SU1167754A1 - Receiver of frequency-shift keyed signals with continuous phase - Google Patents

Abstract

A RECEIVER OF FREQUENCY-MANIPULATED SIGNALS WITH CONTINUOUS PHASES, containing the first multiplier, output connected to the filter, phase-locked loop, the output of which through the serially connected second multiplier, the first integrator and the first decision unit connected to the first section of the charm, and the first integrator and the first decision unit connected to the first input of the switch, and the first integrator and the first crucial unit connected to the first section of the charm, and the first integrator and the first crucial unit connected to the first chases, connected to the first input of the switch, and the first integrator, the first integrator and the first crucial unit connected to the first section of the chapters the second integrator and the second decision unit with the second input of the switch, characterized in that, in order to improve the noise immunity , a sequentially connected controlled clock generator, a second phase shifter, a fourth, fifth and sixth multipliers, a frequency divider and two square pulse shapers are inputted, the output of the controlled clock generator, frequency is connected through the first shaper of the square pulse to another input of the first integrator , the output of the first square pulse driver is connected via a frequency divider to the third input of a switch, the output of which is connected to another input of the fifth multiplier body, the output of which is connected to the input of the phase locked loop and to the first input of the first multiplier, the second input of which is connected to the output of the first phase shifter, the output of the controlled clock generator is connected to one input of the sixth Q multiplier, the other input (L combined with another input the fourth multiplier and is the receiver input, the output of the second phase shifter through the second square pulse shaper is connected to another input of the second integrator, the output of the fourth multiplier The body is connected to another input of the third non multiplier, the output of the sixth multiplier O5 is connected to another input of the second multiplier, and the output of the filter is connected to the input of the controlled clock frequency generator. N

Description

The invention relates to radio and can be used in systems for the transmission of discrete messages over radio channels.

A known receiver comprising a multiplier, the output of which is connected via a series-connected phase discriminator, a low-pass filter and a controlled oscillator connected to the input of the phase shifter, the output of which is connected to another input of the phase discriminator 1.

The closest to the present invention is a receiver of frequency-manipulated signals with a continuous phase, comprising a first multiplier, an output connected to a filter, a phase locked loop unit, the output of which is connected through the second multiplier through the second multiplier, the first integrator and the first decisive block is connected to the first input of the switch and sequentially the first phase shifter, the third multiplier, the second integrator, and the second deciding unit, are connected with the second input of the switch 2.

However, the known receivers have insufficient noise immunity.

The purpose of the invention is to increase noise immunity.

The goal is achieved by the fact that the receiver of frequency-controlled signals with a continuous phase, containing the first multiplier, the output connected to the filter, the phase locked loop, whose output through the serially connected second multiplier, the first integrator and the first solver unit is connected to the first input of the switch and through serially connected first phase shifter, the third multiplier, the second integrator and the second decisive block — with the second inlet of the switch, are introduced in series e controlled clock generator, second phase shifter, fourth, fifth and multiple multipliers, frequency divider and two square pulse shapers, with the output of the controlled clock frequency generator connected to the other input of the first integrator through the first square pulse shaper, the output of the first shaper rectangular pulses through a frequency divider connected to the third input of the switch, the output of which is connected to another input of the fifth multiplier, the output of which is connected to the input b phase locked loop and with the first input of the first multiplier, the second input of which is connected to the output of the first phase shifter, the output of the controlled clock generator is connected to one input of the sixth multiplier, the other input of which is combined with the other input of the fourth multiplier and is the input of the receiver, the output of the second the phase shifter is connected to the second input of the second integrator via the second square pulse shaper, the output of the fourth multiplier is connected to the other input of the third variable the resident, the output of the multiplier is connected to another input of the second multiplier, and the filter output is connected to the input of the controlled clock frequency generator.

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

The receiver of the frequency-manipulated signals contains the fourth 1, 2, second, 3, third 4 multipliers, the first 5 and second 6 integrators, the first 7 and second 8 decision blocks, switch 9, a controlled oscillator 10 clock frequency, the second phase shifter 11, the fifth 12 and the first 13 multipliers, filters 14, the second shaper 15 rectangular pulses, frequency divider 16, the first shaper 17 rectangular pulses, phase locked loop 18, the first phase shifter 19.

