RU109942U1 - ADAPTIVE INTERFERENCE COMPENSATOR - Google Patents

Abstract

 An adaptive interference compensator comprising a main channel — an adaptive signal model former, characterized in that a compensation channel is introduced — an adaptive noise model former, the main channel consisting of a first ADC, a first white noise generator, a first addition block, a first delay block, a first adaptive filter and the first subtraction block; the compensation channel consists of a second ADC, a second white noise generator, a second addition block, a second delay block, a second adaptive filter and a second subtraction block; the adaptive compensator also contains: the third and fourth adaptive filters, the third block of subtraction and DAC; The adaptive compensator has the following connections: the input signal is a mixture of the useful signal and the noise - it is connected to the input of the first ADC and to the inputs of the third and fourth adaptive filters, the output of the first ADC is connected to the first input of the first addition unit and through the first delay unit to the first input of the first subtraction unit , the output of the first white noise generator is connected to the second input of the first addition unit, the output of which through the first adaptive filter is connected to the first input of the first subtraction unit, the output of which is the first feedback bus the communication is connected to the feedback inputs of the first and third adaptive filters; the reference interference signal is connected through the second ADC to the first input of the second addition unit and through the second delay unit to the second input of the second subtraction unit, the second white noise generator is connected to the second input of the second addition unit, the output of which is connected to the second adaptive filter, the output of which is through the second unit subtracting second shea

Description

The utility model relates to radio electronics and can be used to increase the effectiveness of the fight against interference caused by extraneous technical means in the systems for receiving and processing information, communications, industrial and medical technical devices.

The general problem of receiving and processing useful signals against interference is the following. The loading of a number of ranges of the radio spectrum has now reached such a level when measures of frequency regulation have become insufficient to ensure electromagnetic compatibility of simultaneously operating radio equipment. In these ranges, one of the main factors limiting the effective functioning of radio communications is mutual interference. Therefore, the problem of protecting radio communication lines from electromagnetic radiation created by extraneous radio means occupying the same or adjacent frequency bands has become very urgent. Such radiation, the spectra of which completely or partially intersect with the spectrum of the useful signal, are often called concentrated on the spectrum or station interference. Station interference is classified as structural or, more precisely, structurally determined interference (hereinafter referred to as interference LED), bearing in mind a certain regularity of the structure of high-frequency modulated radio signals. A special role is played by interference from extraneous radio equipment in special reception conditions, characterized by a weak energy of useful signals, unique binding to a given communication channel, and the need to ensure the secrecy of transmitted signals.

Of particular interest is the synthesis and analysis of optimal signal receivers when exposed to station noise modeled by known types of random processes (in particular, Gaussian and Markov ones).

An analysis of publications on the issue raised shows that among a number of known methods for controlling station interference, the most common are methods based on the use of adaptive interference compensators in the receiving equipment. This choice is primarily due to the fact that these methods are sufficiently universal and have high potential effectiveness.

However, despite the abundance of publications on this topic, the creation of a general theory of adaptive interference compensators is not yet complete.

Adaptive interference compensation is an optimal filtering method that can always be applied when there is a suitable reference input signal. The principal advantages of this method are the invariance of the circuit with respect to the class of signals and their parameters, a low level of noise at the output, and small introduced signal distortions. This method leads to a stable system that automatically shuts off if there is no improvement in the signal-to-noise ratio. In auto-compensators of interference using an adaptive filter, effective interference suppression occurs only when the interference components at both inputs of the auto-compensator are mutually correlated [1-3].

The technical task of the utility model is to increase the efficiency of suppressing interference into the path of receiving useful signals, moreover, by unknown or variable parameters of interfering signals.

