CN102184453A - Wind power combination predicting method based on fuzzy neural network and support vector machine - Google Patents

Abstract

The invention provides a wind-field power combination predicting method based on a fuzzy neural network and a support vector machine, which comprises the following steps of: acquiring and pre-processing data; setting up a fuzzy neural network model by using a normalized training sample set and a prediction sample set and predicting; setting up a support vector machine model and predicting; linearly combining the prediction results of the two algorithms to obtain a wind speed prediction value; and setting up a wind speed power expert table via historical data, and inquiring the expert table according to the predicted wind speed value so as to obtain a power prediction result. By the method provided by the invention, the short-term prediction of a wind speed sequence can be effectively realized, the power prediction precision is improved, and fewer computing resources are consumed.

Description

Wind power combination forecasting method based on fuzzy neural network and support vector machine

Technical field

The present invention relates to a kind of data modeling and Forecasting Methodology, relate in particular to a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine based on artificial intelligence technology.

Technical background

Along with the fast development of wind-power electricity generation installed capacity, the ratio of wind-powered electricity generation in electrical network constantly increases.Because wind-powered electricity generation is a kind of intermittence, the undulatory property energy, large-scale wind-powered electricity generation inserts safety, the stable operation of electric system and guarantees that the quality of power supply brought severe challenge.If can make prediction more accurately to the wind speed and the generated output of wind field, then can effectively alleviate the influence of wind-powered electricity generation to whole electrical network.To help dispatching of power netwoks department in time to formulate reasonable Operation Mode and adjust operation plan exactly by wind power prediction, thereby guarantee reliable, high-quality, the economical operation of electric system.In general, according to the object difference of forecast model, Forecasting Methodology can be divided into based on the direct predicted method of power with based on the indirect predictions method of wind speed, and the present patent application belongs to the latter.

The domestic existing prognoses system time series methods that adopt based on the autoregression linear model more, because model itself is linear, precision of prediction is often not ideal enough according to this, and the single neural network method of existing employing needs more training sample usually, calculation consumption is excessive on the one hand, generalization ability preferably can't be guaranteed on the other hand, when sample information is insufficient, the better prediction precision can't be obtained again simultaneously.The present invention adopts fuzzy neural network and support vector machine to realize the combined prediction algorithm, fuzzy neural network possesses the advantage of powerful learning ability of neural network and fuzzy logic processes uncertain information simultaneously, and support vector machine processing small sample higher-dimension problem has a clear superiority in than traditional neural network, therefore, the binding energy of the two effectively overcomes existing ultrashort phase forecasting problem, can realize accurate ultrashort phase prediction with less historical sample.

Summary of the invention

The invention reside in the defective that overcomes prior art, a kind of intelligent data modeling algorithm that is used for the prediction of wind energy turbine set generated output is proposed, this method synthesis has utilized the advantage of fuzzy neural network and support vector machine, can in forecasting process, add the expertise experience, also can under the sufficient inadequately situation of blower fan historical data, realize the accurate short-term prediction of wind series, in the precision that improves power prediction, only consume less computational resource.

The object of the present invention is achieved like this:

A kind of wind power combination forecasting method based on fuzzy neural network and support vector machine comprises the steps:

(1) data obtains and pre-service.

Wind energy turbine set power prediction system utilizes data acquisition module to obtain data such as wind field wind speed, wind direction, temperature, humidity, atmospheric pressure and blower fan output power in the fixed time scope from the anemometer tower of wind field and wind field central monitoring system, obtains sample set thus and carries out normalized.Training sample set is input as:

V (t)=[X (t-m) ..., X (t-2), X (t-1), Vs (t-1), Vc (t-1), T (t-1), H (t-1), P (t-1)], wherein, X is a wind speed, and Vs is the wind speed sine, Vc is a wind speed cosine, and T is a temperature, and H is a humidity, P is an atmospheric pressure, and t is the moment to be predicted, and m is the length as the wind series of model input.

Training sample set is output as t wind speed X (t) constantly, and then [V (t), X (the t)] training sample that partners is right.By time range and the right number of time interval decision training sample.Forecast sample then is the V of current time.

