SU1172039A1 - Device for checking serviceability of multichannel radio systems - Google Patents

Abstract

A DEVICE FOR MONITORING OPERATIONAL CAPABILITY OF MULTI-CHANNEL RADIO SYSTEMS, containing on the transmitting side a control signal generator, a frequency conversion unit and N keys, a control signal generator output connected to the input of a frequency conversion unit and to the combined N / 2 keys whose outputs are the inputs of the first group of channels monitored multi-channel radio system, the output of the frequency conversion unit is connected to the other N / 2 switches integrated at the input, the outputs of which are the inputs of the second group A / C monitored multichannel radio system, and on the receiving side N keys and serially connected signal level comparison and indicator inputs N / 2 keys are the outputs of the first group of controlled multichannel radio systems, the inputs of the other N / 2 keys are the outputs of the second group of channels of the controlled multichannel radio system , characterized in that, with the aim of ensuring the possibility of monitoring without interruptions in the operation of a controlled multi-channel radio system, In series, the first frequency converter and the first filter, the output of which is connected to the first input of the element of the level comparison, and the second frequency converter and the second filter, the output of which is connected to the second input of the comparison element, are connected in series, the signal input of the first frequency converter is connected to the outputs N / 2 keys (second group of channels of the controlled multichannel radio system, and the heterodyne input is connected to the output of the control signal generator, si tional input of the second frequency converter coupled to outputs N / 2 of the first group of keys controlled multichannel radio channels, and LO input connected to the output of the frequency converting block. to oo; o

Description

The invention relates to radio engineering and can be used to periodically monitor the performance of multichannel frequency selective systems.

The purpose of the invention is to provide the possibility of monitoring without interruptions in the operation of a controlled multichannel radio system.

The drawing shows a structural electrical circuit of the proposed device.

A device for monitoring the operability of multichannel radio systems on the transmitting side contains a pilot signal generator 1, N keys 2, a frequency converter block 3, on the receiving side N keys 4, a signal level comparison element 5, indicator 6, first filter 7, first frequency converter 8, second the filter 9, the second converter 10 is often 10, the transmitting and receiving sides are connected by the first group of channels 11 and the second group of channels 12 of the controlled multi-channel radio system.

The device works as follows.

During the performance monitoring of the monitored multichannel radio system, N keys 2 on the transmitting side and N keys 4 on the receive side are closed, ensuring the connection of the first channel group 11 and the second group of channels 12 of the monitored multichannel radio system for monitoring and their parallel connection to the inputs and outputs. At the same time, the number of channels in the first group of channels 11 and in the second group of channels 12 is the same, and the difference in the frequencies of tuning the amplitude-frequency characteristics (AFC) of the channels in the first group of channels 11 and in the second group of channels 12, which have the same sequence numbers, is always constant nna

The control signal of the generator 1 with a frequency varying in the range of input frequencies of the first group of channels 11 and a level equal to the level of own sound of the monitored multichannel radio system recalculated to the input through the corresponding keys 2 is fed to the inputs of the channels of the first group of channels 11 Simultaneously to the inputs of the second group of channels 12, through the corresponding keys 2, the same signal is supplied as to the first group, but transferred by the frequency conversion unit 3 to the range corresponding to its input frequencies. Thus, at the inputs of both groups of channels 11 and 12 there are signals of the same level that synchronously change their frequencies, which pass from channel to channel and retain the same relative detuning in the channels they occupy.

In a working multichannel radio system, the output responses of the channels to such input signals will be equal to each other due to the uniformity of the shape of the frequency response.

serviceable channels.

To compare the levels of responses at the outputs of the election channels of the first and second groups of channels 11 and 12, they are fed through the corresponding keys 4 on the receiving side to the signal inputs of the first

and second transducers 8 and 10 frequencies. As a heterodyne signal, these frequency converters 8 and 10 are supplied with frequency-tunable control signals from the inputs of the keys 2 of the adjacent

channel groups. Those. The second frequency converter 10 connected via keys 4 to the outputs of the first group of channels 11, which are controlled through the keys 2 directly by the signal from the control signal generator 1, is given a signal from the output of the frequency conversion unit 3 as the heterodyne signal, and the first converter 8 through the keys 4 to the outputs of the second group of channels 12, controlled through the keys 2 by a signal from the frequency conversion unit 3, the signal from the oscillator 1 of the control signal is fed as the heterodyne one signal.

