CN113297957A - Electricity utilization characteristic waveform extraction and analysis framework based on edge calculation - Google Patents

Abstract

The invention discloses a power utilization characteristic waveform extraction and analysis framework based on edge calculation, which comprises a terminal and a cloud end, wherein the terminal comprises an equipment real-time data collection module, a real-time data calculation and analysis module and a lightweight feature library, and the cloud end comprises a fault classification model module based on machine learning and a lightweight feature library extraction module; the terminal is deployed on a power utilization side, collects a time sequence of power utilization data of a user in real time and high frequency, calculates a characteristic value of the time sequence data in real time, uploads the characteristic value to the cloud, the cloud establishes a lightweight characteristic library through a fault classification model module and a lightweight characteristic library extraction module and feeds the lightweight characteristic library back to the terminal, and the terminal performs characteristic extraction and fault analysis on the collected power utilization data according to the deployed lightweight characteristic library. According to the invention, the abnormal fault detection of the power utilization side is realized efficiently by utilizing edge cloud cooperation.

Description

Electricity utilization characteristic waveform extraction and analysis framework based on edge calculation

Technical Field

The invention relates to the technical fields of electric power data analysis, electric power data abnormity prediction, edge cloud cooperative computing and the like, in particular to an electric power utilization characteristic waveform extraction and analysis framework based on edge computing.

Background

In recent years, there are two typical methods around the problem of abnormal failure detection on the electricity-consuming side. The first method sets a simple threshold value at the terminal equipment for diagnosis, simultaneously stores data in a storage device, and after power utilization abnormity occurs, extracts data from the terminal through an off-line method on site and analyzes the data, and the method focuses more on post analysis; in the second method, the terminal transmits data to the cloud in real time, and the cloud performs model training and online fault diagnosis. The first method adopts a simple fault diagnosis method with unsatisfactory effect, and the second method improves the accuracy of fault identification even if the cloud participates in fault diagnosis, but because the fault diagnosis is not performed locally, delay is generated in the data transmission process, and the requirement of timely response when a fault occurs cannot be met. Therefore, a large amount of calculation tasks cannot be simply put on the cloud for processing, and the terminal equipment is only used for collecting and uploading data, and the cloud needs to be subjected to load reduction and the terminal equipment needs to be subjected to appropriate load increase so as to achieve the aims of fully utilizing resources and responding to fault data in time.

Disclosure of Invention

The invention aims to overcome the defects of the prior art, provides an electricity utilization characteristic waveform extraction and analysis framework based on edge calculation, and realizes the abnormal fault detection of the electricity utilization side by utilizing edge cloud cooperation.

One technical scheme for achieving the above purpose is as follows: an electricity utilization characteristic waveform extraction and analysis framework based on edge calculation comprises a terminal and a cloud end;

the terminal comprises an equipment real-time data collection module, a real-time data calculation and analysis module and a lightweight feature library, and the cloud end comprises a fault classification model module based on machine learning and a lightweight feature library extraction module;

the terminal is deployed on a power utilization side, collects a time sequence of power utilization data of a user in real time and high frequency, calculates a characteristic value of the time sequence data in real time, uploads the characteristic value to the cloud, the cloud establishes a lightweight characteristic library through a fault classification model module and a lightweight characteristic library extraction module and feeds the lightweight characteristic library back to the terminal, and the terminal performs characteristic extraction and fault analysis on the collected power utilization data according to the deployed lightweight characteristic library.

Further, the working method of issuing the lightweight feature library by the cloud comprises three processes of generating the lightweight feature library by the cloud, collecting and diagnosing data in real time by the terminal, and interacting the cloud and the terminal;

step 1, the cloud generates a lightweight feature library: extracting the characteristics of a fault classification model through a fault classification model module based on machine learning, and simplifying a row description on a fault data characteristic library so that the fault data characteristic library can be sent to a terminal and identified and utilized by the terminal;

step 2, the terminal collects data in real time and diagnoses: the terminal collects power utilization data in a real-time high-frequency mode, and according to the instruction provided by the cloud, the collected data are calculated and analyzed through the locally deployed lightweight feature library. A

Furthermore, when the cloud end interacts with the terminal, the mutual agreement is observed, the agreed content comprises rules of uploading, issuing and updating the feature library, so that the situation that the edge cloud collaborates to complete power failure diagnosis is guaranteed, and the cloud end adjusts the computing work of the cloud end according to the diagnosis effect of the terminal.

Compared with the prior art, the method can make up for the defect of weak computing capability of the terminal and the low timeliness of online diagnosis. By fully utilizing the characteristics of data, the training result of the cloud is applied to the terminal equipment in a lightweight form by adopting an edge calculation method, and is uploaded to the cloud in different ways according to different diagnosis results, so that a more rapid and simple diagnosis way is formed, and due to the fact that the terminal and the cloud are constantly in contact, timely interaction is carried out, and the timeliness of a terminal characteristic library is guaranteed.

Drawings

Fig. 1 is a schematic diagram of an electrical characteristic waveform extraction and analysis architecture based on edge calculation according to the present invention.

