RU2079971C1 - Amplitude-modulated signal receiver incorporating harmonic interference correction provision - Google Patents

Abstract

FIELD: radio engineering; broadcasting and radio communications. SUBSTANCE: receiver has series-connected amplitude detector 25 and adder 34, as well as beat signal shaper 26, switch 33 whose outputs are coupled with adder 34, series-connected first low- frequency filter 27, first additional amplitude detector 30, and comparison element 32 whose output is connected to control input of switch 33 and second input is connected to output of second additional amplitude detector 31 whose input is connected to output of high- frequency filter 28 whose input is connected to inputs of first low- frequency filter 27, beat signal shaper 26, and amplitude detector 25, amplifier-converter channel incorporating series-connected antenna 1, radio-frequency resonant amplifier 2, first frequency converter 3, first intermediate-frequency resonant amplifier 4, second frequency converter 6, and first resonant amplifier 7 of second intermediate frequency, as well as frequency synthesizer 5 whose outputs are connected to second inputs of first and second frequency converter 3 and 6, respectively; amplitude-modulated signal built up across output of amplifier-converter channel is separated into carrier-frequency signal and double side frequency signal by means of narrow-band carrier-frequency rejection filter 8, band filter 10, narrow-band carrier-frequency filters 9,10; then these signals are added in second adder 18 in appropriate proportions afforded by first adjustable carrier-frequency amplifier 11. Control is effected by gain control 12, high- and low-level comparators 13, 14, phase detector 20 with low-frequency filter 16, square-wave shapers 19,24, and amplitude limiter 22 with band filter 23. This control is effected according to interference level due to provision for separating interference from signal. Gain control of adjustable beat-signal amplifier is effected simultaneously. EFFECT: improved efficiency of interference correction due to increasing permissible threshold value of interference-to-signal ratio at receiver input. 1 dwg

Description

 The present invention relates to the field of radio engineering and can be used in broadcasting and radio communications.

 In real conditions of radio reception, especially in a difficult electromagnetic environment at the input of an amplitude detector, there are both desirable and undesirable signals. As a result of the beating of these signals in the detector, interference occurs with the beat frequency, which worsens the signal-to-noise ratio at the output of the linear path of the radio receiving device. There are various radios, including devices that improve the signal-to-noise ratio at the output of the radio receiver.

 A known receiver of amplitude-modulated (AM) signals [1] comprising a first bandpass filter that transmits a carrier signal and a lower sideband signal, a second bandpass filter that transmits a carrier signal and a upper sideband signal, a switching unit that sequentially connects the first filter with the second, and in the second state, the second filter with the first, limiter, multiplier. In the first state of the switching unit, the output of the limiter, as well as the first filter, receives the detected signal of the lower sideband. In the second state of the switching unit, the output of the limiter, as well as the second filter, receives the detected signal of the upper sideband. In this way, the sideband in which there is no interference is selected. The disadvantages of this device are: 1) manual switching when selecting side bars; 2) in the event of interference in both sidebands, it is not possible to completely get rid of the interference; 3) when choosing sidebands there will be a break in receiving messages.

 A known receiver of AM signals [2] which has a selector for selecting the output signals of the detectors of the upper and lower sidebands and is characterized in that it contains blocks emitting beating components with the signals of neighboring stations contained in the output signals of the detector, and a switch comparing the output signals of these blocks of choice. The output signal of the comparator is controlled by a selector. This selects the signal without interference.

 The disadvantage of this device is the inability to exclude interference acting independently in the upper and lower sidebands, and when choosing sidebands there will be a short break in receiving messages.

 The closest in technical essence to the proposed one is a device for compensating harmonic interference in radio receivers of amplitude-modulated signals [3] selected for the prototype, which contains a series-connected amplitude detector, the input of which is the input of the device, and an adder, as well as a beat signal generator, a commutator, the first and the second outputs of which are connected to the inputs of the adder, a series-connected low-pass filter, a first additional amplitude detector and a comparison element connected between the input of the device and the control input of the switch, a series-connected high-pass filter and a second additional amplitude detector connected between the input of the device and the other input of the comparison element, and the beat signal driver is made in the form of a series-connected limiter, frequency detector and integrating circuit and is connected between device input and switch input.

 When a signal with a harmonic noise acts at the input of the AM device, the beat signal generator emits harmonic noise and, through the switch, this signal goes to the adder, where the total signal containing the desired signal and the interference signal is output from the output of the amplitude detector. In the adder, the interference signal is compensated, and at the output of the device there is only the desired signal. The low-pass filter, the high-pass filter, additional detectors and the comparison element are used to control the adder using a switch, which, depending on which sideband the interference acts in, works either as an adder or as a subtractor. However, in the device, due to different laws of changes in the amplitude and phase of the total oscillation, compensation is possible only for a certain threshold value of the interference to signal ratio. If this threshold is exceeded, the compensation efficiency decreases. And the more the threshold is exceeded, the more the compensation efficiency decreases.

