CN112613666A - Power grid load prediction method based on graph convolution neural network and transfer learning - Google Patents
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Abstract
The invention discloses a power grid load prediction method based on a graph convolution neural network and transfer learning. Aiming at the time-space characteristics of power grid load data, a power grid load prediction method suitable for a large-scale area is designed by adopting a graph convolution network and combining a migration learning method. The method comprises the steps of dividing the whole power grid into a plurality of sub-areas according to areas and independently constructing a model for each sub-area for prediction. In the model construction, a dynamic time warping algorithm is adopted to fuse time similarity, a graph convolution network is introduced by using a power grid topological structure to extract spatial features, time features are extracted through convolution operation in a time domain, and network models in different regions are trained by using a transfer learning method. The method can reduce the calculation pressure of the cloud server, improve the accuracy of power grid load prediction and reduce the time of model training.
Description
Technical Field
The invention relates to the technical field of power grid load prediction, in particular to a power grid load prediction method based on a graph convolution neural network and transfer learning.
Background
The power grid load prediction plays a very key role in tasks such as power utilization planning, operation scheduling and the like of a power system. Because the load of the power grid is influenced by various factors, the load is closely related to conditions such as economic level, industrial structure, meteorological conditions and the like of the region, and certain complexity is presented. In addition, the change of the load of the power grid has certain regularity and periodicity. Therefore, how to accurately predict the load of the power grid is an important issue facing the power system. However, most of the previous research has mainly focused on the prediction of the load of a single node or the total load of the grid. The power grid is a wide area network with a large range, multiple regions and multiple nodes, so how to comprehensively consider the correlation among different regions of the power grid and the space-time characteristics among the nodes to realize the rapid and large-range accurate prediction of the load of each node of the power grid has great economic value and practical significance.
There are two main types of statistics for grid charge prediction, the first type is based on traditional statistical methods, such as autoregressive integrated moving average ARIMA, vector autoregressive VAR, etc. Such methods typically require data to satisfy some assumptions, but these grid data are too complex to satisfy these assumptions, and therefore they typically have poor prediction accuracy in practical applications. The second category of prediction methods is based on data-driven methods. In this class of methods, the performance of these methods is superior to statistical methods, based mainly on traditional machine learning, such as Support Vector Regression (SVR), k-nearest neighbor (KNN). However, these methods require many complex feature extractions and are not suitable for processing large amounts of complex grid data. With the rapid development of deep learning, breakthrough is made in many fields (such as image processing and speech recognition). The method for obtaining the space-time correlation of the data by using the deep learning-based method, such as a Convolutional Neural Network (CNN) and a cyclic convolutional neural network (RNN), can be used for effectively predicting the load data of the power grid, but cannot sufficiently extract the space correlation between the power grid nodes. Also, generally only a single node can be predicted. In order to solve the problems, the invention provides a power grid load prediction method based on a graph convolution neural network and transfer learning.
Disclosure of Invention
The invention aims to provide a power grid load prediction method based on a graph convolution neural network and transfer learning.
In order to achieve the purpose, the technical scheme of the invention is as follows: a power grid load prediction method based on a graph convolution neural network and transfer learning comprises the following steps:
step S1: according to the geographical position information, dividing a region to be predicted into a plurality of small regions, and independently constructing a model for each sub-region to predict the power grid load of the region;
step S2: extracting time-space information of the power grid nodes of each sub-region, including topological structure information of the power grid nodes and time sequence information of load data, and constructing a prediction model by adopting a graph convolution neural network and a full connection layer;
step S3: training the constructed model by adopting the power grid load data of all nodes in the subareas;
step S4: and sharing the trained network model to the adjacent subareas as an initial training model by adopting a transfer learning method, and training each subarea model.
In an embodiment of the present invention, in step S1, the grid area division is performed as follows:
step S11: according to the geographical position information, the power grid node topological structure is divided into a plurality of sub-graphs, nodes with more connection points in each sub-graph are extracted as central nodes, and the sub-graphs with similar sizes are divided according to the central nodes. And overlapping partial nodes in the nearby area on the subgraph with small nodes, so that the subgraph has similar size.
In the embodiment of the present invention, in step S2, the time-space information of each sub-region is integrated into the model construction through the time warping algorithm, and the load of each node of the power grid is predicted by using the graph convolution neural network. The method comprises the following specific steps:
and step S21, calculating the similarity between different nodes in the subgraph by using a dynamic time warping algorithm (dynamic time warping), wherein the calculation method comprises the following steps:wherein (n, m) is the length of two different sequences, WnmDistance matrix, w, representing two sequencesijDist (-) is a classical distance computation function for the elements therein.
Step S22: constructing a topological graph G containing spatial information according to the connectivity of the power grid topological structureS. According to the sequence similarity calculated by the dynamic time warping algorithm, the first 5 percent of most similar nodes are taken to be connected to form a new topological graph GSTAnd time information and space information of the power grid nodes are fused.
