channels, each of which contains a series-connected high-frequency amplifier, a first mixer, a demodulator, and a modulator and in series connected second mixer and output amplifier, the output of which is the output of the frequency channel and the output of the repeater as well as the master oscillator, the output of which is The frequency multiplier is connected to the first input of the frequency synthesizer, and through a frequency divider to the second input of the frequency synthesizer3 whose output is connected to the inputs of the first and second blocks of heterodyne frequency formers, respectively, connected to the heterodyne inputs of the first and second mixers of each channel 2. However This multichannel repeater affects the radio transmitters of the repeater on radio receivers, which leads to a deterioration of the multi-signal selectivity transponder receivers, making it difficult to maneuver frequencies, leads to the appearance of a large number of affected frequencies. This reduces the stability of the radio through a multi-channel transponder. The purpose of the invention is to improve the stability of radio communications. The goal is achieved by the fact that a multichannel transponder comprising a frequency division block, the outputs of which are connected to the inputs of the respective frequency channels, each of which contains a series-connected high-frequency amplifier, a first mixer, a demodulator, as well as a modulator and the second connected the mixer and the output amplifier, the output of which is the output of the frequency channel and the output of the repeater, a master oscillator, the output of which is connected to The first input of the frequency synthesizer, and through the frequency divider - with the second input of the frequency synthesizer, the output of which is connected to the inputs of the first and second blocks of heterodyne frequency formers, the outputs of which are respectively connected to the heterodyne inputs of the first and second channel mixers, are entered into the repeater The first channel is the first electronic key, the second electronic key and the memory unit of the level connected in series and the third electronic key and the band-pass filter connected in series, as well as the control unit, the first outputs of which are connected to the control inputs of the first and second electronic keys in the channel, the second outputs are connected to the control inputs of the level memory unit and the third electronic key in each channel, and the input of the control unit is connected to the output of the frequency divider, outputs of the frequency section the channels are connected to the inputs of the first electronic switches, which are the inputs of the frequency channels, the output of the first electronic switch in each frequency channel is connected to the inputs of the high-frequency amplifiers, the output of the demodule Hur connected to second inputs of the electronic switches, block outputs a memory layer through the modulators are connected to inputs of third electronic switches, and the outputs of bandpass filters are connected to inputs of second mixers. The drawing shows a structural electrical circuit of the proposed multi-channel repeater. The multichannel repeater contains a block 1 frequency division channels. Each of the frequency channels contains a first electronic switch 2, a high-frequency amplifier 3, the first mixer 4, a demodulator 5, a second electronic switch 6, a level memory block 7, a modulator 8, a third electric switch 9, a band-pass filter 10, a second mixer 11, output force X body 12, master oscillator 13, frequency clever 14, frequency divider 15, frequency synthesizer 16, first heterodyne frequency generating unit 17, second heterodyne frequency generating unit 18, control unit 19. The device works as follows. The output of the antenna-feeder device (not shown) is connected to the input of the frequency separation channel unit t, in which the group signal filtering is performed, as well as its separation. The outputs of block 1 of the frequency separation channels are connected to the inputs of the first electronic switches 2, which ensure the disconnection of the repeater reception path at the moments of the retransmission to transmit. The locking and unlocking of the first electric key 2 is controlled by clock pulses from the first output of the control unit 19. The output of the first electronic key 2 is connected to the input of the amplifier 3 high frequency. High-frequency amplifier 3 provides the amplification of the reception of that signal, the required sensitivity and selectivity of the receiving path through side reception channels. The output of high-frequency amplifier 3 is connected to the input of the first mixer 4. In mixer 4, the signal frequency is reduced to an intermediate value. , In demodulator 5, the intermediate low frequency baseband signal is released from the intermediate frequency signal. From the output of the demodulator 5, the low-frequency signal is fed to the input of the second electronic key 6. The second electronic key 6 periodically opens on the clock pulses received at its input from the first. the output of control block 19, for a time shorter than half the sampling period, but sufficient to fix the level of the low-frequency signal at the output of memory block 7 at the output of demodulator 5 at the time of opening the second electronic key 6. The clock frequency of control block 19 is determined by iodization of T, determined by the frequency greater than the maximum frequency of the