To solve this problem, an adaptive interference compensator is proposed, comprising a main channel — an adaptive signal model former, characterized in that a compensation channel is introduced — an adaptive noise model former, the main channel consisting of a first ADC, a first white noise generator, a first addition block, a first block delay, the first adaptive filter and the first subtraction block; the compensation channel consists of a second ADC, a second white noise generator, a second addition block, a second delay block, a second adaptive filter and a second subtraction block; the adaptive compensator also contains: the third and fourth adaptive filters, the third subtraction unit and the DAC; The adaptive compensator has the following connections: the input signal is a mixture of the useful signal and the noise - it is connected to the input of the first ADC and to the inputs of the third and fourth adaptive filters, the output of the first ADC is connected to the first input of the first addition unit and through the first delay unit to the first input of the first subtraction unit , the output of the first white noise generator is connected to the second input of the first addition unit, the output of which through the first adaptive filter is connected to the first input of the first subtraction unit, the output of which is the first feedback bus communication with the feedback inputs of the first and third adaptive filters; the reference interference signal is connected through the second ADC to the first input of the second addition unit and through the second delay unit to the second input of the second subtraction unit, the second white noise generator is connected to the second input of the second addition unit, the output of which is connected to the second adaptive filter, the output of which is through the second unit subtracting the second feedback bus is connected to the feedback inputs of the second and fourth adaptive filters, and the outputs of the third and fourth adaptive filters are connected to the first and second inputs of the third block Itani ,, whose output is connected to the input of the DAC, the last output is the output of the compensator.

Each of the channels is a shaper of an adaptive signal model, in which a white noise forming is mixed with the input signal.

The signal channel is designed to form a model of a noisy signal (a mixture of the useful signal and interference). The channel input signal is a noisy signal (s + d ₁ ). In the process of model formation (using the appropriate adaptation algorithm), the impulse response of adaptive filter 1 (AF1) is rebuilt so that the filter output signal has the best approximation to the useful signal (s + d ₁ ). In other words, rebuilding the weight coefficients, thereby forming a model of the desired signal, presented in the form of filter coefficients AF1.

The operation of the compensation channel is identical. In the process of forming weights, the adaptive filter 2 (AF2) is adjusted so that the signal at the filter output has a maximum approximation to the required reference noise d ₂ . In this case, a reference interference model d _{2 is formed} .

Then the resulting coefficient of the model adaptive interference compensator is determined as the difference between the optimal transmission coefficients of adaptive filters AF1 and AF2:

where S _S (ω) is the spectral power density of the signal;

S _d (ω) is the spectral density of the interference power;

S _υ (ω) is the spectral power density of the forming white noise.

To make an expression to zero, it is necessary that the ratio of the power of the noise-forming noise in the signal channel (q ₂₁ ) and the ratio of the power of the noise-forming noise in the compensation channel (q ₂₂ ) are equal. Those.

q ₂₁ = q ₂₂ = q ₂

In this case, f.1 can be rewritten as

If the ratio of the power of the noise-forming noise in the channels (q ₂ ) is chosen significantly less than unity, then the transfer characteristic of the two-channel model compensator can be represented as

Those. With this choice of power for generating white noise, the described model adaptive noise canceller is a quasi-optimal linear filter, the parameters of which are adjusted in such a way as to effectively suppress the noise.

Using the developed software “Model interference canceller”, modeling of the operation of the model adaptive interference compensator was carried out. In the experiments, the dependence of the loss of the optimal filter l on the signal-to-noise ratio η was studied. The following results are obtained.

The optimal filter refers to a linear filter with constant parameters, the input of which acts the signal s and interference d ₁ having a Gaussian distribution, the dispersion of the filtering error at the output of which [4]:

The relative loss to the optimal filter is expressed through the ratio of the variance of the filtering error at the output of the model compensator and at the output of the optimal linear filter:

The simulation parameters are shown in Table 1, the simulation results are shown in Figure 2. The Gaussian-Markov process was chosen as a useful signal. Interference - white Gaussian noise, interference in the channels mutually uncorrelated.

Parameter Value Signal bandwidth 3354 Hz Sample size for estimation l 65536 Number of samples to average l 10 The number of weights 256 Filter Adaptation Factor 0.001 Filter Adaptation Algorithm least squares method [2]

Figure 1 shows a generalized block diagram of an adaptive interference compensator, figure 2 is a structural electrical diagram, figure 3 is a work simulation diagram - the dependence of the loss l on the signal-to-noise ratio η at q ₂ = -10 dB (solid line) , at q ₂ = -6 dB (dash-dotted line), at q ₂ = 0 dB (dashed line).