The normalized formula is:

$X\left(t\right)=\frac{d\left(t\right)-\min \left(d\left(t\right)\right)}{\max \left(d\left(t\right)\right)-\min \left(d\left(t\right)\right)}$

Wherein, d (t) is a raw data, and X (t) is the data after the normalization.

(2) utilize training sample set and forecast sample collection after the normalization to set up fuzzy neural network model and prediction:

(2.1) the input and output dimension number of samples of determining the number of training sample and model need to determine to consider requirements such as computing time of model training and prediction and accuracy of predicting.Model adopts the output of multidimensional input one-dimensional.

(2.2) determine model structure and parameter and cycle of training number adopt fuzzy subtractive clustering to determine the structure of fuzzy model, determine that by selecting different cluster radius the model structure of optimum is to guarantee less training error; Cycle of training number definite computing time of need considering model training, avoid over training to guarantee extensive performance simultaneously.

(2.3) model training.Determined after the model structure that adopt training sample set pair model training, target is to minimize training error, the Error Calculation formula is:

$\mathrm{RMSE}=\sqrt{\frac{\underset{i=1}{\overset{n}{\mathrm{\Σ}}}{(V_{\mathrm{Mi}}-V_{\mathrm{Pi}})}^2}{n}}$

Wherein, V _MiBe i actual wind speed constantly, V _PiBe i prediction wind speed constantly, n is a number of samples;

(2.4) model prediction.Model training is input to model with the forecast sample collection after finishing, and obtains predicted value, then predicted value is added the forecast sample collection, re-enters model, and circulation obtains the multi-step prediction value according to this.

(2.5) predicted value aftertreatment.The anti-normalization of model predication value is reduced to actual value, judges whether to exist abnormity point simultaneously, if there is then in addition smoothing processing.Anti-normalized formula:

Y(t)＝u(t)*max(d(t))-min(d(t))+min(d(t)

Wherein, u (t) is the model output valve, and Y (t) is the data after the anti-normalization.

(3) set up supporting vector machine model and prediction:

(3.1) determine the number of training sample and the input and output dimension of model

Consider the advantage of support vector machine on small sample higher-dimension problem, the number of training sample can be less here, and the input dimension is desirable higher.Because scale is calculated in the training of support vector machine and training sample number exponentially changes, so the number of training sample is chosen the computing power that will consider particular hardware simultaneously.

(3.2) determine the super parameter value of model

There are three main super parameters in support vector machine: the insensitive loss factor, kernel function parameter and punishment parameter.Wherein, the selection of the insensitive loss factor and kernel function parameter is bigger to the model performance influence, therefore can adopt the crosscheck method to determine concrete parameter value.

(3.3) model training

Determined that training sample is right, selected radially basic kernel function for use, good super parameter value is determined in input, the beginning model training, and output support vector and Lagrange multiplier difference are finished in training.

(3.4) model prediction

Input forecast sample collection obtains the single step predicted value to the model that trains, and then predicted value is added former forecast sample collection and forms new forecast sample collection, re-enters model, and circulation obtains the multi-step prediction value according to this.

(3.5) predicted value aftertreatment

The model predication value of support vector machine is reduced to actual value, judges whether to exist abnormity point simultaneously, if there is then in addition smoothing processing.

(4) with two kinds of algorithm predicts results linear combination in addition, obtain the forecasting wind speed value.If historical predicated error is respectively e ₁, e ₂, now predicting the outcome is V ₁, V ₂, then predicting the outcome after the combination is respectively:

$P=\frac{e_2}{e_1+e_2}{V}_1+\frac{e_1}{e_1+e_2}{V}_2$

Be that historical predicated error is more little, this predicts that shared weight is then big more.

(5) set up wind speed power expert table by historical data, obtain the power prediction result thereby remove to inquire about expert's table according to the air speed value of prediction.

