CN110944354A - Base station interference monitoring method and system based on waveform analysis and deep learning - Google Patents

Abstract

The invention discloses a base station interference monitoring method based on waveform analysis and deep learning, which is characterized in that data required by interference monitoring of an LTE system is acquired; screening out a high uplink interference cell according to the acquired network management data; carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing the similarity, and marking the base station faults; feeding back the interference wave type obtained by primary matching to the grid in a thermodynamic mode according to the GPS position of the base station to obtain a grid thermodynamic diagram; establishing an interference prediction model based on a deep neural network; and updating the grid thermodynamic diagram and the interference experience base according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model. The method and the device perform interference wave matching based on the similarity, and provide directional guidance for technical personnel to inquire fault sources by combining graphical deep network prediction, thereby improving the accuracy and efficiency of base station interference monitoring.

Description

Base station interference monitoring method and system based on waveform analysis and deep learning

Technical Field

The invention relates to the technical field of mobile communication, in particular to a base station interference monitoring method and system based on waveform analysis and deep learning.

Background

In the daily optimization process of a mobile communication network, the positioning analysis and optimization of interference is one of the key tasks. The currently adopted high uplink interference positioning technology needs to consider multi-dimensional interference characteristics such as frequency domain, time domain, space and the like to correlate and position interference factors. Due to the complex and various factors of high uplink interference, the position of the interference source and the interference information are difficult to judge quickly and accurately, and certain experienced technicians are needed; meanwhile, as the acquisition and operation of the features are complex, a large amount of manpower and material resources are consumed in the process, so that the positioning time of the interference information is slow, and the positioning accuracy is low.

In addition, most of the existing high uplink interference positioning technologies aim at regional position information, recognize limited interference factors and perform manual matching. In a larger area, the maintenance cost is directly increased, and the interference diversity is more complicated, so that the interference is difficult to position in the larger area, and the high-accuracy fault prediction and prediction are not facilitated.

Disclosure of Invention

The invention provides a base station interference monitoring method and system based on waveform analysis and deep learning, and aims to solve the problems that the existing high uplink interference positioning technology is slow in positioning time, low in positioning accuracy and small in positioning area range.

In order to achieve the above purpose, the technical means adopted is as follows:

the base station interference monitoring method based on waveform analysis and deep learning comprises the following steps:

s1, collecting data required by interference monitoring of an LTE system;

s2, screening out a high uplink interference cell according to the acquired network management data;

s3, carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing similarity, and marking base station faults;

s4, feeding back the interference wave type obtained by primary matching to the grid in a thermal form according to the GPS position of the base station to obtain a grid thermodynamic diagram;

s5, establishing an interference prediction model based on a deep neural network, wherein the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is a predicted interference type of the high uplink interference cell;

and S6, updating the grid thermodynamic diagram and an interference experience library according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

In the scheme, interference wave matching is carried out based on the similarity, and graphical deep network prediction is combined, compared with a single-point base station interference wave matching method based on the similarity, the method can be used for correlating the influence of other base stations in the grid thermodynamic diagram on a base station to be monitored, forming area monitoring, clearly and intuitively seeing the influence range of the fault and general fault information on the grid thermodynamic diagram, and providing directional guidance for technical personnel to inquire the fault source, so that the accuracy and the efficiency of base station interference monitoring are improved. In addition, the accuracy of the interference prediction model may be continually improved based on the empirical accumulation of troubleshooting each time.

Preferably, the data in step S1 includes XDR information, network management information, and 4G LTE parameters information.

Preferably, the step S3 specifically includes the following steps:

s31, calculating the shortest algorithm distance between the given waveform in the high uplink interference cell and the matched waveform in a preset interference experience library;

and S32, ascending sorting is carried out on the shortest algorithm distances obtained through calculation, the matchable waveform types corresponding to the first N shortest algorithm distances are selected as the initial matching interference wave types of the high uplink interference cell, and the base station fault is marked.

Preferably, the method for calculating the shortest algorithm distance in step S31 includes:

let a be any real number, calculate the minimum value of the solution formula, i.e.

Minimum value of (d);

wherein j is 1,2,3, 100, which is the PRB value; x denotes a given waveform, x^jFor the jth data in a given waveform; y isⁱIdentifying matchable waveforms, y_i ^jThe j data in the i-th matchable waveform; wherein a is used for eliminating the difference caused by control translation;

and expanding the solving formula:

the minimum value of the formula solved by the matching method is:

preferably, the step S4 specifically includes: expressing different interference wave types on the grid in different colors in the initial matching interference wave types obtained in the step S3, and setting color depth according to the interference wave influence range to obtain a grid thermodynamic diagram; wherein the latitude and longitude values of the base station form the vertices of the grid. In the preferred scheme, the color depth is set according to the influence range of the interference wave, namely, for example, the loss of step of the GPS can cause the square circle to be several kilometers, so that the thermal value of the interference wave fault is very large; for example, a single point of influence failure, the thermal value is small.

