RU2653150C1 - Method of finding-out of information image of electrical signal - Google Patents

Abstract

FIELD: electricity.

SUBSTANCE: invention relates to processing of electrical signals, namely to methods for finding-out of information image of electrical signal. In method, electrical signal is converted into a digital signal and for each discrete moment, a sampling control is taken on signal time axis. On this sample, a signal model is formed and noise signal is determined as offset between corresponding sampling and model samples. Noise power is estimated and, comparing its level with limer, reveals information image of signal at sampling controls. In order to increase the reliability of recognition of the information image, with help of mentioned signal model, information component is extracted and the specified limer is proportional to its level. It is believed that the information image of the signal corresponds to working one and the sampled control contains information component of signal if noise power is below the limer, otherwise, it is assumed that information image of the signal is inoperative and the sample does not contain information component of the signal. It is suggested to isolate the information component by structural analysis of sampling controls or by using a model in form of hybrid filter or by converting signal into a composite filter of the information component. Noise power is defined as average rectified or root-mean-square value of offset from the sampling controls. In the first case, limer of noise power is determined in proportion to average rectified value of information component of the signal in the sample, in the second case it is proportional to its root-mean-square value.

EFFECT: technical result of the method is an increase in the reliability of finding-out of the information image of electrical signal.

6 cl, 6 dwg

Description

The invention relates to the field of processing electrical signals, and in particular to methods for recognizing the information image of an electrical signal.

A known method of recognizing the information image of an electric signal implemented in a device for monitoring a sensor signal (US 8797047 B2, US 2010060296 (A1) - 2010-03-11, IPC G01R 29/26. Method and device for checking a sensor signal / Zheng-Yu Jiang ; Matthias Kretschmann; Herbert Preis; Christoph Resch), according to which an electrical signal is converted into a digital signal by measuring it at uniformly fixed time points, for each discrete moment on the time axis, a sample of samples is taken, the noise signal is determined as the output signal of the high-pass filter and evaluated noise power as medium ekvadratichnoe value of the noise signal. It is believed that the informational image of the signal corresponds to the working one and the mentioned sample of samples contains the informational component of the signal if the noise power does not exceed the minimum and maximum thresholds of operation, otherwise it is believed that the informational image of the signal corresponds to a non-working one and the sample does not contain the informational component of the signal.

The method responds to an absolute noise level and does not have the ability to change thresholds. Therefore, when the noise level changes due to a drift in the characteristics of the signal source, the method loses its operability.

Closest to the claimed method for use, technical nature and technical result achieved is a method of recognizing an information image of an electrical signal based on determining the signal-to-noise ratio (US 7895006 B2, US 2009164159 (A1) - 2009-06-25, IPC G01R 29 / 26. System and method for determining signal-to-noise ratio (SNR), signal-to-noise and distortion ratio (SINAD) and total harmonic distortion (THD)).

According to it, an electrical signal is converted into a digital signal by measuring it at uniformly fixed time instants, and for each discrete moment, a sample of samples is taken on the time axis. On the indicated sample, the frequency of the prevailing harmonic is estimated and a component model is formed consisting of models of the constant component and higher harmonics of frequencies that are multiples of the frequency of the prevailing harmonic. The noise signal is then determined as the residual between the respective samples of the sample and the model, and the signal-to-noise ratio is calculated as the ratio of the rms value of the model signal to the rms value of the noise. It is believed that the informational image of the signal corresponds to the working one, and said sample of samples contains the informational component of the signal if the signal-to-noise ratio exceeds the threshold, otherwise it is believed that the informational image of the signal is inoperative and the sample does not contain the informational component of the signal.

The signal power used in calculating the signal-to-noise ratio is determined from the totality of the components of the model. Since the signal model is non-adaptive and its order is arbitrary, components that are actually absent in the signal appear in the model. Since the method is not selective for the signal components, the signal-to-noise ratio will be above the threshold even with an insufficiently high level of information component. For example, if the harmonic of industrial frequency is taken as the information component (as is customary in the electric power industry), then the method recognizes the information image as working even if there is no or a low level of harmonic against the background of other components and noise.

This method is adopted as a prototype.

The technical result of the proposed method is to increase the reliability of recognition of the information image of an electric signal.