Owing to adopted above-mentioned technical solution, the inventive method is with the beneficial effect that existing method is compared:

One, the present invention has adopted fuzzy neural network (ANFIS) model, this model had both possessed the ability of carrying out reasoning and study in uncertain and out of true environment, fast convergence rate, good stability are arranged simultaneously, and the precision advantages of higher has innate advantage to handling the wind field environmental data;

Two, the present invention has adopted support vector machine (SVM) model simultaneously, and this model is the data digging method that grows up on the Statistical Learning Theory basis, obviously is better than traditional neural network on processing small sample higher-dimension problem.Therefore this model is suitable for the power prediction under the limited sample situation of wind field, simultaneously since its based on structural risk minimization, the generalization ability of model can be protected;

Three, based on the combined prediction algorithm of two kinds of models, can adjust the weight of two class models according to historical precision of prediction in real time, when obtaining the higher forecasting precision, strengthened the stability of prognoses system greatly.

Description of drawings

Fig. 1 prognoses system structural drawing;

Fig. 2 is the process flow diagram of fuzzy neural network modeling among the present invention;

Fig. 3 is the modeling process flow diagram of support vector machine among the present invention;

Fig. 4 is that the present invention gives weighted array with two kinds of algorithm predicts results, obtains the forecasting wind speed value, the combinational algorithm synoptic diagram;

Fig. 5 is a prognoses system program flow diagram of the present invention;

Fig. 6 is predicted power and real power curve map.

Embodiment

Below in conjunction with accompanying drawing the present invention is described in further detail.

Fig. 1 is a power prediction of the present invention system pie graph, and it has illustrated formation, effect and the implementation procedure of native system.System at first obtains wind field weather information data from the measurement module of wind field, obtain the power output data of blower fan from wind field central monitoring system (SCADA), by data processing module with in the data importing database, the prediction algorithm service routine extracts the historical sample data and forms training sample set forecast sample collection from database, be input to ANFIS and SVM model again, combinational algorithm draws final predicting the outcome, and will predict the outcome and store in the database server.At last, predicted data is shown to the user, and the power prediction result is reported dispatching of power netwoks mechanism by suitable communication interface by man-machine interface.

Fig. 2 is the process flow diagram of fuzzy neural network modeling among the present invention.Prognoses system is utilized data acquisition module to obtain data such as wind field wind speed, wind direction, temperature, humidity, atmospheric pressure and blower fan output power in the fixed time scope from the anemometer tower of wind field and wind field central monitoring system and is carried out normalized.Determine the number of training sample and the input and output dimension of model after utilizing normalization then, key elements such as the computing time of definite need consideration model training of number of samples and prediction and accuracy of predicting.Next be to adopt fuzzy subtractive clustering to determine the structure of fuzzy model, determine that by selecting different cluster radius optimum model structure is to guarantee less training error; Cycle of training number definite computing time of need considering model training, avoid over training to guarantee extensive performance simultaneously.Determined after the model structure that adopt training sample set pair model training, target is to minimize training error.Model training is input to model with the forecast sample collection after finishing, and obtains predicted value, then predicted value is added the forecast sample collection, re-enters model, and circulation obtains the multi-step prediction value according to this.Be the predicted value aftertreatment at last, model predication value is reduced to actual value, judge whether to exist abnormity point simultaneously, if there is then in addition smoothing processing.

Fig. 3 is a support vector machine modeling process flow diagram among the present invention.The normalized process is to determine the number of training sample and the input and output dimension of model with preceding identical afterwards.Consider the advantage of support vector machine on small sample higher-dimension problem, the number of training sample can be less here, and the input dimension is desirable higher.Because scale is calculated in the training of support vector machine and training sample number exponentially changes, so the number of training sample is chosen the computing power that will consider particular hardware simultaneously.Be to determine the super parameter value of model then.There are three main super parameters in support vector machine: the insensitive loss factor, kernel function parameter and punishment parameter.Wherein, the selection of the insensitive loss factor and kernel function parameter is bigger to the model performance influence, therefore can adopt the crosscheck method to determine concrete parameter value.Be the model training step then.Determined that training sample is right, selected radially basic kernel function for use, good super parameter value is determined in input, the beginning model training, and output support vector and Lagrange multiplier difference are finished in training.Import the forecast sample collection then to the model that trains, obtain the single step predicted value, then predicted value is added former forecast sample collection and form new forecast sample collection, re-enter model, circulation obtains the multi-step prediction value according to this.Model predication value with support vector machine is reduced to actual value at last, judges whether to exist abnormity point simultaneously, if there is then in addition smoothing processing.