Figures 1 and 2 show: 1 and 2 - the first and second ADCs, respectively, 3 and 4 - the first and second white noise generators, respectively, 5 and 6 - the first and second white noise generators, respectively, 7 and 8 - the first and second blocks delays (in numbers), respectively, 9, 10, 11 and 12 - first-fourth adaptive filters (digital), respectively, 13, 14 and 15 - first-third subtraction blocks, respectively, 16 - DAC, S + d ₁ - compensator input (mixture useful signal and interference), d ₂ - reference interference, the output of the compensator is an estimate of the useful signal.

The structural electrical circuit has the following connections. An adaptive interference compensator comprising a main channel — an adaptive signal model former; a compensation channel — an adaptive noise model former is also introduced, the main channel consisting of a first ADC, a first white noise generator, a first addition block, a first delay block, a first adaptive filter and a first block subtraction; the compensation channel consists of a second ADC, a second white noise generator, a second addition block, a second delay block, a second adaptive filter and a second subtraction block; the adaptive compensator also contains: the third and fourth adaptive filters, the third subtraction unit and the DAC; The adaptive compensator has the following connections: the input signal is a mixture of the useful signal and the noise - it is connected to the input of the first ADC and to the inputs of the third and fourth adaptive filters, the output of the first ADC is connected to the first input of the first addition unit and through the first delay unit to the first input of the first subtraction unit , the output of the first white noise generator is connected to the second input of the first addition unit, the output of which through the first adaptive filter is connected to the first input of the first subtraction unit, the output of which is the first feedback bus communication with the feedback inputs of the first and third adaptive filters; the reference interference signal is connected through the second ADC to the first input of the second addition unit and through the second delay unit to the second input of the second subtraction unit, the second white noise generator is connected to the second input of the second addition unit, the output of which is connected to the second adaptive filter, the output of which is through the second unit subtracting the second feedback bus is connected to the feedback inputs of the second and fourth adaptive filters, and the outputs of the third and fourth adaptive filters are connected to the first and second inputs of the third block Itani ,, whose output is connected to the input of the DAC, the last output is the output of the compensator.

The nodes and blocks of the compensator can be performed on the following IC.

The analog-to-digital converter is made on the AD876 IC of the Analog Device company [2]; The digital-to-analog converter is made on the AD7390 IC of the Analog Device company [2]; White noise generators are made on IC K561IR2 and K561LP2 [3]; Digital adaptive filters are made on a digital signal processor ADSP2181 from Analog Device [4]; The operation “addition”, the operation “subtraction” and digital delay are implemented as part of the digital adaptive filter 1 on the ADSP2181 [4]; or on one Philips LPC2124 microcontroller.

Claims (1)

An adaptive interference compensator comprising a main channel, an adaptive signal model former, characterized in that a compensation channel is introduced, an adaptive noise model former, the main channel consisting of a first ADC, a first white noise generator, a first addition block, a first delay block, a first adaptive filter and the first subtraction block; the compensation channel consists of a second ADC, a second white noise generator, a second addition block, a second delay block, a second adaptive filter and a second subtraction block; the adaptive compensator also contains: the third and fourth adaptive filters, the third subtraction unit and the DAC; The adaptive compensator has the following connections: the input signal is a mixture of the useful signal and the noise - it is connected to the input of the first ADC and to the inputs of the third and fourth adaptive filters, the output of the first ADC is connected to the first input of the first addition unit and through the first delay unit to the first input of the first subtraction unit , the output of the first white noise generator is connected to the second input of the first addition unit, the output of which through the first adaptive filter is connected to the first input of the first subtraction unit, the output of which is the first feedback bus the communication is connected to the feedback inputs of the first and third adaptive filters; the reference interference signal is connected through the second ADC to the first input of the second addition unit and through the second delay unit to the second input of the second subtraction unit, the second white noise generator is connected to the second input of the second addition unit, the output of which is connected to the second adaptive filter, the output of which is through the second unit subtracting the second feedback bus is connected to the feedback inputs of the second and fourth adaptive filters, and the outputs of the third and fourth adaptive filters are connected to the first and second inputs of the third block Itani, whose output is connected to the input of the DAC, the last output is the output of the compensator.