To this end, in the known method of recognizing the information image of an electrical signal, according to which the electrical signal is converted into a digital signal by measuring it at uniformly fixed time points, for each discrete moment on the time axis of the signal, a sample of samples is taken, a signal model is formed on the specified sample and the signal is determined noise as a residual between the corresponding samples of the sample and model, evaluate the noise power and, comparing its level with a threshold, identify the information image of the signal and sample counts, new operations introduced. Their essence lies in the fact that, in order to increase the reliability of recognition of the information image, using the aforementioned signal model, the information component is extracted and the specified threshold is formed in proportion to its level, and it is believed that the information image of the signal corresponds to the working one and the sample of samples contains the information component of the signal, if the noise power is below the threshold, otherwise it is believed that the information image of the signal is inoperative and the sample mentioned does not contain the information component of the signal .

In the general case, the information component is isolated as a result of a structural analysis of sample samples, which includes sequential operations of tuning an adaptive non-recursive filter to completely suppress a signal, determining the roots of its characteristic equation and generating a component model of the signal from it, and setting the component model based on sample samples.

In another implementation of the method, the information component is isolated using a hybrid filter model, which includes an adaptive filter and a non-adaptive model of the signal information component, which is configured to completely suppress the signal, the information component being obtained by dividing the signal of the non-adaptive model by the adaptive filter information transmission coefficient module component.

In the next implementation of the method, the information component is isolated by converting the signal with a composite filter of the information component formed by the roots of the characteristic equation configured to suppress the signal of the adaptive non-recursive filter with the exception of the roots matched with the information component and dividing the output signal of the composite filter by the module of its transmission coefficient of the information component .

The method may also differ in the approach to determining the threshold and noise power.

The noise power can be defined as the average rectified value of the residual according to sample samples, and the mentioned threshold is proportional to the average rectified value of the information component of the signal in the sample.

In addition, the noise power can be defined as the rms value of the residual for the sample samples, and the threshold is proportional to the rms value of the information component of the signal in the sample.

In FIG. 1 is a flowchart illustrating the proposed method. FIG. 2 illustrates the operation of the method with different options for highlighting the information component - the third harmonic. The recognized signal (Fig. 2, a) contains two intervals of uniformity. On the first of them, the signal contains only the main harmonic of a frequency of 50 Hz with an amplitude of 1.0 relative units (pu) and white noise, and on the second interval, an information component is also added to them - the 3rd harmonic with an amplitude of 0.1 father In FIG. 2b), the identification of the information component and noise by the adaptive model obtained as a result of the structural analysis is presented; FIG. 2c) - a model in the form of a hybrid filter, in FIG. 2d) - a composite model. All models provide recognition of the information image of the signal, in FIG. 2, e) the signal of the sign of the information image is issued: the signal Q = 0 corresponds to the non-working information image, and Q = 1 to the working image.

The essence of the invention is as follows.

Let the electrical signal be represented by readings

where x _i (k) is the information component of the signal, x _r (k) is the sum of the remaining components of the signal, n (k) is the noise signal, k is the reference number. The method works with sampling samples of size L

formed for each discrete moment k on the time axis of the signal.

Signal Model

и сумму оценок остальных компонентов сигнала

.customizable on this sample, in general, contains an estimate of the information component of the signal

and the sum of the estimates of the remaining components of the signal

.

The noise signal is obtained as the difference between the corresponding samples of the sample (2) and model (3):

Assume for convenience of presentation of the essence of the invention that the information component of the signal x _i (k) is a harmonic (in the electric power industry this is usually a harmonic of an industrial frequency of 50 Hz)

в модели (3) тоже будет гармоникойwhere A _i is the amplitude, ω _i is the angular frequency, ψ _i is the initial phase, T _s is the sampling interval. Then the assessment of the information component of the signal

in model (3) will also be a harmonic

whose parameters will be close to the parameters of component (5).

(6) информационной составляющей x_i(k) (5). Если в сигнале выборки присутствует информационная составляющая, то порог R_i будет высокого уровня и намного превосходить мощность шума P_n. Это сигнализирует, что информационный образ сигнала определен как рабочий. Если в сигнале информационная составляющая отсутствует, то порог R_i будет мал и определяться уровнем ошибок и шумов вычисления. Поэтому его уровень будет близок, а может быть, и ниже уровня мощности шума P_n. В этом случае способ определит информационный образ сигнала выборки как нерабочий.The method recognizes the information image of the electric signal in a given sample x (k) (2) by comparing the noise power P _n (4) with a threshold R _i proportional to the estimation level

(6) information component x _i (k) (5). If an information component is present in the sample signal, then the threshold R _i will be high and far exceed the noise power P _n . This signals that the informational image of the signal is defined as working. If there is no information component in the signal, then the threshold R _i will be small and determined by the level of calculation errors and noise. Therefore, its level will be close, and maybe even lower than the noise power level P _n . In this case, the method will determine the information image of the sample signal as inoperative.

