CN112734141B - Diversified load interval prediction method and device - Google Patents
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Abstract
The application discloses a diversified load interval prediction method and device. Then dividing the load predicted value into different prediction sections, fitting the error distribution of the load predicted value in each prediction section by normal distribution, and establishing a diversified load condition probability section prediction model. And then, carrying out iterative optimization on the diversified load conditional probability interval prediction model, and finally determining and evaluating the optimal prediction interval of the diversified load. According to the method and the device, only the point prediction of the diversified loads is considered, unavoidable prediction errors exist, so that the interval prediction of the diversified loads is considered, the prediction result is more accurate, and practical and reliable information is provided for the operation regulation and control of the power system.
Description
Technical Field
The application relates to the technical field of load prediction and planning, in particular to a diversified load interval prediction method and device.
Background
The load prediction is to determine load data at a certain future moment according to various factors such as the operating characteristics, capacity increase decision, natural conditions, social influence and the like of a system under the condition of meeting a certain precision requirement, wherein the load refers to the power demand (power) or the power consumption. Load prediction is an important content in economic dispatch of a power system and is an important module of an Energy Management System (EMS).
In the prior art, the future power demand of a power load is presumed through the past power demand and the present power demand of the power load, specifically, point prediction is carried out on related data information of the load to obtain a predicted value of the load in a future period of time, and then starting and stopping of a generator set in a power grid are economically and reasonably arranged through the predicted value, so that the safety and stability of power grid operation are kept, a unit maintenance plan is reasonably arranged, the power generation cost is effectively reduced, and the economic benefit is improved.
However, with the rapid development of the modern society, the types and forms of loads are being developed in various directions, including specifically, power loads, thermal loads, and the like. Compared with the traditional power load, the novel diversified load is more complex and diversified, the requirements of different types of loads on the reliability and the power supply quality of a power system are different, only the diversified load is subjected to point prediction, and the accuracy is very low.
Disclosure of Invention
The application provides a diversified load interval prediction method and device, which aim to solve the technical problem that in the prior art, only point prediction is carried out on diversified loads, and the accuracy is low.
A diversified load interval prediction method, comprising:
acquiring diversified load historical data information and multiple groups of load real values, performing point prediction on the diversified load historical data information, and determining multiple groups of load predicted values corresponding to the multiple groups of load real values one by one;
determining the error of each group of load predicted values according to the plurality of groups of load predicted values and the plurality of groups of load real values which correspond one to one;
acquiring a plurality of groups of prediction error normal distribution functions, wherein each group of prediction error normal distribution functions corresponds to the errors of each group of load predicted values one by one;
according to the multiple groups of load predicted values and preset predicted interval boundary parameters, carrying out interval division on the multiple groups of load predicted values, and determining multiple predicted intervals;
generating a diversified load conditional probability interval prediction model according to the multiple groups of prediction error normal distribution functions and the multiple prediction intervals;
performing iterative optimization on the diversified load condition probability interval prediction model, updating the boundary parameter of the prediction interval in the optimization process, and determining the optimal boundary parameter value of the prediction interval; the optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real value of each group of loads falls in the corresponding prediction interval;
and determining the optimal prediction interval of the diversified loads according to the boundary parameters of the optimal prediction interval.
Optionally, the obtaining multiple groups of prediction error normal distribution functions includes:
determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
and determining a plurality of groups of prediction error normal distribution functions according to the error of each group of load predicted values, the error mean value and the error standard deviation.
Optionally, the performing interval division on the multiple groups of load predicted values according to the multiple groups of load predicted values and preset prediction interval boundary parameters, and determining multiple prediction intervals includes:
determining a normal distribution quantile corresponding to the boundary parameter of the prediction interval according to the preset boundary parameter of the prediction interval;
determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
for any load predicted value, determining the upper limit value and the lower limit value of a group of predicted sections according to the normal distribution quantiles, the error mean value and the error standard deviation;
determining a boundary value of a group of prediction intervals according to the boundary parameter of the prediction intervals and the upper and lower limit values of the group of prediction intervals;
determining a predicted interval according to the upper and lower limit values of the group of predicted intervals and the boundary value of the group of predicted intervals;
a plurality of predicted block segments are obtained.