Thus, at the outputs of the first and second converters 8 and 10 frequency

The responses of the control signals from the outputs of the first and second groups of channels I and 12 will have a constant frequency equal to the difference between the varying synchronous frequencies of the signal and the local oscillator, i.e. the difference in the frequency of the control signal in both groups of channels

11 and 12 generated on the transmission side by the frequency conversion unit 3. The frequency of the main signals processed by the controlled system at the outputs of the first and second converters 8

and 10, the frequency becomes variable, varying with the rate of tuning the frequency of the control signal of generator 1.

The first and second filters 7 and 9 connected to the outputs of the first and second inverters 8 and 10 are tuned to

the constant frequency of the response of the control signal formed by these transducers.

The bandwidth of the first and second filters 7 and 9 is chosen narrow enough to provide the necessary signal-to-noise ratio at their output and isolate the control signal from the intrinsic noise of the path of the controlled multi-channel radio system. The improvement in the signal-to-noise ratio will then be determined by knowing -, where D f c is the strip by reading

starting channels of a controlled multichannel radio system, the passband of the first and second filters 7 and 9. The bandwidth ratio of the first and second filters 7 and 9 and the frequency tuning frequency of the control signal generator 1 is selected so that the maximum level operating signals processed by the controlled multichannel radio system whose frequency at the output of the first and second converters 8 and 10, the frequencies change synchronously with the frequency of the generator 1; they did not have time to form the outputs of the first and second filters 7 and 9 the ditch responses at levels close to the level of the pilot signal responses m. Thus, at the outputs of the first and second filters 7 and 9, the selection of the control signal responses for each group of channels 11 and 10 of the controlled multi-channel radio system is provided. To compare the response levels at the outputs of the selective channels of both groups of channels 11 and 12, they are fed from the outputs of the first and second filters 7 and 9 to the inputs of the element 5 of the signal strength comparison (from each group to its own input). The difference signal of the compared responses comes from element 5 comparing the signal levels to the indicator 6. The appearance of the difference signal on the indicator 6 indicates a malfunction of the single channel and, accordingly, of the entire controlled multi-channel radio system. It is assumed here that the probability of a simultaneous failure of the two compared channels, resulting in identical changes in the shape of their frequency response, is rather small.

Claims (1)

DEVICE FOR MONITORING THE PERFORMANCE OF MULTI-CHANNEL RADIO SYSTEMS, comprising on the transmitting side a control signal generator, a frequency conversion unit and N keys, the output of a control signal generator connected to the input of the frequency conversion unit and to N / 2 keys combined at the input, the outputs of which are inputs of the first group of channels being monitored multichannel radio system, the output of the frequency conversion unit is connected to the combined input of other N / 2 keys, the outputs of which are the inputs of the second group of channels to of the monitored multichannel radio system, and on the receiving side of N keys and serially connected signal level comparing element and indicator, the N / 2 key inputs are outputs of the first group of the monitored multichannel radio system, the inputs of the other N / 2 keys are outputs of the second channel group of the monitored multichannel radio system, characterized in that, in order to ensure the possibility of monitoring without interruptions in the operation of the controlled multichannel radio system, the following the first frequency converter and the first filter are connected, the output of which is connected to the first input of the signal level comparing element, and the second frequency converter and the second filter are connected in series, the output of which is connected to the second input of the signal level comparing element, the signal input of the first frequency converter with outputs N / 2 of the keys of the second group of channels of a controlled multi-channel radio system, and the heterodyne input is connected to the output of the control signal generator, the signal input the second frequency converter is connected to the N / 2 outputs of the keys of the first group of channels of the monitored multichannel radio system, and the heterodyne input is connected to the output of the frequency conversion unit. >