SU1601775A1 - Demodulator of frequency-manipulated signals - Google Patents

Abstract

The invention relates to radio engineering. The purpose of the invention is to increase speed. For this, the demodulator contains frequency detectors 1 and 5, synchronized oscillators (CA) 2 and 3, multiplexer 4, r-r 6 clock pulses, amplitude selector 7, delay block 8, triggers 9 and 10, and inverter 11. CA 2 and 3 can operate in two modes, "noise-free" or "increased speed", which differ in the synchronization bandwidth, with each CA 2 and 3 tuned to its own specified frequency. When the frequency of the input signal jumps, the CA 2 and 3 modes switch, and the CA, which was in the "high speed" mode before the frequency jump, quickly works out the frequency jump and then goes into the "noise-immune" mode. The other CA, which was in a noise-tolerant "mode" before the frequency jump, slowly begins to work out the jump, and then switches to the "faster performance" mode. 1 sludge.

Description

The invention relates to radio engineering and can be used in communication systems with frequency manipulation.

The purpose of the invention is improving performance. j

The drawing shows a structural electrical diagram of the proposed demodulator.

The demodulator contains a first frequency {detector 1, first 2 and second 3 synchronized oscillators, multiplexer 4, second frequency detector 5, clock generator 6, amplitude selector 7, delay unit 8, second 9 and first 10 D-flip-flops, inverter 11.

The demodulator works as follows- 1! at once.

The frequency-mamulated intermediate frequency signal simultaneously arrives {at the inputs of the frequency detector 5 and synchronized oscillators 2 and 3, which can operate in two modes: "noise-resistant" or "increased speed", which differ in the synchronization bandwidth, and synchronized oscillator 2 is tuned to the frequency Fi, and the synchronized oscillator 2 torus 3 to the frequency F2. When the frequency of the input signal jumps with the help of the frequency detector 5, trigger 10 and inverter 11, the modes of synchronized oscillators are switched, and the synchronized oscillator, which was in the “high speed” mode before the frequency jump, quickly fulfills the frequency jump and then switches to the “noise-resistant” mode. The other, which was before the frequency jump in. "Noise-tolerant" mode, slowly begins to work out the jump, and then switches to the "increased speed" mode. In this case, the multiplexer 4 is switched so that it connects to the input of the frequency detector 1 a self-synchronized self-oscillator, which is at that moment in the “noise-resistant” mode. A useful signal from the output of the frequency detector 5 is fed to the D-input of the D-trigger 10.

The signal from the output of the frequency detector 1 is supplied to the amplitude selector 7; where the synchronization pulses of the generator 6 are allocated, in which they generate pulses with a repetition period equal to the duration of the digital signal discrete, which synchronize the D-trigger 10 and through block 8 go to the C-input of the D-trigger 9. The delay is necessary to ensure the reading of the level of the useful signal ^J closure after transients in the path.

Claims (1)

'Claim A frequency-manipulated signal demodulator containing a first synchronized oscillator and a first frequency detector, characterized in that, in order to improve performance, a second synchronized oscillator, a second frequency detector, a multiθ plexor, an amplitude selector, a clock generator, a delay unit, two D -trigger, inverter, and the inputs of synchronized oscillators and the input of the second frequency detector are connected and are the input of the demodulator, the outputs of the first and second synchronized These oscillators are connected to the corresponding inputs of the multiplexer, the control input of which is connected to the control input of the first synchronized oscillator: 0 torus, the inverter input and connected to the output of the first D-trigger, the D-input of which is connected to the output of the second frequency detector, and the C-input is connected to the output of the clock generator, the inverter output is connected to the control input of the second synchronized self-oscillator, the multiplexer output is connected to the input of the first frequency detector, the output of which dklyuchen amplitude to the input selector and the D-input of the second D-flip-flop, the output 0 of the amplitude selector connected to an input of the clock, the output of which is coupled via a delay unit to the C-input of the second D-flip-flop, whose output is the output of the demodulator.