Optionally, after determining the optimal prediction interval of the diversified loads, the method further includes:
performing prediction evaluation on the optimal prediction interval; the prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval.
Optionally, the prediction interval evaluation includes: average coverage error assessment, sensitivity assessment, and composite score value assessment.
A second aspect of the present application discloses a diversified load section prediction apparatus, which is applied to the diversified load section prediction method according to the first aspect, and the apparatus includes:
the point prediction module is used for acquiring diversified load historical data information and multiple groups of load real values, performing point prediction on the diversified load historical data information and determining multiple groups of load predicted values which are in one-to-one correspondence with the multiple groups of load real values;
the error acquisition module is used for determining the error of each group of load predicted values according to the one-to-one corresponding groups of load predicted values and the groups of load real values;
the function acquisition module is used for acquiring a plurality of groups of prediction error normal distribution functions, and each group of prediction error normal distribution functions corresponds to the error of each group of load predicted values one by one;
the interval division module is used for carrying out interval division on the multiple groups of load predicted values according to the multiple groups of load predicted values and preset predicted interval boundary parameters and determining multiple predicted intervals;
the interval prediction model establishing module is used for generating a diversified load condition probability interval prediction model according to the multiple groups of prediction error normal distribution functions and the multiple prediction intervals;
the optimization processing module is used for performing iterative optimization on the diversified load condition probability interval prediction model, updating the boundary parameter of the prediction interval in the optimization process and determining the optimal boundary parameter value of the prediction interval; the optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real value of each group of loads falls in the corresponding prediction interval;
and the optimal prediction interval acquisition module is used for determining the optimal prediction interval of the diversified loads according to the boundary parameter of the optimal prediction interval.
Optionally, the function obtaining module includes:
the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
and the function acquisition unit is used for determining a plurality of groups of prediction error normal distribution functions according to the error of each group of load prediction values, the error mean value and the error standard deviation.
Optionally, the interval dividing module includes:
a normal distribution quantile obtaining unit, configured to determine, according to the preset prediction interval boundary parameter, a normal distribution quantile corresponding to the prediction interval boundary parameter;
the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
the interval upper and lower limit value acquisition unit is used for determining the upper and lower limit values of a group of prediction interval values according to the normal distribution quantile points, the error mean values and the error standard deviations aiming at any load prediction value;
a boundary value obtaining unit, configured to determine a boundary value of a group of predicted intervals according to the predicted interval boundary parameter and the upper and lower limit values of the group of predicted intervals;
a predicted block section obtaining unit configured to determine a predicted block section based on upper and lower limit values of the group of predicted block sections and a boundary value of the group of predicted block sections; a plurality of predicted block segments are obtained.
Optionally, the diversified load interval prediction apparatus further includes a prediction evaluation module, where the prediction evaluation module is configured to perform prediction evaluation on the optimal prediction interval after determining the optimal prediction interval of the diversified load; the prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval.
Optionally, the prediction interval evaluation includes: average coverage error assessment, sensitivity assessment, and composite score value assessment.
The application discloses a diversified load interval prediction method and device. Then dividing the load predicted value into different prediction sections, fitting the error distribution of the load predicted value in each prediction section by normal distribution, and establishing a diversified load condition probability section prediction model. And then, carrying out iterative optimization on the diversified load conditional probability interval prediction model, and finally determining the optimal prediction interval of the diversified load. The effectiveness and the correctness of the optimal prediction interval are verified by performing prediction evaluation on the optimal prediction interval.
In the present application, it is considered that only point prediction is performed on diversified loads, and there is an inevitable prediction error, and therefore it is important to obtain the upper and lower limit values of prediction. Therefore, interval prediction is carried out on diversified loads, and on the premise that the true value of each group of loads is ensured to fall into the correspondingly obtained prediction interval, the smaller the range of each prediction interval is, the better the prediction result is, so that the prediction result is more accurate, and practical and reliable information is provided for operation regulation and control of the power system.
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In order to more clearly explain the technical solution of the present application, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious to those skilled in the art that other drawings can be obtained according to the drawings without creative efforts.