Preferably, the interference prediction model based on the deep neural network in step S5 includes a covn convolution unit, N residual units, and a conv output layer, which are connected in sequence; wherein the covn input layer is used for extracting the image characteristics of the grid thermodynamic diagram, and the convolution of the image characteristics is X_c ⁽¹⁾＝f(W_c ⁽¹⁾*X_c ⁽⁰⁾+b_c ⁽¹⁾)；

Wherein, f is special convolution for ensuring that the output and the input are the same;

the mathematical model of the residual error unit is X_c ^(l+1)＝X_c ^(l)+F(X_c ^(l)；θ_c ^(l)),l＝1,2,...,L

Where F is the residual equation, θ_c ^(l)All parameters needing to be learned in the first layer are contained;

obtaining a predicted interference type X_c ^(L+1)And outputting by a conv output layer.

In the preferred embodiment, since the obtained image information of the grid thermodynamic diagram is not much, and the size of each grid thermodynamic diagram is 32 × 32, it is not necessary to use a multi-level deep neural network.

Preferably, a hyperbolic tangent function tanh and an optimization function minimizlos are connected behind a conv output layer of the interference prediction model; the hyperbolic tangent function tanh is used for standardizing the predicted value output by the covn output layer, and the optimization function minimizloss is used for calculating the metric value of the predicted value and the true value output by the interference prediction model, namely:

wherein X_tIn order to be a matrix of predicted values,

is a true value matrix.

Preferably, the predicted value is normalized by the hyperbolic tangent function tanh and then is located in the range of [ -1,1 ].

The invention also provides a base station interference monitoring system based on waveform analysis and deep learning, which comprises:

the data acquisition module is used for acquiring data required by interference monitoring of the LTE system;

the high uplink interference cell screening module is used for screening out the high uplink interference cell according to the acquired network management data;

the interference wave type primary matching module is used for carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing similarity and marking base station faults;

the grid thermodynamic diagram building module is used for feeding back the interference wave type obtained by primary matching to a grid in a thermodynamic mode according to the GPS position of the base station to obtain a grid thermodynamic diagram;

the interference prediction model building module is used for building an interference prediction model based on a deep neural network, the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is the predicted interference type of the high uplink interference cell;

and the interference optimization module is used for updating the grid thermodynamic diagram and the interference experience base according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

Compared with the prior art, the technical scheme of the invention has the beneficial effects that:

compared with a single-point base station interference wave matching method based on the similarity, the base station interference monitoring method and system can correlate the influence of other base stations in the grid thermodynamic diagram on the base station to be monitored, form piece area monitoring, clearly and intuitively see the influence range of the fault and the approximate fault information on the grid thermodynamic diagram, provide directive guidance for technical personnel to inquire the fault source, improve the accuracy and efficiency of base station interference monitoring, and can be positioned in a region with a larger range. In addition, based on experience accumulation of troubleshooting each time, the accuracy of the interference prediction model can be continuously improved, and benign and high-precision prejudgment closed-loop operation is formed.

The method solves the problems of slow positioning time, low positioning accuracy and smaller positioning area range of the high uplink interference positioning technology due to the need of considering multi-dimensional interference characteristics of frequency domain, time domain, space and the like.

Drawings

FIG. 1 is a process flow diagram of example 1.

Fig. 2 is a schematic diagram of a given waveform a in example 1.

Fig. 3 is a diagram of a matchable waveform B similar to the given waveform a in example 1.

Fig. 4 is a schematic diagram of a residual error unit in embodiment 1.

FIG. 5 is a block diagram of a system according to example 2.

Detailed Description

The drawings are for illustrative purposes only and are not to be construed as limiting the patent;

for the purpose of better illustrating the embodiments, certain features of the drawings may be omitted, enlarged or reduced, and do not represent the size of an actual product;

it will be understood by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The technical solution of the present invention is further described below with reference to the accompanying drawings and examples.

Example 1

A base station interference monitoring method based on waveform analysis and deep learning, as shown in fig. 1, includes the following steps:

s1, collecting data required by interference monitoring of an LTE system; the method comprises XDR information, network management information and 4G LTE working parameter information;

s2, screening out a high uplink interference cell according to the acquired network management data;

s3, carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing similarity, and marking base station faults; the method specifically comprises the following steps:

s31, calculating the shortest algorithm distance between the given waveform in the high uplink interference cell and the matched waveform in the preset interference experience library, wherein the calculation method comprises the following steps:

let a be any real number, calculate the minimum value of the solution formula, i.e.