Fig. 4 is a combinational algorithm synoptic diagram of the present invention.If historical predicated error is respectively e ₁, e ₂(general desirable preceding 5 prediction result statistics), now predicting the outcome is V ₁, V ₂, then predicting the outcome after the combination is respectively:

$P=\frac{e_2}{e_1+e_2}{V}_1+\frac{e_1}{e_1+e_2}{V}_2$

Be that historical predicated error is more little, this predicts that shared weight is then big more, and each prediction all can adjust according to historical prediction result, and real-time follow-up shows model preferably in the recent period.

After drawing the combined prediction result, can set up wind speed power expert table, obtain the power prediction result thereby remove to inquire about expert's table according to the air speed value of prediction by historical data.Fig. 5 has illustrated the real work process flow diagram of power prediction algorithm routine of the present invention, to predict 1 hour simultaneously and 4 hours generated outputs are example, Fig. 6 has provided the prediction effect figure of the inventive method, gets 40 sample points, and each sample point is the real 15 minutes mean value of power of sending out.Horizontal ordinate is the data number, and ordinate is the wind power size, and unit is MW.Three curves are arranged among the figure, and solid line is actual wind field generated output data, and dotted line is 1 one-hour rating predicted value, the asterisk line is 4 one-hour rating predicted values, 1 hour predicted root mean square error of gained is that 4.3%, 4 hour predicted root mean square error is 5.7%, and visible precision of prediction is good.Root-mean-square error adopts following formula to calculate:

$\mathrm{RMSE}=\sqrt{\frac{\underset{i=1}{\overset{n}{\mathrm{\Σ}}}{(P_{\mathrm{Mi}}-P_{\mathrm{Pi}})}^2}{\mathrm{Cap}*\sqrt{n}}}$

Wherein, P _MiBe i real power constantly, P _PiBe i predicted power constantly, Cap is average start capacity, and n is a number of samples.The start capacity is 7.6MW in this example.

Below embodiment has been described in detail the present invention in conjunction with the accompanying drawings, and those skilled in the art can make the many variations example to the present invention according to the above description.Thereby some details among the embodiment should not constitute limitation of the invention, and the scope that the present invention will define with appended claims is as protection scope of the present invention.

Claims (7)

1. the wind power combination forecasting method based on fuzzy neural network and support vector machine comprises the steps:

Step 1, data acquisition and pre-service:

Wind power forecasting system utilizes data acquisition module to obtain wind field wind speed, wind direction, temperature, humidity, atmospheric pressure and blower fan output power data in the fixed time scope from the anemometer tower of wind field and wind field monitoring system, Various types of data is provided with limits, out-of-limit abnormal data is corrected, obtained sample set thus and carry out normalized;

Step 2 utilizes training sample set and forecast sample collection after the normalization to set up fuzzy neural network model and prediction;

Step 3 is set up supporting vector machine model and prediction;

Step 4 with two kinds of algorithm predicts results linear combination in addition, obtains the forecasting wind speed value, that is:

If historical predicated error is respectively e ₁, e ₂, now predicting the outcome is V ₁, V ₂, then predicting the outcome after the combination is respectively:

$P=\frac{e_2}{e_1+e_2}{V}_1+\frac{e_1}{e_1+e_2}{V}_2$

Be that historical predicated error is more little, this predicts that shared weight is then big more;

Step 5 is set up wind speed power expert table by historical data, obtains the power prediction result thereby remove to inquire about expert's table according to the air speed value of prediction.

2. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 1 is characterized in that:

Wind speed in the described fixed time scope in the step 1, wind direction, temperature, humidity and atmospheric pressure data are meant in chronological sequence one group of data of tactic constant duration, training sample set is input as:

V(t)＝[X(t-m)，...，X(t-2)，X(t-1)，Vs(t-1)，Vc(t-1)，T(t-1)，H(t-1)，P(t-1)]，

Wherein, X is a wind speed, and Vs is the wind speed sine, and Vc is a wind speed cosine, and T is a temperature, and H is a humidity, and P is an atmospheric pressure, and t is the moment to be predicted, and m is the length as the wind series of model input;

Training sample set is output as t wind speed X (t) constantly, and then [V (t), X (the t)] training sample that partners is right, by time range and the right number of time interval decision training sample.Forecast sample then is the V of current time;

Normalized formula in the step 1 is:

$X\left(t\right)=\frac{d\left(t\right)-\min \left(d\left(t\right)\right)}{\max \left(d\left(t\right)\right)-\min \left(d\left(t\right)\right)}$

Wherein, d (t) is a raw data, and X (t) is the data after the normalization;

Anti-normalized formula:

Y(t)＝u(t)*max(d(t))-min(d(t))+min(d(t)

Wherein, u (t) is the model output valve, and Y (t) is the data after the anti-normalization.

3. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 1 is characterized in that:

In the step 2 utilize the training sample set after the normalization and the forecast sample collection is built the ANFIS model and prediction comprises the following steps:

2.1 empirical method is determined the number that training sample is right and the input dimension of model;

Adopt fuzzy subtractive clustering to determine model structure 2.2 set suitable cluster radius, set number cycle of training simultaneously;

2.3 model training is promptly determined after the good model structure, adopts training sample set with blended learning method training fuzzy neural network parameter, target is to minimize training error, and the Error Calculation formula is:

$\mathrm{RMSE}=\sqrt{\frac{\underset{i=1}{\overset{n}{\mathrm{\Σ}}}{(V_{\mathrm{Mi}}-V_{\mathrm{Pi}})}^2}{n}}$

Wherein, V _MiBe i actual wind speed constantly, V _PiBe i prediction wind speed constantly, n is a number of samples;

2.4 model prediction after promptly model training finishes, is input to model with the forecast sample collection, obtains predicted value, then predicted value is added the forecast sample collection, re-enters model, circulation obtains the multi-step prediction value according to this;

2.5 the predicted value aftertreatment is about to model predication value and is reduced to actual value, judge whether simultaneously to exist out-of-limit, if there is then in addition smoothing processing.

4. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 1 is characterized in that:

Setting up the SVM model and predicting in the step 3 comprises the following steps:

3.1 determine the number of training sample and the input and output dimension of model;

3.2 select radially basic kernel function for use, adopt the grid search method to determine the super parameter value of model;

3.3 model training has determined that training sample is right, good super parameter value is determined in input, the beginning model training, and output support vector and Lagrange multiplier difference are finished in training;

3.4 model prediction, input forecast sample collection obtains the single step predicted value to the model that trains, and then predicted value is added former forecast sample collection and forms new forecast sample collection, re-enters model, and circulation obtains the multi-step prediction value according to this;

3.5 the predicted value aftertreatment is reduced to actual value with the model predication value of support vector machine, judges whether to exist abnormity point simultaneously, if there is then in addition smoothing processing.

5. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 3 is characterized in that:

Step 2.1 is determined the number of training sample and the input and output dimension of model, be that computing time and the accuracy of predicting according to model training, prediction requires to determine number of samples, and model adopts multidimensional input one-dimensional to export.

6. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 3 is characterized in that:

Step 2.2 determine model structure and parameter and cycle of training number, be to adopt fuzzy subtractive clustering to determine the structure of fuzzy model, determine that by selecting different cluster radius the model structure of optimum is to guarantee less training error; Cycle of training number definite computing time of need considering model training, avoid over training to guarantee extensive performance simultaneously.

7. a kind of wind power combination forecasting method based on fuzzy neural network and support vector machine according to claim 4 is characterized in that:

Step 3.2 is determined the super parameter value of model, is to adopt the crosscheck method to determine concrete parameter value.

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