Fig. 1 is a schematic flowchart of a diversified load interval prediction method disclosed in an embodiment of the present application;
fig. 2 is a schematic diagram illustrating a prediction interval division in a diversified load interval prediction method disclosed in an embodiment of the present application;
fig. 3 is an error distribution histogram of a load predicted value in a diversified load interval prediction method disclosed in the embodiment of the present application;
fig. 4 is a diagram of a prediction result of an optimal prediction interval when a boundary parameter of the prediction interval is 0.95 in the diversified load interval prediction method disclosed in the embodiment of the present application;
fig. 5 is a schematic structural diagram of a diversified load interval prediction apparatus disclosed in an embodiment of the present application.
Detailed Description
In order to solve the technical problem that in the prior art, the accuracy is low only by performing point prediction on diversified loads, the application discloses a diversified load interval prediction method and device through the following two embodiments.
A first embodiment of the present application discloses a diversified load interval prediction method, specifically referring to a flow diagram shown in fig. 1, the method includes:
step S101, obtaining diversified load historical data information and multiple groups of load real values, performing point prediction on the diversified load historical data information, and determining multiple groups of load predicted values which are in one-to-one correspondence with the multiple groups of load real values.
Specifically, there are many point prediction methods, including a method for establishing load prediction through machine learning, and a prediction method for mining intrinsic characteristics of load data through deep learning, including a time series method, a persistence method, a gray prediction method, a support vector machine, a neural network algorithm, and the like. The point prediction method has unavoidable prediction errors, so that the prediction of the upper limit value and the lower limit value becomes more important, the reasons for generating errors of prediction results are many, and error distribution functions obeyed by the prediction errors have differences under different conditions.
In some embodiments of the present application, point prediction of diversified loads is performed by taking wavelet decomposition and LSTM network in machine learning as an example, and a point prediction error condition is obtained. Specifically, in the actual operation process, 10 months of diversified load historical data information is collected, the Pearson correlation coefficient value between each feature and diversified loads at the future four-hour moment is calculated, and strong correlation features are screened to serve as a data set. And performing wavelet decomposition on the diversified load historical data to obtain a plurality of wavelet components. And establishing an input and output model of each wavelet decomposition by taking a plurality of power characteristics before the current moment as input variables and taking the load predicted value as an output variable. And (3) carrying out 0-mean normalization processing on the whole sample set, carrying out PCA (principal component analysis) dimensionality reduction on the input variable set, dividing 3000 samples as a training set of the model, and dividing 6000 samples as a test set. And carrying out LSTM network training on all wavelet component sample training sets, substituting input variables of respective wavelet sample testing sets into the trained network model to obtain predicted values and real values of all wavelet samples, and overlapping the predicted values and the real values of all wavelet components to finish the diversified load point prediction based on wavelet decomposition and the LSTM network.
And S102, determining the error of each group of load predicted values according to the multiple groups of load predicted values and the multiple groups of load real values which correspond one to one.
And step S103, acquiring multiple groups of prediction error normal distribution functions, wherein each group of prediction error normal distribution functions corresponds to the error of each group of load predicted values one by one.
Further, the obtaining of the multiple groups of prediction error normal distribution functions includes:
and determining an error mean value and an error standard deviation corresponding to the errors of each group of load predicted values according to the errors of each group of load predicted values.
And determining a plurality of groups of prediction error normal distribution functions according to the error of each group of load prediction values, the error mean value and the error standard deviation.
Specifically, the error between the predicted value of the load and the true value of the load is used as a condition, and parameterized distribution functions of prediction errors in different predicted value intervals are constructed so as to be used for describing the prediction errors of diversified loads. In some embodiments of the present application, a large amount of collected diversified load historical data information and a load true value are analyzed to obtain an error of a load predicted value, and then, an analysis modeling is performed, and a random variable of the error of the load predicted value is denoted as X, so that a probability density function of X is expressed in the following form:
in the formula: mu and sigma are respectively the mean value and the standard deviation of the error X of the load predicted value.