The receiver works as follows.

The incoming signal is fed to the inputs of the multipliers 1 and 2 frequencies, to the other inputs of which signals from the controlled oscillator 10 are supplied are straight and shifted by the phase shifter 11 in phase by 90 ° C. The outputs of the multipliers 1 and 2 of the system are fed to the multipliers 3 and 4 frequencies, where the second inputs of the frequency multipliers also receive direct and shifted in phase by 90 ° due to the phase rotator 19 signals from the reference high frequency generator (not shown) entering the the composition of the block 18, carrying the oscillations, and the generated signals in the channels. fed through integrators 5 and 6 and decision blocks 7 and 8 to switch 9 of the output channels, which connects the channel to the receiver output in accordance with a clock frequency equal to half the pulse frequency coming from the controlled generator 10 through the driver 17 and the divider 16 by two clock speeds. The former 17 generates square pulses from a sinusoidal signal generated by the controlled generator 10. The integrators 5 and 6 are reset by the signals of the controlled generator 10, which feed through the drivers 17 and 15, and the integrator 6 receives the signal from the controlled generator 10 through the phase shifter 11. Duration integration is equal to the duration of two information packages, and the beginning of the integration time is shifted in time in integrators 5 and 6 relative to each other for the duration of one information package and. . For the operation of the information symbol allocation scheme, it is necessary to synchronize the frequency and phase of the carrier wave and the clock frequency of the information symbols. The operation of these systems in the proposed device is carried out as follows. The signal taken from the frequency multiplier 1 is fed to the input of the multiplier 12, the second input from which switches information symbols 9, as a result of which the input signal is removed in the multiplier 12 and the sinusoidal signal of the carrier oscillation of the main current is introduced into the unit 18, where the mismatch error of the input and reference signals of the carrier frequency is minimized. As a result, unit 18 operates on the main carrier current and generates a signal to perform synchronous detection in the information symbol extraction system. The signal after multiplier 12, where manipulation is removed, contains a clock error signal, which is fed to a non-multiplier 13, to the second input of which a carrier wave signal is generated from block 18, and from the output of multiplier 12, a clock frequency error signal is fed to filter 14, which generates a signal which changes the frequency of the controlled oscillator 10 in accordance with the error signal taken from the multiplier I. Thus, in the proposed device, quasi-coherent reception of information frequency-response modulator is performed. Continuous phase symbols, where block 18 operates on the main current of the carrier frequency, which increases its noise immunity compared to the known, increasing the overall noise immunity of the receiver of frequency-manipulated signals with a continuous phase.

Claims (1)

RECEIVER OF FREQUENCY MANIPULATED SIGNALS WITH CONTINUOUS PHASE, comprising a first multiplier output connected to a filter, a phase-locked loop, the output of which is connected through a second multiplier, a first integrator and a first deciding unit connected to the first input of the switch and the third phase shifter connected in series, the third phase shifter, the third the second integrator and the second decision unit with the second input of the switch, characterized in that, in order to increase the noise immunity, enter s are connected in series by a controlled clock generator, a second phase shifter, a fourth, fifth and sixth multipliers, a frequency divider and two shapers of rectangular pulses, the output of a controlled clock and frequency generator connected through the first shaper of rectangular pulses to another input of the first integrator, the output of the first shaper rectangular pulses through a frequency divider connected to the third input of the switch, the output of which is connected to another input of the fifth multiplier, the output to connected to the input of the phase locked loop and to the first input of the first multiplier, the second input of which is connected to the output of the first phase shifter, the output of the controlled clock generator is connected to one input of the sixth g multiplier, the other input of which is combined with the other input of the fourth multiplier and is the input of the receiver , the output of the second phase shifter through the second driver of rectangular pulses is connected to another input of the second integrator, the output of the fourth multiplier is connected to another the input of the third multiplier, the output of the sixth multiplier is connected to another input of the second multiplier, and the output of the filter is connected to the input of a controlled clock generator.