Minimum value of (d);

wherein j is 1,2,3, 100, which is the PRB value; x denotes a given waveform, x^jFor the j-th data in a given waveform；y_iIdentifying matchable waveforms, y_i ^jThe j data in the i-th matchable waveform; wherein a is used for eliminating the difference caused by control translation; the preset interference experience library comprises a plurality of PRB values of known interference types;

the above solving formula is to find out the waveform with the minimum sum of squared differences with the given waveform except the translation factor from all other matchable waveforms;

and expanding the solving formula:

the minimum value of the formula solved by the matching method is:

s32, performing ascending sequencing on the calculated shortest algorithm distances, selecting the matchable waveform types corresponding to the first N shortest algorithm distances as the initial matched interference wave types of the high uplink interference cell, and marking the base station fault; FIG. 2 shows one of the given waveforms A, FIG. 3 shows one of the similar matchable waveforms B for the given waveform, with the shortest algorithmic distance of 1.9;

s4, feeding back the interference wave types obtained by primary matching to the grid in a thermodynamic mode according to the GPS position of the base station to obtain a grid thermodynamic diagram, namely, different interference wave types in the primary matching interference wave types obtained in the step S3 are represented on the grid in different colors, and color depth is set according to the interference wave influence range to obtain the grid thermodynamic diagram; for example, if GPS desynchronization results in several kilometers of square circle, the thermal value of such interference wave fault is large; for example, a single point of influence fault, the thermal value is small; wherein the latitude and longitude values of the base station form the vertices of the grid;

s5, establishing an interference prediction model based on a deep neural network, wherein the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is a predicted interference type of the high uplink interference cell;

the interference prediction model based on the deep neural network comprises a covn convolution unit, N residual error units, a conv output layer, a hyperbolic tangent function tanh and an optimization function Minimiz Loss which are sequentially connected; wherein the covn input layer is used for extracting the image characteristics of the grid thermodynamic diagram, and the convolution of the image characteristics is X_c ⁽¹⁾＝f(W_c ⁽¹⁾*X_c ⁽⁰⁾+b_c ⁽¹⁾)；

Wherein, f is special convolution for ensuring that the output and the input are the same;

the mathematical model of the residual error unit is X_c ^(l+1)＝X_c ^(l)+F(X_c ^(l)；θ_c ^(l)),l＝1,2,...,L

As shown in fig. 4, where F is the residual equation, combined by two relus and convolution; theta_c ^(l)All parameters needing to be learned in the first layer are contained;

obtaining a predicted interference type X_c ^(L+1)Output by the conv output layer;

the output predicted value is standardized by the hyperbolic tangent function tanh and then is positioned in an interval of [ -1,1], and then the metric value of the predicted value and the true value is calculated by an optimization function minimizlo, namely:

wherein X_tIn order to be a matrix of predicted values,

is a true value matrix;

and S6, updating the grid thermodynamic diagram and an interference experience library according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

Example 2

As shown in fig. 5, the system for monitoring interference of a base station based on waveform analysis and deep learning includes:

the data acquisition module 1 is used for acquiring data required by interference monitoring of the LTE system;

the high uplink interference cell screening module 2 is used for screening out the high uplink interference cell according to the acquired network management data;

an interference wave type primary matching module 3, configured to perform primary matching on the interference wave type of the high uplink interference cell by using similarity, and mark a base station fault;

the grid thermodynamic diagram building module 4 is used for feeding back the interference wave type obtained by primary matching to the grid in a thermodynamic mode according to the GPS position of the base station to obtain a grid thermodynamic diagram;

the interference prediction model building module 5 is used for building an interference prediction model based on a deep neural network, the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is the predicted interference type of the high uplink interference cell;

and the interference optimization module 6 is used for updating the grid thermodynamic diagram and the interference experience base according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

The terms describing positional relationships in the drawings are for illustrative purposes only and are not to be construed as limiting the patent;

it should be understood that the above-described embodiments of the present invention are merely examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention. Other variations and modifications will be apparent to persons skilled in the art in light of the above description. And are neither required nor exhaustive of all embodiments. Any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the claims of the present invention.