 The objective of the invention is to increase the compensation efficiency by increasing the allowable threshold value of the ratio of interference to the signal at the input of the radio receiver.

 The solution to this problem is provided by the fact that in the AM signal receiving device containing an amplitude detector and an adder connected in series, the output of which is an output of the device, a beat signal generator, a switch, the first and second outputs of which are connected to the inputs of the first adder, the first low-pass filter is connected in series , the first additional amplitude detector and a comparison element, the output of which is connected to the control input of the switch, the filter is connected in series to the top frequencies and a second additional amplitude detector, the output of which is connected to another input of the comparison element, and the inputs of the amplitude detector, beat generator, first low-pass filter and high-pass filter are combined, a series-connected antenna, resonant radio frequency amplifier, first frequency converter, resonant are introduced an amplifier of the first intermediate frequency, a second frequency converter and a first resonant amplifier of the second intermediate frequency, as well as a frequency synthesizer, first the first and second outputs of which are connected respectively to the second inputs of the first and second frequency converters, serially connected by a notch filter of a carrier frequency, a first band-pass filter, a second adder, a second resonant amplifier of a second intermediate frequency, an amplitude limiter, a second band-pass filter, a first square-wave oscillator, a phase detector and a second low-pass filter, connected in series with a first narrow-band carrier frequency filter, a first adjustable gain carrier frequency carrier, second carrier-frequency narrow-band filter and phase shifter, and gain regulator, first and second comparators, second square-wave oscillator and second adjustable amplifier, while the output of the first resonant amplifier of the second intermediate frequency is connected to the outlets of the carrier-frequency notch filter and the first a narrow-band filter of the carrier frequency, the output of the phase shifter is connected to the second input of the second adder and the input of the second square-wave oscillator, you One of which is connected to the second input of the phase detector, the output of the second low-pass filter is connected to the inputs of the first and second comparators, the outputs of which are connected to the corresponding inputs of the gain controller, the output of which is connected to the second input of the first adjustable amplifier, the output of the second resonant amplifier of the second intermediate frequency is connected to the input of the amplitude detector, the output of the beat signal driver is connected to the first input of the second adjustable amplifier, the second input of which is connected to the output gain control, and the output to the input of the switch.

 The introduced differences make it possible to increase the allowable threshold value of the ratio of interference to the signal at the input of the radio receiver, since the amplitude-modulated signal obtained at the output of the amplifier-converter path (output of the first amplifier of the second intermediate frequency) is separated by a notch, band-pass filter, and narrow-band filter of the carrier into carrier signals and double lateral, which then add up in the second adder in the corresponding proportions provided by the first adjustable force Itel carrier. The adjustment is controlled by a gain controller, upper and lower level comparators, a phase detector and a low-pass filter, a square-wave oscillator and an amplitude limiter with a band-pass filter. This adjustment is made according to the level of interference due to the fact that the device separates the interference from the signal. At the same time, the gain of the adjustable beat signal amplifier is adjusted. As a result, the compensation efficiency is increased.

 The drawing shows a structural diagram of the proposed device.