Detailed Description

Referring to fig. 1, in order to better understand the technical solution of the present invention, the following detailed description is made by specific examples:

the terminal mainly comprises the following modules for realizing real-time data collection and fault discovery:

the real-time data acquisition module 1 is used for collecting three-phase voltage electric current data of a power utilization side in real time at the frequency of 6.4khz, and in the experimental process, the AD value of one phase is extracted, and the following conversion is required to be carried out:

I＝Idata/104.9

U＝Udata/12482.5

the real current value and the real voltage value can be obtained after conversion, and the unit is milliampere (mA) and volt (V) respectively.

The real-time computing module 2: the real-time computing module provides a computing library through a terminal, the computing library comprises computing methods of specific indexes, but in actual use, all the methods do not need to be called, and only specified characteristics are computed according to configuration files issued by a cloud, which is an important step in collaborative computing.

The fault diagnosis module 3: the module comprises two sub-modules, a configuration file and a diagnosis method. The method for diagnosing the fault identification is provided by the server side, and classification results of the server side are fully utilized.

The data uploading module 4: considering the timeliness of fault diagnosis, the energy consumption problem of terminal equipment and the bandwidth problem of transmission, it is necessary to adopt different uploading modes for normal and abnormal data, so in the module, the normal data is uploaded at time intervals and the abnormal data is uploaded in real time.

The cloud terminal is matched with the terminal in the edge cloud coordination process to realize diagnosis, and the cloud terminal comprises the following modules:

the data collecting module 5: the cloud needs to face the problem of uploading a large amount of data, so the problem that the processing speed is not matched needs to be solved, the uploaded data is temporarily stored by setting a cache mechanism at the cloud, and when the processing speed of the cloud can be matched, the data is cached and taken out.

The machine learning module 6: and selecting a proper machine learning method, learning the characteristics of the electric power data uploaded to the cloud end, and realizing the purpose of classifying the electric power data, wherein the characteristic library can be better extracted only if the data classification of the cloud end is accurate enough.

And (3) extracting a characteristic library module 7: extracting features from fault data, describing the features into a feature library form, and using the feature library as a means and a method for judging abnormity by a terminal. In order to realize a lighter-weight feature library, the dimension reduction of the features is needed; and obtaining a more meaningful feature library and sending the more meaningful feature library to the terminal.

The file issuing module 8: the module is an important step in the interaction process of the terminal and the cloud. The diagnosis method and the configuration file in the module are issued to the terminal, and the terminal can accurately and efficiently finish the work of fault diagnosis only by diagnosing according to the content in the issued file; and the module ensures timeliness of the feature library, and the problem of asynchronism between the cloud and the terminal cannot occur.

The specific method for realizing the cooperative computing of the terminal device and the cloud device can make up for the defect of poor computing performance of the terminal and reduce computing tasks of the cloud.

It should be understood by those skilled in the art that the above embodiments are only for illustrating the present invention and are not to be used as a limitation of the present invention, and that changes and modifications to the above described embodiments are within the scope of the claims of the present invention as long as they are within the spirit and scope of the present invention.

Claims (3)

1. The utility model provides a power consumption characteristic waveform draws and analysis framework based on edge calculation, includes terminal and high in the clouds, its characterized in that:

the terminal comprises an equipment real-time data collection module, a real-time data calculation and analysis module and a lightweight feature library, and the cloud end comprises a fault classification model module based on machine learning and a lightweight feature library extraction module;

the terminal is deployed on a power utilization side, collects a time sequence of power utilization data of a user in real time and high frequency, calculates a characteristic value of the time sequence data in real time, uploads the characteristic value to the cloud, the cloud establishes a lightweight characteristic library through a fault classification model module and a lightweight characteristic library extraction module and feeds the lightweight characteristic library back to the terminal, and the terminal performs characteristic extraction and fault analysis on the collected power utilization data according to the deployed lightweight characteristic library.

2. The architecture for extracting and analyzing power consumption characteristic waveforms based on edge computing according to claim 1, wherein the working method of issuing the lightweight feature library by the cloud comprises three processes of generating the lightweight feature library by the cloud, collecting and diagnosing data in real time by the terminal, and interacting between the cloud and the terminal;

step 1, the cloud generates a lightweight feature library: extracting the characteristics of a fault classification model through a fault classification model module based on machine learning, and simplifying a row description on a fault data characteristic library so that the fault data characteristic library can be sent to a terminal and identified and utilized by the terminal;

step 2, the terminal collects data in real time and diagnoses: the terminal collects power utilization data in a real-time high-frequency mode, and according to the instruction provided by the cloud, the collected data are calculated and analyzed through the locally deployed lightweight feature library. A

3. The architecture of claim 2, wherein the cloud and the terminal follow conventions during interaction, the conventions include rules for uploading, issuing, and updating the feature library, so that the cloud cooperatively completes power failure diagnosis, and the cloud adjusts computing work of the cloud according to the diagnosis effect of the terminal.

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