The distribution function corresponding to the error of the load predicted value is expressed as:
and step S104, according to the multiple groups of load predicted values and preset predicted interval boundary parameters, carrying out interval division on the multiple groups of load predicted values, and determining multiple predicted intervals.
Further, the performing interval division on the multiple groups of load predicted values according to the multiple groups of load predicted values and preset prediction interval boundary parameters, and determining multiple prediction intervals includes:
and determining the normal distribution quantiles corresponding to the boundary parameters of the prediction interval according to the preset boundary parameters of the prediction interval.
And determining an error mean value and an error standard deviation corresponding to the errors of each group of load predicted values according to the errors of each group of load predicted values.
And determining the upper limit value and the lower limit value of a group of prediction sections according to the normal distribution quantiles, the error mean value and the error standard deviation aiming at any load prediction value.
And determining the boundary value of a group of prediction intervals according to the boundary parameters of the prediction intervals and the upper and lower limit values of the group of prediction intervals.
And determining a predicted interval according to the upper and lower limit values of the group of predicted intervals and the boundary value of the group of predicted intervals.
Thereby obtaining a plurality of predicted sections.
Referring to fig. 2, a schematic diagram of prediction section division in the diversified load section prediction method disclosed in the embodiment of the present application is shown. Specifically, an initial value [ α ] of the prediction section boundary parameter is set 1 ,α 2 ,,α 3 ,α 4 ,...,α n ]If the prediction interval boundary parameter α is used to divide the prediction interval, the error of the predicted load value can be calculated to be [ min, t ] respectively 1 ],[t 1 ,t 2 ],[t 2 ,t 3 ],[t 3 ,t 4 ],[t 4 ,t 5 ],…,[t n ,max]And predicting a normal distribution model in the interval.
According to the probability statistics theory, under the condition of normal distribution and the condition of a prediction interval boundary parameter alpha for evaluating the confidence coefficient, the confidence interval of the probability prediction of the diversified loads is as follows:
max=y+z*σ+u
min=y-z*σ+u
in the formula: max is the upper limit value of the prediction interval, min is the lower limit value of the prediction interval, y is the prediction value, z is the normal distribution quantile point corresponding to the boundary parameter alpha of the prediction interval, and sigma and u are the standard deviation and the mean value of the error of the load prediction value.
Boundary value t of predicted value interval i And a prediction interval boundary parameter alpha i The relationship between them is as follows:
t i =min+α i *(max-min)
in the formula: alpha is alpha i Is a constant between 0 and 1, and determines the quality of the final divided section.
Specifically, the conditional probability interval prediction is a more objective and reliable probability prediction method established by dividing prediction errors into different modules according to a certain characteristic, so that the diversified load prediction values are divided into different prediction blocks, and the distribution function of the diversified load prediction errors in each block is fitted into normal distribution, so that the error distribution description of the load prediction values can be more exquisite, and the final probability prediction result is more reliable.
And step S105, generating a diversified load condition probability interval prediction model according to the multiple groups of prediction error normal distribution functions and the multiple prediction intervals.
And S106, performing iterative optimization on the diversified load condition probability interval prediction model, and updating the boundary parameter of the prediction interval in the optimization process to determine the optimal boundary parameter value of the prediction interval. The optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real value of each group of loads falls in the corresponding prediction interval.
In some embodiments of the application, a multivariate load condition probability interval prediction model is optimized based on a PSO optimization method, and an optimal prediction interval boundary parameter value is searched, so that the comprehensive quality of a prediction interval is optimal.
And S107, determining the optimal prediction interval of the diversified loads according to the optimal prediction interval boundary parameter.
Further, after the determining the optimal prediction interval of the diversified loads, the method further includes:
and performing prediction evaluation on the optimal prediction intervals of a plurality of samples. The prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval. The prediction interval evaluation comprises: average coverage error assessment, sensitivity assessment, and composite score value assessment.
Specifically, the average coverage error evaluation is used for evaluating the reliability of the optimal prediction interval, and the smaller the absolute value of the average coverage error evaluation is, the more reliable the prediction interval is, specifically, the following formula is used for performing:
R=[ζ-(1-α)]×100%
wherein, R represents the average coverage rate error of the optimal prediction interval when the boundary parameter of the prediction interval is 1-alpha, and ζ represents the actual coverage rate of the optimal prediction interval when the boundary parameter of the prediction interval is 1-alpha.
