SU745005A1 - Device for evaluating signal amplitude at the background of noise - Google Patents

Description

The invention relates to a technique for receiving narrowband signals modulated by amplitude and can be used to evaluate signals with an unknown phase with an asymmetric interference energy spectrum operating in a communication channel.

A device is known for estimating the amplitude of signal A with an unknown phase on an interference background, containing a local oscillator, two non-linear converters, two multipliers. The disadvantage of this device is the high level of interference at the output of the device with an asymmetric interference spectrum, as well as the presence of a C11 local oscillator.

A device for estimating the amplitude of an amplitude-modulated Signal is also known, consisting of a band-pass filter, an amplitude detector connected to the output of the band-pass filter, and a low-pass filter connected to the output of the amplitude detector [2J.

The disadvantage of this device is the high level of interference at the output of the amplitude detector with an asymmetric .energy 'interference spectrum.

The aim of the invention is to reduce the level of interference at the output of the amplitude detector when the energy spectrum of the noise is asymmetric with respect to the carrier frequency of the signal.

This goal is achieved by the fact that between the band-pass filter and the low-pass filter, a series-connected limiter, a frequency discriminator, an integrating filter, the output of which is connected to the inputs of two non-linear converters, the outputs of which are connected respectively to the first inputs of two multipliers, the second inputs of which are connected to the output, are additionally connected said amplitude detector, wherein the output of one of the multipliers is connected via a delay line to one input of the subtractor, another output of the multiplier is connected via a Hilbert filter to the second input of the subtractor, the output of which is connected to the input of a lowpass filter.

In FIG. 1 is a block diagram of a device, and FIG. 2-vector diagram explaining his work.

The device consists of a band-pass filter 1, an amplitude detector 2 and a series-connected limiter 3, a frequency discriminator 4, an integrating filter 5, the output of which is connected to two non-linear converters 6 and 7, which perform sine and cosine transforms, respectively, and are connected to their outputs · Multipliers 8, 9, the second inputs of which are connected to the output of the amplitude detector 2. The output of the multiplier 8 is connected to the input of the Hilbert filter 10, and the multiplier 9 is connected to the delay line 11. The outputs of the Hilbert filter 10 and delay lines 11 are connected to the inputs of the subtractor 12, the output of which is connected to the low-pass filter ‘13.

From the vector diagram, it follows that where R (£) is the envelope of the sum of the transmitted message Q (t) and the interference is? (*) N n _s ( _ί ) and n is _the (t) -square and in-phase components of the noise at the output of the bandpass filter, 'f (t) is the phase shift between the transmitted signal Q (0 and the received signal Q. (t) + n (t).

In the case of a one-sided interference spectrum, the quadrature component of the interference can be estimated using the Hilbert transform to obtain an estimate of the common mode component n (t): & __ t-t ^dl The transmitted message estimate Q (I) is found by the formula:

Qit) = COi ^ (t) -n _c (t).

The device operates as follows. ; - ·. '. something ’/'

The signal from the output of the bandpass filter 1 is fed to the amplitude detector 2, where the envelope R (O of the sum of the transmitted signal (ί) and the interference P (7) are highlighted. 'The signal from the output of the bandpass filter 1 also goes to the limiter 3, the frequency discriminator 4 and the lower filter 5 frequencies, at the output of which it is formed.55 an estimate of the phase shift (tΪ between the transmitted signal O (t) and the received signal R (t) = 0 (0 + (O. Next, signal 15 from the output of the low-pass filter 5. ~ arrives at nonlinear devices 6 and 7. for sine and cosine transforms, signals from these devices The signals are fed to the multipliers 8 and 9, which also receive the signal R (с) from the amplitude detector 2. At the output of the multipliers, a signal and R (?) cozy are thus generated. Using Hilbert 10, the in-phase component of the interference P _s (t) is estimated. The output signal from the Hilbert filter 10 is fed to a subtractor 12, which also receives the signal R (t) co $ Jf (/) from the output of the multiplier 9 through the delay line 11. The delay line 11 compensates for the delay in the signal in the Hilbert filter 10. At the output of the subtractor 12 a difference signal P (/) c is generated os'fli;) - / ¾ (- £), which is an estimate of the transmitted message. This estimate is subjected to linear filtering lowpass filter 13. The unit amplitude signal noise background estimates, reduces the noise level by 20 dB + 30 in the case where energy spectrum is interference On the one hand _ι us from the carrier frequency signal, and a significant decrease in the level of interference when cutting. asymmetries of the interference spectrum relative to the carrier frequency of the signal.