It is important to note that the threshold R _{i is} not fixed at one level and is completely determined only by the level of the information component of the signal. Therefore, the method acquires selectivity with respect to the information component, and its operation does not depend on other components x _r (k) of the signal (1).

The method can be implemented in different ways. The options for its implementation depend on the principle of constructing the signal model, the method of estimating the noise power P _n and the principle of forming the threshold R _i .

We begin by considering methods for estimating noise power and the principle of threshold formation, since they are methodologically related to each other. Hereinafter, the noise power is understood as a conditional average value, which serves as a measure of the noise intensity in a signal within a selected sample of samples (2).

One of the methods for determining the noise power (4) is to calculate its average straightened value

Threshold

in this case, it should also be determined in proportion to the average straightened value of the information component

The coefficient λ (sensitivity coefficient) determines the sensitivity of the method: the larger it is, the higher the sensitivity of the method to the level of the information component. The choice of coefficient depends on the specific conditions of application of the method.

In the case of a harmonic information component (5), the value (9) can be determined by its amplitude:

Another method for determining noise power is to calculate its rms value.

The threshold (8) in this case is also determined in proportion to the rms value of the information component

or, in the case of harmonic (5), in proportion to the effective value determined by the amplitude:

Consider methods for extracting the information component x _i (l) and determining the residual (noise) n (k).

In the general case, the information component is isolated as a result of a structural analysis of sample samples.

Structural analysis involves several stages. Adaptive non-recursive filter first

set to the complete suppression of the digital signal x (k) so that the residual e (k) satisfies the least-squares criterion [Antonov V.I., Lazareva N.M., Pulyaev V.I. Methods for processing digital signals of power systems // M., NTF "Energoprogress", "Energetik". 2000. S. 31]. The order of the filter M depends on the number of terms of the electric signal, it is chosen obviously more than the order of the signal.

характеристического уравнения фильтра (14)Then the roots are determined

filter characteristic equation (14)

At the next stage, using the roots of equation (15), a component model of the signal is formed

. Поскольку с информационной составляющей (5) ассоциированы два корня

и

, то модель информационной составляющей (6) будет входить в компонентную модель (16) какand by tuning it to the sample signal also by the least squares method, complex amplitudes are determined

. Since two roots are associated with the information component (5)

and

, then the model of the information component (6) will be included in the component model (16) as

.For the method, it is important to determine the amplitude A _{i of the} information component (5), and, as follows from (16), it will be equal to

.

.The signal noise in this case can be defined either as the residual of the filter (14), i.e. n (k) = e (k), or as a residual of the component model (16), i.e.

.

In another implementation of the method, the signal model is formed as a hybrid filter

where c = B _i cosψ _i and s = B _i sinψ _i are the orthogonal components of the non-adaptive model proportional to the information component of the signal [Antonov V.I., Naumov V.A., Ivanov N.G., Soldatov A.V., Fomin A.I. General principles of the theory of filters of orthogonal components // Relay protection and automation. No. 1. 2016. S. 16-25]. The filter (18) is configured similarly to the adaptive filter (14). An estimate of the amplitude of the information component of the signal is generated from the found orthogonal components of the non-adaptive model, taking into account the modulus of the transmission coefficient of the adaptive part of the filter (18)

at a frequency ω _{i of the} information component:

Here, it is assumed that the signal noise is equal to the residual (18): n (k) = e (k).

In the next implementation of the method, the information component is isolated using a composite model. The model owes its name to the fact that it is a combination of blocking filters of all signal components, except for the information one, and is formed on the basis of an adaptive filter (14) configured to completely suppress the signal. The desired information component appears as a result of the signal conversion by this set of blocking filters, i.e. as an output signal of a composite filter.