Claims (9)

1. The base station interference monitoring method based on waveform analysis and deep learning is characterized by comprising the following steps of:

s1, collecting data required by interference monitoring of an LTE system;

s2, screening out a high uplink interference cell according to the acquired network management data;

s3, carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing similarity, and marking base station faults;

s4, feeding back the interference wave type obtained by primary matching to the grid in a thermal form according to the GPS position of the base station to obtain a grid thermodynamic diagram;

s5, establishing an interference prediction model based on a deep neural network, wherein the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is a predicted interference type of the high uplink interference cell;

and S6, updating the grid thermodynamic diagram and an interference experience library according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

2. The method for monitoring interference of base station based on waveform analysis and deep learning of claim 1, wherein the data in step S1 includes XDR information, network management information, and 4G LTE parameters information.

3. The method for monitoring interference of a base station based on waveform analysis and deep learning of claim 1, wherein the step S3 specifically includes the following steps:

s31, calculating the shortest algorithm distance between the given waveform in the high uplink interference cell and the matched waveform in a preset interference experience library;

and S32, ascending sorting is carried out on the shortest algorithm distances obtained through calculation, the matchable waveform types corresponding to the first N shortest algorithm distances are selected as the initial matching interference wave types of the high uplink interference cell, and the base station fault is marked.

4. The method for monitoring interference of base station based on waveform analysis and deep learning of claim 3, wherein the calculation method of the shortest algorithm distance in step S31 is as follows:

let a be any real number, calculate the minimum value of the solution formula, i.e.

Minimum value of (d);

wherein j is 1,2,3, 100, which is the PRB value; x denotes a given waveform, x^jFor the jth data in a given waveform; y is_iThe identification of a waveform that can be matched,

the j data in the i-th matchable waveform; wherein a is used for eliminating the difference caused by control translation;

and expanding the solving formula:

the minimum value of the formula solved by the matching method is:

5. the method for monitoring interference of a base station based on waveform analysis and deep learning of claim 1, wherein the step S4 specifically includes: expressing different interference wave types on the grid in different colors in the initial matching interference wave types obtained in the step S3, and setting color depth according to the interference wave influence range to obtain a grid thermodynamic diagram; wherein the latitude and longitude values of the base station form the vertices of the grid.

6. The method for monitoring base station interference based on waveform analysis and deep learning of claim 1, wherein the interference prediction model based on the deep neural network of step S5 includes a covn convolution unit, N residual error units, and a conv output layer connected in sequence; wherein the covn input layer is used for extractionThe image features of the grid thermodynamic diagram are convoluted into X_c ⁽¹⁾＝f(W_c ⁽¹⁾*X_c ⁽⁰⁾+b_c ⁽¹⁾)；

Wherein, f is special convolution for ensuring that the output and the input are the same;

the mathematical model of the residual error unit is X_c ^(l+1)＝X_c ^(l)+F(X_c ^(l)；θ_c ^(l)),l＝1,2,...,L

Where F is the residual equation, θ_c ^(l)All parameters needing to be learned in the first layer are contained;

obtaining a predicted interference type X_c ^(L+1)And outputting by a conv output layer.

7. The base station interference monitoring method based on waveform analysis and deep learning of claim 6, characterized in that a hyperbolic tangent function tanh and an optimization function MinimizLoss are further connected behind a conv output layer of the interference prediction model; the hyperbolic tangent function tanh is used for standardizing the predicted value output by the covn output layer, and the optimization function minimizloss is used for calculating the metric value of the predicted value and the true value output by the interference prediction model, namely:

wherein X_tIn order to be a matrix of predicted values,

is a true value matrix.

8. The method for monitoring interference of base station based on waveform analysis and deep learning of claim 7, wherein the predicted value is normalized by the hyperbolic tangent function tanh and then located in the range of [ -1,1 ].

9. The system for monitoring the base station interference based on the waveform analysis and the deep learning as claimed in any one of claims 1 to 8, comprising:

the data acquisition module is used for acquiring data required by interference monitoring of the LTE system;

the high uplink interference cell screening module is used for screening out the high uplink interference cell according to the acquired network management data;

the interference wave type primary matching module is used for carrying out primary matching on the interference wave types of the high uplink interference cells by utilizing similarity and marking base station faults;

the grid thermodynamic diagram building module is used for feeding back the interference wave type obtained by primary matching to a grid in a thermodynamic mode according to the GPS position of the base station to obtain a grid thermodynamic diagram;

the interference prediction model building module is used for building an interference prediction model based on a deep neural network, the input of the interference prediction model is a grid thermodynamic diagram, and the output of the interference prediction model is the predicted interference type of the high uplink interference cell;

and the interference optimization module is used for updating the grid thermodynamic diagram and the interference experience base according to the predicted interference type and the result of on-site investigation and processing, and optimizing the interference prediction model.

Images