SU1573546A1 - Device for checking serviceability of superheterodyne receiver - Google Patents

Abstract

This invention relates to a radio technique. The purpose of the invention is to improve the control accuracy by estimating the frequency variation of the local oscillators from the nominal value. The entered amplitude detector 12, the first 23 and second 28 phase detectors, the first 25, the second 30 and the third 32 memory elements, the third deceleration element 27, the third threshold unit 29, the third indicator 31 allow you to monitor the frequency stability of the first 8 and second 9 local oscillators monitored superheterodyne receiver 1 and thereby increases its control accuracy. 1 il.

Description

The invention relates to radio communication technology and can be used in various radio-telephone and radio-telegraph communication systems for monitoring the high-frequency channel of radio receivers in standby mode.

The purpose of the invention is to increase accuracy by assessing deviations from the frequency of the local oscillators from the nominal value.

The drawing shows a structural • electrical diagram of the proposed device.

A device for monitoring the performance of a superheterodyne receiver 1, consisting of a high-frequency amplifier 2, a first mixer 3, a first intermediate frequency amplifier 4, a second mixer 5, a second 20 'intermediate frequency amplifier 6, a detector 7, a first 8, and a second 9 local oscillators, balanced demodulator 10, filter 11, amplitude detector 12, first threshold 25 block 13, pseudo-random sequence generator 14, first indicator 15, input signal simulator 16, consisting of balanced modulator 17, first mixer 18, g 19 generators of the intermediate frequency and a second mixer 20, the first 21 and second 22 delay elements, the first phase detector 23, a second threshold unit 24, a first memory element 25, second indicator 26, the third delay element 27, the second phase detector 28, the third threshold unit

29, a second memory element 30, a third indicator 31, and a third memory element 32.

The device operates as follows: 2 of the first 3 and second 5 mixers, the first 4 and second 6 'amplifiers, is fed to the input of the first balance ₍ demodulator 10, the second input of which receives a signal from the pseudo-random sequence generator 14, but delayed in the first element 21 delays equal to the time delay of the control signal during the passage of the linear path of the controlled superheterodyne receiver 1. As a result, at the output of the balanced demodulator 10, the control signal is freed from manipulation From the output of the balanced demodulator 10, the signal enters through the filter 11, tuned to the value of the second intermediate frequency, to the amplitude detector 12 and its output signal is compared in the first threshold block 13 with a predetermined threshold, and the result of the comparison is remembered in the third memory element 32 and is displayed on the first indicator 15. In the case of a frequency shift of the controlled superheterodyne receiver 1 due to the instability of the frequencies of its first and second local oscillators Ovs 8 and 9, the harmonic signal from the output of the balanced demodulator 10 leaves the passband of the filter 11 and, therefore, the signal from the output of the amplitude detector 12 is the smaller, the larger the frequency offset due to the frequency instability of the first 8 and second 9 local oscillators. At the same time, to increase the accuracy of the control, the stability control is carried out hourly.

The control signal, which is a sinusoidal carrier modulated by a pseudo-random sequence from the generator 14, from the generator 19, is supplied from the output of the balanced modulator 17 of the simulator 16 of the input signal to the input of the first 18 and second 20 mixers, in which the conversion of the control signal spectrum to the tuning frequency occurs controlled superheterodyne receiver 1, which is then fed to its input. The signal transmitted through the ^linear! tract controlled superheterodyne PRIE nick 1 consisting of usitoty first 8 and second 9 oscillators controlled supergeterodin45 Nogo receiver 1 "

It is known that the frequency and phase of harmonic oscillations are interdependent, therefore, checking the frequency instability of the first 8 and second 9 hetero50 dan can be done by comparing the phases of the oscillations in the time interval; to a multiple period of oscillations ”The harmonic signal from the output of the first .8 and second 9 local oscillators is sent respectively to the first inputs of the first 23 and second 28 phase detectors and to their second inputs through the second 22 and third 27 delay elements, where it is delayed by a multiple of several the oscillation periods of these local oscillators are 8 and 9. If the oscillation phases at both inputs of the first 23 and second 28 phase detectors coincide, their output signals have a maximum value, and if a phase jump occurs, then a minimum. From the outputs of the first 23 and second .28 phasics, containing a simulator of the input signal, the output of which is: the information input of the superheterodyne receiver being monitored, the first and second indicators, the first and second threshold blocks, the control signal generator and the first delayed detector element are connected in series, respectively on the second 24 and third 29 threshold blocks, where they are compared with a predetermined threshold, and the comparison result is stored in the first 25 and second 30 memory elements and selected It appears on the second 26 and third 31 indicators.

The first phase detector 23 is designed to compare the phases of the oscillations at the output of the first local oscillator 8 after a time interval that is a multiple of its oscillation period.

The second phase detector 28 is designed to compare the phases of the oscillations at the output of the second local oscillator 9 after a time interval that is a multiple of its oscillation period.

The second threshold unit 24 is designed to compare the signal level at the output of the first phase detector 23 with a predetermined threshold.

The third threshold unit 29 is designed to compare the signal level at the output of the second phase detector 28 with a predetermined threshold.

The second delay element 22 is designed to delay the oscillation from the output of the first local oscillator 8 for a time multiple of its oscillation period.

The third delay element 27 is designed to delay the oscillation from the output of the second local oscillator 9 for a time multiple of its oscillation period.

The first 25, second 30, third 32, memory elements are designed to store the results of the comparison, respectively, in the second 24, third 29 and first 13 threshold blocks.

The first 18 and second 20 mixers are designed to transfer the spectrum of the control signal to the tuning frequency.

The generator 19 of the intermediate frequency. Designed to generate an intermediate frequency signal.

Claims (1)

Claim' A device for monitoring the operability of a superheterodyne IQ signal, a second delay element, a balanced demodulator connected in series, the input of which is a low-frequency output of a superheterodyne receiver being monitored, and 15 is a filter, and the input signal simulator consists of a series-connected intermediate frequency generator, a balanced modulator, the second input of which is connected to the output of the control signal generator, the first mixer, the second input of which is disconnected from the output of the second local oscillator of the superheterodyne receiver, the second mixer is 25, the second input which is connected to the output of the first local oscillator controlled superheterodyne receiver, and the output of the second mixer is the output of the input simulator 30 signal, characterized in that, in order to improve the accuracy of control by assessing the deviation of the frequency of the local oscillators from the nominal, an amplitude detector, input and output 35 of which are connected respectively to the output of the filter and the input of the first threshold unit, the first phase detector> the first input of which is connected to the output of the first local oscillator of the controlled superheterodyne receiver, the output of which is also connected to the input of the second delay element, the output of which is connected to the second input of the first phase detector, the output of which is connected to the input of the second threshold block, the first memory element, the input and output of which are connected respectively with the output of the second threshold block and the input of the second 50 indicators in series with the third delay element, the input of which is connected to the output of the second local oscillator of the superheterodyne controlled receiver, the second phase detector, the second input of which is connected to the output of the second local oscillator of the superheterodyne controlled receiver, the third threshold block, the second memory element and the third indie 7 - 1573546 cator, the third memory element, the input and output of which are connected respectively to the output of the first threshold ¹ unit and the input of the first indicator, the output of the first delay element is connected to the second input of the balanced demodulator, while the control signal generator is made in the form of a pseudo-random sequence generator ”