 The device contains a series-connected antenna 1, a resonant amplifier of radio frequency 2 (URF), a first frequency converter 3 (Ex. 1), a resonant amplifier of the first intermediate frequency 4 (UPCH 1), a second frequency converter 6 (Ex. 2) the first resonant amplifier of the second intermediate frequency (1 UPCH 2) 7, as well as a frequency synthesizer 5 whose outputs are connected to the second inputs of the first and second frequency converters 3 and 6, respectively; carrier frequency notch filter 8, first carrier frequency narrowband filter 9, first bandpass filter 10, first adjustable carrier amplifier 11, gain control 12, first and second comparators 13 and 14, second carrier narrowband filter 15, second low pass filter 16, phase shifter 17, the second adder 18, the second square-wave oscillator 19, the phase detector 10, the second resonant amplifier of the second intermediate frequency 21, the amplitude limiter 22, the second band-pass filter 23, the first square-wave former x oscillations 24, an amplitude detector 25, a driver of a beat signal 26, a first low-pass filter 27, a high-pass filter 28, a second adjustable amplifier 29, a first additional amplitude detector 30, a second additional amplitude detector 31, a comparison element 32, switch 33, the first adder 34. Moreover, the output of the first resonant amplifier of the second intermediate frequency 7 is connected to the inputs of the notch filter of the carrier frequency 8 and the first notch filter of the carrier frequency 9, the output of which is connected to the first the first adjustable carrier amplifier 11, the second input of which is connected to the output of the gain controller 12, the inputs of which are connected to the outputs of the first 13 and second 14 comparators, the inputs of which are connected to the output of the second low-pass filter 16. The input of the second low-pass filter 16 is connected to the phase output detector 20, the first input of which is connected to the output of the first driver 24, and the second input to the output of the second driver of square waves 19, the input of which is connected to the output of the phase shifter 17. The input of the phase shifter 17 is connected n with the output of the first adjustable carrier amplifier 15, the input of which is connected to the output of the first adjustable amplifier 11. The output of the first bandpass filter 10 is connected to the first input of the second adder 18, the second input of which is connected to the output of the phase shifter 17. The output of the second adder 18 is connected to the input of the second resonant an amplifier of the second intermediate frequency 21, the output of which is connected to the input of the amplitude detector 25 to the input of the amplitude limiter 22, the output of which is connected to the input of the second band-pass filter 23, the output through connected to the input of the first square-wave oscillator 24, the output of which is connected to the first input of the phase detector 20. The input of the beat signal generator 26 is connected to the inputs of the amplitude detector 25, the first low-pass filter 27 and the high-pass filter 28, the output of which is connected to the input of the second additional amplitude detector 31, the output of which is connected to one of the inputs of the comparison element 32, to the other input of which the output of the first additional amplitude detector 30 is connected, the input of which is connected to the output the house of the first low-pass filter 27. The output of the comparison element 32 is connected to one of the inputs of the switch 33, to the second input of which the output of the second adjustable amplifier 29 is connected, the first input of which is connected to the output of the beat generator 26 and the second input to the output of the gain control 12. The output of the amplitude detector 25 is connected to the first output of the switch 33 and one of the inputs of the first adder 34, the second input of which is connected to the second output of the switch 33. The output of the adder 34 is the output of the device.

 The work of the proposed device is as follows.

Serially connected antenna 1, URC 2, PR ₁ 3, PR ₁ 3, UPCH ₁ 4, synthesizer 5, PR ₂ 6, 1 UPCH ₂ 7 represent the main path of the receiving device with a double frequency conversion of the type "Katron", "Rowan" , "Guys", "Philips", described in detail in (1. O.V. Golovin Professional radio receivers of decameter band, M. Radio and communications, 1985). The amplitude-modulated radio signal from the converted carrier to the second intermediate frequency from the output of unit 1 of the IF ₂ 7 is fed to the notch filter of the carrier frequency 8 and to the first narrow-band filter of the carrier frequency 9. From the output of the notch filter of the carrier 8, the signal without carrier is fed to the first band-pass filter 10 s a passband equal to that necessary to equalize the amplitude-frequency characteristics of the signal from the output of which the signal is supplied to the first input of the second adder 18. From the output of the first narrow-band carrier filter 9 pilots at the carrier signal without sidebands supplied to the first input of the first controlled carrier amplifier 11 where amplified. The gain of the amplifier is regulated by the gain control 12 depending on the level of interference, the load of the first adjustable carrier amplifier 11 is the second narrow-band filter of the carrier 15 through the phase shifter 17, which serves to adjust the phase of the carrier with a signal without a carrier. The carrier signal is fed to the second input of the second adder 18, where the amplified carrier signal is summed with the signal without a carrier. From the output of the second adder 18, the amplitude-modulated signal with a higher carrier level is fed to the input of the second resonant amplifier of the second intermediate frequency 21, from the output of which the signal is fed to the input of the amplitude limiter 22, as well as to the input of the amplitude detector 25, the driver of the beat signal 26, of the first a low-pass filter 27 and a high-pass filter 28. From the output of the amplitude limiter 22, the amplitude-limited but phase-modulated signal under the influence of interference is fed through a second band-pass filter 23 to the first square-wave oscillator 24, where phase-modulated square-wave oscillations are generated, from the output of the first square-wave oscillator 24, this signal is supplied to the first input of the phase detector 20, the second input of which is supplied with the carrier frequency signal as the reference voltage after the phase shifter 17 through the second square-wave oscillator 18 . From the output of the phase detector 20, the detected signal through the second low-pass filter 16 is supplied to the first and second comparators 13 and 14, which control the gain control 12, the first carrier amplifier 11 and the second adjustable amplifier 29. A total oscillation is generated by the action of harmonic interference on the desired signal, varying in amplitude and phase. The interference compensation is carried out in the first adder 34. When the interference increases to a level where the interference to signal ratio exceeds the acceptable threshold value, the first comparator 13 is activated and controls the gain control 12, which increases the gain of the first adjustable carrier amplifier 11 and the second adjustable amplifier 29 to those as long as the ratio of interference to the signal is not reduced to acceptable when the noise level is reduced. When the interference to signal ratio is lower than acceptable, the second comparator 14 is triggered, and the gain of the first adjustable carrier amplifier 11 and the second adjustable amplifier 29 is reduced by the gain control 12 until the interference to signal ratio is valid. In the case where there is no interference, the gain of the first adjustable amplifier of the carrier 11 and the second adjustable amplifier 29 are equal to unity.