And sensitivity evaluation is used for describing the change situation of the average width of the optimal prediction interval, and the lower the sensitivity value is, the narrower the interval width is, and the sensitivity evaluation is specifically carried out by the following formula:
in the formula, n represents the number of test samples, up i And low i The optimal prediction interval upper limit value and the optimal prediction interval lower limit value of the ith sample are respectively represented, and R represents the maximum capacity value of the load.
And evaluating the comprehensive score value, which is used for determining the comprehensive quality of the optimal prediction interval, wherein the smaller the absolute value of the comprehensive score value is, the higher the quality of the optimal prediction interval is, and otherwise, the worse the quality is, and the method is specifically carried out by the following formula:
in the formula (I), the compound is shown in the specification,represents the optimal prediction interval width of the ith sample when the boundary parameter of the prediction interval is 1-alpha, up (i) and low (i) respectively represent the optimal prediction interval upper limit value and lower limit value of the ith sample, yt (i) represents the real value of the ith sample, n represents the number of test samples, sc (i) represents the score of the ith sample, and S represents the comprehensive score value of the optimal prediction interval。
In the actual operation process, specifically referring to fig. 3, an error distribution diagram of the load predicted value in the diversified load interval prediction method disclosed in the embodiment of the present application is shown, where the diagram (a), the diagram (b), the diagram (c), and the diagram (d) in fig. 3 respectively show prediction error histograms of the load predicted value with errors of [0,3.701], [3.701, 22.952], [22.952, 32.984], and [32.984, 148.5 ]. Specifically, referring to fig. 4, it is a prediction result diagram of an optimal prediction interval when a prediction interval boundary parameter is 0.95 in the diversified load interval prediction method disclosed in the embodiment of the present application. As can be seen from the figure, the conditional normal distribution model is introduced into the diversified load interval prediction, so that the reliability of the probability prediction result can be improved, the quality of the prediction interval can be improved, and reliable information and basis can be provided for the operation and the regulation of the system.
According to the technical scheme, the method and the device for predicting the diversified load interval are disclosed. Then dividing the load predicted value into different prediction sections, fitting the error distribution of the load predicted value in each prediction section by normal distribution, and establishing a diversified load condition probability section prediction model. And then, carrying out iterative optimization on the diversified load conditional probability interval prediction model, and finally determining the optimal prediction interval of the diversified load. The effectiveness and the correctness of the optimal prediction interval are verified by performing prediction evaluation on the optimal prediction interval.
In the actual operation process, the point prediction is only carried out on diversified loads, inevitable prediction errors exist, and therefore the upper limit value and the lower limit value of the prediction are important to obtain. Therefore, interval prediction is carried out on diversified loads, and on the premise that the true value of each group of loads is ensured to fall in the corresponding obtained prediction interval, the smaller the range of each prediction interval is, the better the prediction result is, so that the prediction result is more accurate, and practical and reliable information is provided for operation regulation and control of the power system.
The following are embodiments of the apparatus disclosed herein for performing the above-described method embodiments. For details not disclosed in the device embodiments, refer to the method embodiments.
A second embodiment of the present application discloses a diversified load interval prediction apparatus, which is applied to the diversified load interval prediction method according to the first aspect, and with reference to a schematic structural diagram shown in fig. 5, the apparatus includes:
and the point prediction module 10 is configured to obtain diversified load historical data information and multiple groups of load real values, perform point prediction on the diversified load historical data information, and determine multiple groups of load predicted values corresponding to the multiple groups of load real values one to one.
And the error obtaining module 20 is configured to determine an error of each group of load predicted values according to the one-to-one corresponding multiple groups of load predicted values and multiple groups of load true values.
And the function obtaining module 30 is configured to obtain multiple groups of prediction error normal distribution functions, where each group of prediction error normal distribution functions corresponds to errors of each group of load predicted values one to one.
Further, the function obtaining module 30 includes:
and the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values.