In the embodiment of the present invention, in step S3, the specific operations are as follows:
step S31: respectively carrying out graph convolution operation by adopting power grid load data of one week, one day and one hour before all nodes of the sub-region, extracting spatial information in the data, then carrying out convolution operation on a time domain, extracting time correlation, and carrying out nonlinear transformation by adopting ReLU as an activation function in a network layer. And fusing the features extracted from the data at different moments, and finally predicting through a full-connection layer.
Step S32: comparing the prediction output of the constructed model with the true value, calculating a loss value, optimizing the model, adopting a mean square error as a loss function, then continuously optimizing parameters of the frame by using a back propagation algorithm, continuously calculating a parameter gradient in the back propagation algorithm, continuously adapting the learning rate by using an RMSprop algorithm, and optimizing the parameters to enable the model to reach an optimal solution.
In the embodiment of the present invention, in step S4, a migration learning method is adopted, the trained model is used as an initial model of an adjacent region, a sub-region similar to or close to a source region is generally selected as a migration target, and the model is trained by using power grid load data of each sub-region.
Compared with the prior art, the invention has the following beneficial effects: the grid load prediction based on the graph convolution neural network and the transfer learning, provided by the invention, can overcome the defect of too large calculated amount caused by cloud computing in the existing method, and meanwhile, the space-time correlation of the grid load data is integrated into a model, so that the prediction precision is improved. The defect of long training time is overcome by adopting transfer learning, and the model training efficiency is improved.
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Fig. 1 is an overall model frame in an embodiment of the present invention.
Detailed Description
The technical scheme of the invention is specifically explained below with reference to the accompanying drawings.
The invention discloses a power grid load prediction method based on a graph convolution neural network and transfer learning, which is specifically realized according to the following steps as shown in figure 1:
step S1: according to the geographical position information, the power grid node topological structure is divided into a plurality of sub-graphs, nodes with more connection points in each sub-graph are extracted as central nodes, and the sub-graphs with similar sizes are divided according to the central nodes. When the subgraph is divided specifically, the subgraph is divided into areas with similar node numbers as much as possible, but the same node number is difficult to guarantee in the specific implementation process, and a zero padding method can be adopted, or nodes in different areas are used in an overlapping mode, so that the subgraph has similar size.
Step S2: extracting time-space information of the power grid nodes of each sub-region, including topological structure information of the power grid nodes and time sequence information of load data, and constructing a prediction model by adopting a graph convolution neural network and a full connection layer;
firstly, a Dynamic Time Warping algorithm (Dynamic Time Warping) is used for calculating the similarity between different nodes in a subgraph, and the calculating method is as follows:wherein (n, m) isLength of two different sequences, WnmDistance matrix, w, representing two sequencesijDist (-) is a classical distance computation function for the elements therein.
Further, a topological graph G containing space information is constructed according to the connectivity of the power grid topological structureS. According to the sequence similarity calculated by the dynamic time warping algorithm, the first 5 percent of most similar nodes are taken to be connected to form a new topological graph GSTAnd time information and space information of the power grid nodes are fused.
Step S3: training the constructed graph convolution network model by adopting the power grid load data of all nodes in the sub-region;
firstly, respectively carrying out graph convolution operation by adopting power grid load data of one week, one day and one hour before all nodes of a sub-region, extracting spatial information in the data, then carrying out convolution operation on a time domain, extracting time correlation, and carrying out nonlinear transformation by adopting ReLU as an activation function in a network layer. And fusing the features extracted from the data at different moments, and finally predicting through a full-connection layer.
Graph convolution is as follows;
gθ*Gx=gθ(UΛUT)x=Ugθ(L)xUTx
in the above formulaGRepresenting the operation of graph convolution, gθThe method is characterized in that the method is a convolution kernel, x is power grid load data, and x adopts data of one day, one week and one hour before a predicted point. L is a Laplace matrixA is the adjacency matrix of the constructed subgraph, and D is the degree of the adjacency matrix. The spatial features of different nodes can be extracted by graph convolution.
Further, by convolution of the time domain CNN:whereinIndicating the output of the r-th layer, the subscript T indicates the current usage data period, and finally the temporal similarity can be extracted using ReLU as the activation function. And finally, fusing the characteristics through a full connection layer.
Furthermore, the prediction results corresponding to the data of one week, one day and one hour are fused through full connection respectively:
Y′=Wh⊙Yh+Wd⊙Ydi-Ww⊙Yw
this wherein |, represents a matrix dot product. Y is the prediction result after fusion, Yh、Yd、YwRespectively represents the prediction of corresponding data one hour before, one day before and one week before, and W represents the influence degree of the corresponding learnable weight reflecting the three components.