primary signal in accordance with theorem V.A. Kotelnikova. After locking the second electronic key 6, the value of the signal level is fixed and remains unchanged until the next clock pulse arrives in block 7 of the memory of the level fulfilled, for example, in the form of a PC circuit. To receive the next signal readout, the level memory unit 7 is set to the zero state by the decay of the pulses arriving at the control input on the second, and the output of the control unit 19 is. The signal from the output of the level memory unit 7 is fed to the input of the modulator 8. From the output of the modulator 8, the signal is fed to the input of the third electronic key 9, which is controlled by unlocking and locking via clock pulses from the second output of the control unit 19 with a period T , but shifted relative to the clock pulses from its first output on T - TD. With the arrival of the control clock pulse, the third electronic key 9 is unlocked and connects the output of the modulator 8 to the input of the bandpass filter 10 for a time less than half of the sampling period. The received radio pulse through a band-pass filter 10, which provides for the suppression of higher harmonics of a radio pulse, is fed to the input of the second mixer t 1. In the second mixer 11, the signal frequency is converted to the transmission frequency. C, the signal of the second mixer 11 is fed to the input of the output amplifier 12. Thus, the samples of the retransmitted signal received in each channel and recorded in block 7 of the level memory arrive at the output of the repeater With a time shift T T. The establishment of transient iA processes in each channel ends in the time interval from the moment of connecting Unit 1 of Frequency Division through the first electronic key 2 to the input of amplifier 3 of high frequency to the moment of locking the second electronic key 6. Signals of heterodyne frequencies are received from master oscillator 13 to multiplier 14 frequencies and frequency divider 15, where, respectively, multiplied and divided by the corresponding multiplication and division factors. YesS11 more signals are sent to the frequency synthesizer 16 and through the first heterodyne frequency shaping unit 17 to the first mixer 4, and through the second heterodyne frequency shaping unit 18 to the second mixer I I Thus, in a multichannel repeater, alternate in time with the period Td, but with a mutual shift on T. reception of retransmitted signals and their transmission. This implementation of the signal re-reception process provides a combination of the advantages of the frequency division method of channels, allowing all sources and receivers of retransmitted signals to work asynchronously, and the temporal separation of signals based on their discretization in accordance with Theorem 6A. Kotelnikov, who allowed to exclude the mutual influence of the signals separated in time, on each other. Thus, the introduction of new elements - the first electronic key, the second electronic key, the memory block, the third electronic key, the bandpass filter in each channel 1, the control unit favorably distinguishes the proposed device from the prototype, since the high multi-signal selectivity of the radio receivers is ensured it is possible to make wide use of the maneuver by frequencies, the appearance of the affected frequencies is eliminated and, by this caMbfri, the stability of the radio communication through the multi-channel retransmission increases l torus

Claims (1)

A MULTI-CHANNEL RELAY, containing a channel frequency separation unit, the outputs of which are connected to the inputs of the corresponding frequency channels, each of which contains a high-frequency amplifier, a first mixer, a demodulator, as well as a modulator and a second mixer and a series-connected output amplifier, the output of which is a frequency output channel and the output of the repeater, the master oscillator, the output of which through the frequency multiplier is connected to the first input of the frequency synthesizer, and without a frequency divider — with the second input of the frequency synthesizer, the output of which is connected to the inputs of the first and second blocks of the heterodyne frequency drivers, the outputs of which are respectively connected to the heterodyne inputs of the first and second channel mixers, characterized in that, in order to increase the stability of the radio, the communication in the repeater is introduced into each channel the first electronic key, the second electronic key and the level memory unit connected in series and the third electronic key and the bandpass filter connected in series, and Also, the control unit, the first outputs of which are connected to the control inputs of the first and second electronic keys in each channel, the second outputs are connected to the control inputs of the level memory unit and the third electronic key in each channel, and the input of the control unit is connected to the output of the frequency divider, the outputs of the frequency block channel separation connected to the inputs of the first electronic keys, which are the inputs of the frequency channels, the output of the first electronic key in each frequency channel is connected to the inputs of the amplifiers high pilots at the outputs of demodulators are connected to inputs of the second electronic switches, memory block outputs level through modulators are connected to inputs of third electronic switches, and the outputs of bandpass filters are connected to inputs of second mixers. SU ,,, 1156262> 1 1156262