And the function acquisition unit is used for determining a plurality of groups of prediction error normal distribution functions according to the errors of each group of load prediction values, the error mean value and the error standard deviation.
And the interval division module 40 is configured to perform interval division on the multiple groups of load predicted values according to the multiple groups of load predicted values and preset predicted interval boundary parameters, and determine multiple predicted intervals.
Further, the interval dividing module 40 includes:
and the normal distribution quantile acquisition unit is used for determining the normal distribution quantile corresponding to the boundary parameter of the prediction interval according to the preset boundary parameter of the prediction interval.
And the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values.
And the interval upper and lower limit value acquisition unit is used for determining the upper and lower limit values of a group of prediction interval values according to the normal distribution quantile points, the error mean values and the error standard deviations aiming at any load prediction value.
And the boundary value acquisition unit is used for determining the boundary value of a group of predicted intervals according to the predicted interval boundary parameter and the upper limit value and the lower limit value of the group of predicted intervals.
And the predicted block section acquisition unit is used for determining a predicted block section according to the upper limit value and the lower limit value of the group of predicted block sections and the boundary value of the group of predicted block sections.
A plurality of predicted block segments are obtained.
And the interval prediction model establishing module 50 is configured to generate a diversified load condition probability interval prediction model according to the plurality of groups of prediction error normal distribution functions and the plurality of prediction intervals.
And the optimization processing module 60 is configured to perform iterative optimization on the diversified load condition probability interval prediction model, and update the prediction interval boundary parameter in the optimization process to determine an optimal prediction interval boundary parameter value. The optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real value of each group of loads falls in the corresponding prediction interval.
And an optimal prediction interval obtaining module 70, configured to determine an optimal prediction interval of the diversified loads according to the optimal prediction interval boundary parameter.
Further, the diversified load interval prediction device further comprises a prediction evaluation module, and the prediction evaluation module is used for performing prediction evaluation on the optimal prediction interval after the optimal prediction interval of the diversified load is determined. The prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval.
Further, the prediction interval evaluation comprises: average coverage error evaluation, sensitivity evaluation and comprehensive score value evaluation.
The present application has been described in detail with reference to particular embodiments and illustrative examples, but the description is not intended to be construed as limiting the application. Those skilled in the art will appreciate that various equivalent substitutions, modifications or improvements may be made to the presently disclosed embodiments and implementations thereof without departing from the spirit and scope of the present disclosure, and these fall within the scope of the present disclosure. The protection scope of this application is subject to the appended claims.
Claims (10)
1. A diversified load interval prediction method, characterized in that the method comprises:
acquiring diversified load historical data information and multiple groups of load real values, performing point prediction on the diversified load historical data information, and determining multiple groups of load predicted values corresponding to the multiple groups of load real values one by one;
determining the error of each group of load predicted values according to the one-to-one corresponding groups of load predicted values and the groups of load real values;
acquiring a plurality of groups of prediction error normal distribution functions, wherein each group of prediction error normal distribution functions corresponds to the errors of each group of load predicted values one by one;
according to the multiple groups of load predicted values and preset predicted interval boundary parameters, carrying out interval division on the multiple groups of load predicted values, and determining multiple predicted intervals;
generating a diversified load conditional probability interval prediction model according to the multiple groups of prediction error normal distribution functions and the multiple prediction intervals;
performing iterative optimization on the diversified load condition probability interval prediction model, updating the boundary parameter of the prediction interval in the optimization process, and determining the optimal boundary parameter value of the prediction interval; the optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real load value of each group falls in the corresponding prediction interval;
and determining the optimal prediction interval of the diversified loads according to the optimal prediction interval boundary parameter.
2. The diversified load interval prediction method according to claim 1, wherein said obtaining a plurality of groups of prediction error normal distribution functions comprises:
determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
and determining a plurality of groups of prediction error normal distribution functions according to the error of each group of load predicted values, the error mean value and the error standard deviation.