Claims (2)

I The invention relates to the technique of receiving amplitude modulated narrowband signals and can be used to estimate signals with an unknown phase with an asymmetrical energy spectrum of interference acting in a communication channel. An apparatus for estimating the amplitude of a signal with an unknown phase against the background noise containing a local oscillator is known. , two nonlinear converters,; sha multiplier. The disadvantage of this device is the high level of the sensor at the output of the device with an asymmetrical interference spectrum, as well as the presence of a local oscillator Li. It is also known a device for estimating the amplitude of an amplitude-modulated signal, consisting of a bandpass filter of an amplitude detector connected to the output of a bandpass filter, and a low-frequency filter connected to the output of amplitude detector C2. The disadvantage of this device is with a large level interference at the output of the amplitude detector with asymmetrical energy spectrum of interference, The aim of the invention is to reduce the level of interference at the output of the amplitude detector at an asymmetrical relative to the carrier hour Ota signal energy spectrum interference. The goal is achieved by connecting a series-connected limiter between the bandpass filter and the low-pass filter, a frequency discriminator, an integrating filter, the output of which is connected to the inputs of two non-linear converters, whose inputs are connected respectively to the first code of the two multipliers, the second inputs of which are connected to the output mentioned amplitude detector, with the output of one of the multipliers connected via a delay line with one input of the subtractor Twa, and the output of another multiplier is connected via a Hilbert filter to the second input of the subtractor, the output of which is connected to a lowpass filter. FIG. 1 shows a block diagram. in FIG. 2 - vector diagram, according to his work. The device consists of a bandpass filter 1, an amplitude detector 2 and successively connected limiter 3, a frequency discriminator 4, an integrating filter 5, to the output of which two nonlinear transducers 6 and 7 are connected, which perform the sine and cosine transformations, respectively, to their the outputs are connected. multipliers 8, 9, the second inputs of which are connected to the BYPASS of the amplitude detector 2. The output of the multiplier 8 is connected to the output of the Gilbert filter 10, and the multiplier 9 to the delay line 11. The outputs of the Hubert filter 10 and the delay lines 11 are connected to the codes of the subtractor 12, the output of which is connected to the low-pass filter 13. From the vector diagram, it follows that P (. (T} –R (t) -), where R () is the envelope the sums yr of the unit & my message E (t) and interference n C), A (f) and (O-square ypia W sinf) as part The components of the interference on the code of the band-pass filter, U. (O is the phase shift between the transmitted signal 9 ( Oh and the received signal Q. (T) + n (i). In the case of a one-way spectrum, the amp & chi on the estimate of the home signal component of the noise can be obtained using the Hilbert transform to estimate the synphasic component of n (t); n, (t), (t, 4J df- ОО V ь Evaluation of the transmitted message Q () is according to the formula: Q (t) R (t) - CO: i: f (t) -rJc (t). The device works Next, the signal from the output of the back-to-edge filter 1 is fed to the amplitude detector 2, where the envelope R is allocated (t} is the perm of the transmitted signal (f) and the interference is P (T). The signal from the bandwidth of the band 1 also goes to the emitter 3, the frequency disc iminator 4 and low pass filter 5, at the output of which an estimate of the phase shift Y {tj between the transmitted signal Q (t) and the received R (OQ (t) + / 7 j) .jDlajiee signal from the output of the filter is formed These frequencies are fed to nonlinear devices 6 and 7 for sine and cosine transforms. The signals from these devices are sent to alternators 8 and 9, which also receive the signal R (O from the amplitude detector 2. At the output of the multipliers, the signal R (t ) -Sin and R () co5y. With the help of Gilbert's 10, it is estimated that it is in phase with () the output signal from the filter of Gilbert 10 goes to the subtractive device 12, which also receives the signal I (t) cosIfiO from the output of the multiplier 9 through delay line 11. Line delay 11 comp siruet delay in the Hilbert filter 10. The output signal of the subtracter 12, a difference signal P () cosfd)) representing an estimate of a transmitted message. This estimate is subjected to linear filtering by a low-pass filter 13. This device estimates the amplitude of the signal against the background noise, provides a reduction in noise level in dB when the interference power spectrum is located on one side of the signal carrier frequency, and a significant decrease in noise level during abrupt asymmetry interference spectrum relative to the carrier signal frequency. Claims device for estimating the amplitude of a signal against a background of noise, containing a series-connected band-pass filter and an amplitude detector, a low-pass filter, characterized in that, in order to reduce the level of interference at the output of the amplitude ijeTeKTopa, when the energy spectrum of the signal is asymmetric with respect to the carrier frequency of the signal, The bandpass filter and the lower frequency filter are additionally connected after; & terminally connected limiter, frequency discriminator, integrating filter, the output of which is connected to the inputs of two nonlinear transducers, whose codes are connected to the first inputs of two multipliers, whose second inputs are connected to the output of the aforementioned-Lp amplitude deut1 {torus, and the output b / from the multipliers is connected via a Delay line with one input of the subtractor y (Aroistev, and the output of the other ifepe- ip is connected through a filter Gilber5 7450056 the one with the second input of the subtractor is 1. 1. Smogilev KA, et al. Radio receivers, the output of which is connected to the microwave input. M., Voennzdat, 1964, p.488du low-pass filter.503.  Sources of information, j solutions. M., Sv eizdat, 1951, p. 21, taken into account in the. Examination (prototype). 2. .Sidorov V .. I. Radio reception lips