And further, comparing the prediction output of the constructed model with a real value, calculating a loss value, optimizing the model, adopting a mean square error as a loss function, then continuously optimizing parameters of the frame by using a back propagation algorithm, continuously calculating a parameter gradient in the back propagation algorithm, and continuously adapting the learning rate and optimizing the parameters by using an RMSprop algorithm to enable the model to reach an optimal solution.
The RMSprop algorithm uses a variable meanSquare (w, t) to store the average value of the square of the gradient of a period of time before each weight value when the learning rate is updated for the t time, and self-adapts to the learning rate according to the variable, and continuously optimizes parameters to enable the structure to reach the optimal solution.
Mean square error function (MSE):
RMSprop formula:
Step S4: and sharing the trained network model to the adjacent subareas as an initial model by adopting a transfer learning method, and training each subarea model to accelerate the model training speed.
Compared with the prior art, the invention has the following beneficial effects: the invention provides a power grid load prediction method based on a graph convolution neural network and transfer learning, which can overcome the defect of large calculation amount caused by cloud computing in the existing method, and simultaneously, the space-time correlation of power grid load data is integrated into a graph model, so that the prediction precision is improved. The defect of long training time is overcome by adopting transfer learning, and the model training efficiency is improved.
The above are preferred embodiments of the present invention, and all changes made according to the technical scheme of the present invention that produce functional effects do not exceed the scope of the technical scheme of the present invention belong to the protection scope of the present invention.
Claims (5)
1. A power grid load prediction method based on a graph convolution neural network and transfer learning is characterized in that: comprises the following steps of (a) carrying out,
step S1: according to the geographical position information, dividing a region to be predicted into a plurality of small regions, and independently constructing a model for each sub-region to predict the power grid load of the region;
step S2: extracting time-space information of the power grid nodes of each sub-region, including topological structure information of the power grid nodes and time sequence information of load data, and constructing a prediction model by adopting a graph convolution neural network and a full connection layer;
step S3: training the constructed model by adopting the power grid load data of all nodes in the subareas;
step S4: and sharing the trained network model to the adjacent subareas as an initial training model by adopting a transfer learning method, and training each subarea model.
2. The grid load prediction method based on the graph convolution neural network and the transfer learning as claimed in claim 1, wherein: in the step S1, the area division is performed by:
step S11: according to the geographical position information, the power grid node topological structure is divided into a plurality of sub-graphs, nodes with more connection points in each sub-graph are extracted as central nodes, and the sub-graphs with similar sizes are divided according to the central nodes. And overlapping partial nodes in the nearby area on the subgraph with small nodes, so that the subgraph has similar size.
3. The grid load prediction method based on the graph convolution neural network and the transfer learning as claimed in claim 1, wherein: in the step S2, the specific space-time diagram configuration is performed as follows:
and step S21, calculating the similarity between different nodes in the subgraph by using a Dynamic Time Warping algorithm (Dynamic Time Warping), wherein the calculation method is as follows:max (n, m) is more than or equal to K and less than or equal to n + m, wherein (n, m) is the length of two different sequences, WnmDistance matrix, w, representing two sequencesijDist (-) is a classical distance computation function for the elements therein.
Step S22: constructing a topological graph G containing spatial information according to the connectivity of the power grid topological structureS. Calculating sequence similarity according to a dynamic time warping algorithm, and connecting the first 5% most similar nodes to form a new topological graph GSTAnd time information and space information of the power grid nodes are fused.
4. The grid load prediction method based on the graph convolution neural network and the transfer learning as claimed in claim 1, wherein: in the step S3, in the above step,
step S31: respectively carrying out graph convolution operation by adopting power grid load data of one week, one day and one hour before all nodes of the sub-region, extracting spatial information in the data, then carrying out convolution operation on a time domain, extracting time correlation, and carrying out nonlinear transformation by adopting ReLU as an activation function in a network layer. And fusing the features extracted from the data at different moments, and finally predicting through a full-connection layer.
Step S32: comparing the prediction output of the constructed model with the true value, calculating a loss value, optimizing the model, adopting a mean square error as a loss function, then continuously optimizing parameters of the frame by using a back propagation algorithm, continuously calculating a parameter gradient in the back propagation algorithm, continuously adapting the learning rate by using an RMSprop algorithm, and optimizing the parameters to enable the model to reach an optimal solution.
5. The grid load prediction method based on the graph convolution neural network and the transfer learning as claimed in claim 1, wherein: in step S4, a transfer learning method is used, the trained model is used as an initial model of an adjacent area, a sub-area similar to or close to the source area is generally selected as a transfer target, and the model is trained by using the power grid load data of each sub-area.
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CN114780870A (en) * | 2022-04-15 | 2022-07-22 | 北京骑胜科技有限公司 | Order quantity prediction method, system, device, server, terminal and storage medium |
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