3. The diversified load interval prediction method according to claim 1, wherein the performing interval division on the multiple groups of load prediction values according to the multiple groups of load prediction values and a preset prediction interval boundary parameter, and determining multiple prediction intervals comprises:
determining a normal distribution quantile corresponding to the boundary parameter of the prediction interval according to the preset boundary parameter of the prediction interval;
determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
for any load predicted value, determining the upper limit value and the lower limit value of a group of predicted sections according to the normal distribution quantiles, the error mean value and the error standard deviation;
determining a boundary value of a group of prediction intervals according to the boundary parameter of the prediction intervals and the upper and lower limit values of the group of prediction intervals;
determining a predicted interval according to the upper and lower limit values of the group of predicted intervals and the boundary value of the group of predicted intervals;
a plurality of predicted block segments are obtained.
4. The diversified load interval prediction method according to claim 1, further comprising, after said determining an optimal prediction interval of the diversified load:
performing prediction evaluation on the optimal prediction interval; the prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval.
5. The diversified load interval prediction method according to claim 4, wherein said prediction interval evaluation comprises: average coverage error assessment, sensitivity assessment, and composite score value assessment.
6. A diversified load section prediction apparatus applied to the diversified load section prediction method according to any one of claims 1 to 5, the apparatus comprising:
the point prediction module is used for acquiring diversified load historical data information and multiple groups of load real values, performing point prediction on the diversified load historical data information and determining multiple groups of load predicted values which are in one-to-one correspondence with the multiple groups of load real values;
the error acquisition module is used for determining the error of each group of load predicted values according to the one-to-one corresponding groups of load predicted values and the groups of load real values;
the function acquisition module is used for acquiring a plurality of groups of prediction error normal distribution functions, and each group of prediction error normal distribution functions corresponds to the error of each group of load predicted values one by one;
the interval division module is used for carrying out interval division on the multiple groups of load predicted values according to the multiple groups of load predicted values and preset predicted interval boundary parameters and determining multiple predicted intervals;
the interval prediction model establishing module is used for generating a diversified load condition probability interval prediction model according to the multiple groups of prediction error normal distribution functions and the multiple prediction intervals;
the optimization processing module is used for performing iterative optimization on the diversified load condition probability interval prediction model, updating the boundary parameter of the prediction interval in the optimization process and determining the optimal boundary parameter value of the prediction interval; the optimal boundary parameter value is a prediction interval boundary parameter value which enables the range of each prediction interval to be minimum on the premise of ensuring that the real value of each group of loads falls in the corresponding prediction interval;
and the optimal prediction interval acquisition module is used for determining the optimal prediction interval of the diversified loads according to the boundary parameter of the optimal prediction interval.
7. The diversified load interval prediction device according to claim 6, wherein the function obtaining module comprises:
the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
and the function acquisition unit is used for determining a plurality of groups of prediction error normal distribution functions according to the errors of each group of load prediction values, the error mean value and the error standard deviation.
8. The diversified load interval prediction device according to claim 6, wherein the interval division module comprises:
a normal distribution quantile obtaining unit, configured to determine, according to the preset prediction interval boundary parameter, a normal distribution quantile corresponding to the prediction interval boundary parameter;
the mean standard deviation obtaining unit is used for determining an error mean value and an error standard deviation corresponding to the error of each group of load predicted values according to the error of each group of load predicted values;
the interval upper and lower limit value acquisition unit is used for determining the upper and lower limit values of a group of prediction interval values according to the normal distribution quantile points, the error mean values and the error standard deviations aiming at any load prediction value;
a boundary value obtaining unit, configured to determine a boundary value of a group of predicted sections according to the predicted section boundary parameter and upper and lower limit values of the group of predicted sections;
a predicted block section obtaining unit configured to determine a predicted block section based on upper and lower limit values of the group of predicted block sections and a boundary value of the group of predicted block sections; a plurality of predicted block segments are obtained.
9. The diversified load interval prediction device according to claim 6, further comprising a prediction evaluation module for performing prediction evaluation on the optimal prediction interval after the optimal prediction interval of the diversified load is determined; the prediction evaluation is used for verifying the validity and correctness of the optimal prediction interval.
10. The diversified load interval prediction device according to claim 9, wherein the prediction interval evaluation comprises: average coverage error assessment, sensitivity assessment, and composite score value assessment.
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