To obtain a composite filter, the first two stages of structural analysis are carried out, during which the filter (14) is adjusted and the roots of the characteristic equation (15) are determined:

и

, ассоциированные с информационной составляющей. Пользуясь множеством оставшихся корней формируется характеристический полином составного фильтраFurther, the roots are excluded from the set (21) of roots

and

associated with the information component. Using the set of remaining roots, the characteristic polynomial of the composite filter is formed

According to polynomial (22), the composite filter will take the following form:

The output signal of the composite filter will contain a signal proportional to the desired information component of the signal

Since it is important for the method to correctly evaluate the amplitude of the information component, for the correct operation of the method it is enough to adjust only the signal amplitude (24), forming the image of the information component according to (6) in the form of an estimate

Здесьnot attaching importance to the determination of the initial phase

Here

Where

the transmission coefficient modulus of the composite filter (23) at the frequency ω _{i of the} information component.

. Мощность шума P_n достаточно высока и превышает порог, способ фиксирует информационный образ этого интервала как нерабочий, устанавливая признак Q=0. На втором интервале в сигнале обнаруживается информационная составляющая достаточной мощности, чтобы ее уровень, учитываемый в пороге R_i, превышал мощность шума P_n. Поэтому все модели формируют достаточные условия для фиксации признака, что информационный образ сигнала на втором интервале рабочий, т.е. Q=1.Since all models in one way or another determine the amplitude of the information component, they all do a good job of recognizing the information image of the signal. As can be seen from FIG. 2b) -d), in the first interval of uniformity, the information component is absent, and the threshold

. The noise power P _{n is} quite high and exceeds the threshold; the method captures the information image of this interval as non-working, setting the sign Q = 0. In the second interval, an information component of sufficient power is detected in the signal so that its level, taken into account in the threshold R _i , exceeds the noise power P _n . Therefore, all models form sufficient conditions for fixing the sign that the information image of the signal on the second interval is operational, i.e. Q = 1.

It should be noted that the use of a composite filter (Fig. 2, g). It consists in the fact that the composite filter forms an estimate of the information component directly from the input signal, passing it through itself. Therefore, on the part of the time axis, there is no evaluation of the information component.

The problem of dividing the signal into intervals is not considered here, since it has independent significance.

Thus, due to the formation of the threshold in proportion to the level of the information component of the signal, it was possible to increase the recognition accuracy of the information image of the electric signal.

Claims (6)

1. A method of recognizing an information image of an electrical signal, according to which the electrical signal is converted into a digital signal by measuring it at uniformly fixed time points, for each discrete moment on the time axis of the signal, a sample of samples is taken, a signal model is formed on the specified sample and the noise signal is determined as a residual between the corresponding samples of the sample and the model, the noise power is estimated and, comparing its level with a threshold, the information image of the signal in the sample samples is revealed, excellent characterized in that, in order to increase the reliability of recognition of the information image, using the aforementioned signal model, the information component is extracted and the specified threshold is formed in proportion to its level, and it is believed that the information image of the signal corresponds to the working one and said sample of samples contains the information component of the signal if the noise power below the threshold, otherwise it is believed that the information image of the signal is inoperative and the sample mentioned does not contain the information component of the signal. 2. The method according to p. 1, characterized in that the information component is isolated as a result of a structural analysis of sample samples, which includes sequential operations of tuning an adaptive non-recursive filter to completely suppress the signal, determining the roots of its characteristic equation and forming a component signal model from it, tuning component model by sample samples. 3. The method according to p. 1, characterized in that the information component is isolated using a model in the form of a hybrid filter, which includes an adaptive filter and a non-adaptive model of the information component of the signal, which is configured to completely suppress the signal, and the information component is obtained by dividing the signal of said non-adaptive models per module of the coefficient of transmission of an adaptive filter of the information component. 4. The method according to p. 1, characterized in that the information component is isolated by converting the signal with a composite filter of the information component formed by the roots of the characteristic equation configured to suppress the adaptive non-recursive filter signal with the exception of the roots matched with the information component and dividing the composite output signal filter to the module of its transmission coefficient of the information component. 5. The method according to PP. 1, 2, 3 or 4, characterized in that the noise power is defined as the average rectified value of the residual according to the sample samples, and the threshold is proportional to the average rectified value of the information component of the signal in the sample. 6. The method according to PP. 1, 2, 3 or 4, characterized in that the noise power is defined as the rms value of the residual for the sample samples, and the threshold is proportional to the rms value of the information component of the signal in the sample.

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