SU1596481A1 - Device for receiving frequency-manipulated signals - Google Patents

Abstract

The invention relates to communication technology. The purpose of the invention is to improve the noise immunity. A device for receiving frequency-manipulated signals contains a band-pass filter 1, a Hilberg converter 2, time samplers 3 and 4 signals, delay blocks 5 and 6, multipliers 7-14, adders 15-20, subtractive blocks 21-25, quadgers 26-29 and the decision block 30. The goal is achieved by calculating the extrapolation estimates of the in-phase and quadrature components of the signal when the parcels arrive at known possible frequencies. 1 il.

Description

entrance

Output The invention relates to a communication technique and can be used when receiving frequency-manipulated signals in signal conversion devices. The purpose of the invention is to increase the security gap. The drawing shows a structural electrical circuit of the proposed device. The device contains a Bandpass Filter 1, a Hilbert converter 2, the first, second time sampling jams 3 and 4 of the signal, the first, second blocks 5 and 6 of the delay, the first, fifth,. the sixth, second, third, seventh, eighth and fourth multipliers 7-14, the first - the sixth adders 15-20, the first - the FIFTH subtractive blocks 21-25, quadratures 26-29, the decisive block 30. The device works as follows. The frequency-manipulated signal is a sequence of packages with a known duration and known possible frequencies CJ and W, of these packages. If we consider such a signal as a vector, rotating in a fixed coordinate system with a speed corresponding to the frequency. Parcel, then, knowing the possible frequencies of the posites, we can determine in advance how much the signal will turn - the vector of signal during a known time interval, in this case - for sampling 1. The signal vector is unambiguously described by it, by projections onto fixed coordinate axes, i.e. in-phase and quadrature components. Thus, taking samples of the in-phase and quadrature signal components at a certain time moment t, one can extrapolate; their possible values at time t + (. In other words, knowing the instantaneous position of the received signal vector at time time t, one can predict which the angle is rotated and what position the vector signal will take if it rotates at a frequency u) or at a frequency co for a known time t. Such extrapolation is given in accordance with the expressions s (t + i;) s (t) cosu ; t - S (T) sinwt, s (t + o) (t) co8wa + S (t) 8inft / C. (2) Calculation wire by (1) and (2) for a uJ, t obtain two pairs tional extrapolating estimates of signal samples following. According to the minimum sum of squares of deviations of the obtained estimates from the samples actually taken at the time t + G of the readings, it is decided to accept the parcel at a frequency o / or i. Mathematically, these operations are described by the following expressions (S, -S) + () S (S, -S) + + (s, -s) | (s (S, -S) + (S, -S) () + extrapolation signal estimates in pre-extraction extrapolation estimates into preliminarily taken signal samples. The signal from the communication channel goes to bandpass filter 1, which filters the signal's useful spectrum from out-of-band interference, after which the received signal arrives at time sampler 3, the output of which produces a pulse sequence with a pulse duration equal to the sampling period and an amplitude equal to the instantaneous value of the signal at the time of sampling. bandpass filter 1 is also fed to converter 2, the output of which produces a pulse sequence with a pulse duration equal to the sampling period and an amplitude equal to the instantaneous value of the signal at the time of sampling. The output from bandpass filter 1 also goes to converter 2 at the output which forms the receive quadrature subchannel signal. This signal is time-sampled at the time sampler 4.

Claims (1)

Claim A device for receiving frequency-controlled signals containing a bandpass filter whose input is the device input, a first signal time sampler, the output of which is connected to the first input of the first subtractive unit and the input of the first delay unit, as well as a solver unit whose output is the output of the decision unit that, in order to improve noise immunity,