 Thus, when the permissible value of the interference to signal ratio is exceeded, the compensation efficiency is much higher.

 The implementation of the device blocks may be as follows.

 The blocks of the resonant radio frequency amplifier 2, antenna 1, the first frequency converter 3, the resonant amplifier of the first intermediate frequency 4, the frequency synthesizer 5, the second frequency converter 6, the first resonant amplifier of the second intermediate frequency 7, and the second resonant amplifier of the second intermediate frequency 21 can be realized according to the schemes and elements described in (1) and (2. B.M.Bogdanovich, Radio receivers with a large dynamic range, M. Radio and communications, 1984). Carrier narrow-band notch filter 8, first carrier narrow-band filter 9, first band-pass filter 10, second narrow-band carrier filter 15, second band-pass filter 23, first low-pass filter 27, high-pass filter 28, can be performed according to the usual scheme with C elements or in the form of monolithic quartz filters, surfactant filters described in (1). The low-pass filter 16 is made in the form of a PC circuit. Comparators 13 and 14 and gain control 12 are made according to the scheme described in (2). Adders 34 and 18 are made similar to the prototype. The first adjustable carrier amplifier 11, gain control 12, phase shifter 17, second additional amplitude detector 31 and first additional amplitude detector 30 can be performed according to the schemes described in (2) and (3. V.I. Gorshkov, Radio electronic devices, M. Radio and Communications, 1984). The phase detector 20 can be performed according to the scheme given in (4. V.V. Palshkov, Radio receivers, M. Radio and communications, 1984). The first driver of rectangular waves 24 and the second driver of rectangular waves 19 are made according to the scheme given in (5. E.I. Manaev, Fundamentals of Radio Electronics, M. Radio and Communications, 1985). The amplitude detector 25, the driver of the beat signal 26, the comparison element 32 and the switch 33 can be performed as in the prototype. The amplitude limiter 22 can be performed according to the schemes given in (3 or 5). The adjustable amplifier 29 can be performed in the same way as the adjustable amplifier 11.

Claims (1)

 A radio-frequency device of amplitude-modulated signals with harmonic compensation, comprising a series-connected amplitude detector and a first adder, the output of which is the output of the device, a beat signal generator, a switch, the first and second outputs of which are connected to the inputs of the first adder, the first low-pass filter connected in series, the first additional amplitude detector and the comparison element, the output of which is connected to the control input of the switch, sequentially connect a high-pass filter and a second additional amplitude detector, the output of which is connected to another input of the comparison element, and the inputs of the amplitude detector, beat generator, first low-pass filter and high-pass filter are combined, characterized in that a series-connected antenna and a resonant radio frequency amplifier are introduced , a first frequency converter, a resonant amplifier of a first intermediate frequency, a second frequency converter and a first resonant amplifier, a second intermediate frequencies, as well as a frequency synthesizer, the first and second outputs of which are connected respectively to the second inputs of the first and second frequency converters, serially connected by a notch filter of the carrier frequency, the first band-pass filter, the second adder, the second resonant amplifier, the second intermediate frequency, the amplitude limiter, the second a band-pass filter, a first square-wave oscillator, a phase detector and a second low-pass filter, connected in series to the first narrow-band filter are not frequency, the first adjustable carrier frequency amplifier, the second narrow-band carrier frequency filter and phase shifter, as well as the gain control, the first and second comparators, the second square-wave oscillator and the second adjustable amplifier, while the output of the first resonant amplifier of the second intermediate frequency is connected to the inputs of the narrow-band notch carrier frequency filter and the first narrow-band carrier frequency filter, the phase shifter output is connected to the second input of the second adder and the input of the second form square wave oscillator, the output of which is connected to the second input of the phase detector, the output of the second low-pass filter is connected to the inputs of the first and second comparators, the outputs of which are connected to the corresponding inputs of the gain controller, the output of which is connected to the second input of the first adjustable amplifier, the output of the second resonant amplifier is the second intermediate frequency is connected to the input of the amplitude detector, the output of the beat signal driver is connected to the first input of the second adjustable amplifier, W swarm input of which is connected to the output gain control, and the output to the input of the switch.