The Hybridization of Ensemble Empirical Mode Decomposition with Forecasting Models: Application of Short-Term Wind Speed and Power Modeling
Abstract
:1. Introduction
2. State-of-the-Art Methods
2.1. Empirical Mode Decomposition (EMD) Method
- mean of both envelopes (lower and upper) approaches zero
- count of minima and maxima, and zero crossings differs at most by one
2.2. Ensemble Empirical Mode Decomposition (EEMD) Method
2.3. Pattern Sequence based Forecasting (PSF) Method
2.4. Autoregressive Integrated Moving Average (ARIMA) Method
3. Proposed Methods
3.1. Hybrid EEMD-PSF Model
- Step 1: Apply EEMD method to transform a time-series in to a set of sub-series (IMFs and a residue).
- Step 2: Calculate the cluster size (K) and optimum window size (W) for the IMFs and residue.
- Step 3: Use PSF method to forecast all sub-series (IMFs and residue).
- Step 4: Add forecasted outcomes corresponding to all sub-series to achieve the ultimate forecasting results.
3.2. Hybrid EEMD-PSF-ARIMA Model
- Step 1: Apply EEMD method to transform a time-series in to a set of sub-series (IMFs and a residue).
- Step 2: Execute the KPSS test on all IMFs and the residue to differentiate them in stationary and non-stationary groups.
- Step 3: Apply the PSF method on stationary IMFs and the ARIMA method on non-stationary IMFs.
- Step 4: Add forecasted outcomes corresponding to all sub-series to achieve the ultimate forecasting results.
4. Case Study
- 24 h-ahead prediction with iterated strategy, and
- multiple step ahead prediction with direct strategy (12 and 24 h).
4.1. Case Study 1 - Wind Power Data
4.1.1. Simulation
4.1.2. Comparison and Discussion
4.2. Case Study 2—Wind Speed Data
4.2.1. Simulation
4.2.2. Comparison and Discussion
- Prediction with the proposed models (EEMD-PSF and EEMD-PSF-ARIMA) is more accurate as compared to other methods.
- The hybridization with EMD and EEMD methods with PSF, ARIMA, and LSSVM methods lead to more accurate predictions as compared to their original forms.
- Similar to case 1, the trade-off between accuracy in prediction and computation time consumption is observed in case 2. For example, EEMD-ARIMA and EMD-ARIMA show more prediction accuracy at the cost of excess in computation delays.
- While discussing computation time, there are a few different things from case 1:
- (a)
- the performance of the PSF model is better than that of the EMD-PSF model in terms of prediction accuracy as well as computation time, and
- (b)
- the computation time for models hybridized with the EEMD method noted longer than the models hybridized with the EMD method. For example, the EEMD-PSF consumed 11.41 s, whereas the EMD-PSF completed the task in 9.75 s.
- In Table 6, the ANOVA test results are shown. The EEMD-PSF-ARIMA model prediction results show one-sided p-values significant at and show statistical significance of the proposed comparison.
5. Conclusions
- In case of short-term wind power time-series prediction, both proposed methods have shown at least 18.03 and 14.78 percentage improvement in forecast accuracy as compared to contemporary methods considered in this study for direct and iterated strategies, respectively. Similarly, for wind speed data, those improvement observed to be 20.00 and 23.80 percentages, respectively.
- In all cases, EEMD-PSF-ARIMA has outperformed in terms of prediction accuracy improvements by at least 10.03 and 8.33 percentages in wind power and speed data, respectively. In wind power data, this achievement is attained at the cost of minute computation delay in the EEMD-PSF-ARIMA model better than EEMD-PSF model by merely few seconds. Conversely, in wind time-series, the EEMD-PSF-ARIMA model takes lesser computation delay as compared to the EEMD-PSF model. Hence, it can be stated that the forecasting accuracy benefits are much greater than the harm produced by the time delay.
- Furthermore, the hybridization of a prediction method with the EEMD method has improved the prediction accuracy significantly. For example, in wind power time-series, EEMD-PSF, EEMD-ARIMA, and EEMD-LSSVM models have shown 23.56, 29.34 and 6.76 percentage improvements in prediction accuracy, better than simple PSF, ARIMA, and LSSVM models, respectively.
Author Contributions
Conflicts of Interest
Abbreviations
AI | Artificial Intelligence |
AIC | Akaike’s Information Criterion |
ANN | Artificial Neural Networks |
ANOVA | Analysis of Variance |
AR | Autoregression |
ARMA | Autoregressive Moving Average |
ARIMA | Autoregressive Integrated Moving Average |
BIC | Schwartz Bayesian Information Criterion |
EEMD | Ensemble Empirical Mode Decomposition |
EMD | Empirical Mode Decomposition |
ENN | Elman Neural Network |
f-ARIMA | Fractional Autoregressive Integrated Moving Average |
GABP | Genetic Algorithm Back Propagation |
GARCH | Generalized Autoregressive Conditional Heteroskedasticity |
IMF | Intrinsic Mode Function |
kNN | k - Nearest Neighbors |
KPSS test | Kwiatkowski Phillips Schmidt Shin test |
LSSVM | Least Squares Support Vector Machine |
MAE | Mean Absolute Error |
MAPE | Mean Absolute Percentage Error |
NARX | Nonlinear Autoregressive Exogenous |
NN | Neural Networks |
PSF | Pattern Sequence based Forecasting |
RMSE | Root Mean Square Error |
SSA | Singular Spectrum Analysis |
SVM | Support Vector Machine |
WNN | Weighted Neural Network |
WRF | Weather Research and Forecasting |
WT | Wavelet Transform |
Appendix A. ‘decomposedPSF’—An R Package
Models | Functions |
---|---|
EMD-PSF | emdpsf(data, n.ahead) |
EEMD-PSF | eemdpsf(data, n.ahead) |
EMD-ARIMA | emdarima(data, n.ahead) |
EEMD-ARIMA | eemdarima(data, n.ahead) |
EMD-PSF-ARIMA | emdpsfarima(data, n.ahead) |
EEMD-PSF-ARIMA | eemdpsfarima(data, n.ahead) |
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Median | Mean | Maximum | Minimum | Standard Deviation |
---|---|---|---|---|
576.50 | 757.20 | 2578.0 | 18.0 | 623.53 |
IMFs | EEMD-PSF (Method Selection) | EEMD-PSF-ARIMA (Method Selection) | |||
---|---|---|---|---|---|
IMF1 | >0.05 | PSF | (K = 3, W = 3) | PSF | (K = 3, W = 3) |
IMF2 | >0.05 | PSF | (K = 3, W = 9) | PSF | (K = 3, W = 9) |
IMF3 | >0.05 | PSF | (K = 3, W = 7) | PSF | (K = 3, W = 7) |
IMF4 | >0.05 | PSF | (K = 3, W = 1) | PSF | (K = 3, W = 1) |
IMF5 | >0.05 | PSF | (K = 3, W = 1) | PSF | (K = 3, W = 1) |
IMF6 | >0.05 | PSF | (K = 2, W = 7) | PSF | (K = 2, W = 7) |
IMF7 | >0.05 | PSF | (K = 4, W = 9) | PSF | (K = 4, W = 9) |
IMF8 | <0.05 | PSF | (K = 3, W = 10) | ARIMA | (p = 1, d = 2, q = 0) |
IMF9 | <0.05 | PSF | (K = 2, W = 1) | ARIMA | (p = 1, d = 2, q = 0) |
IMF10 | <0.05 | PSF | (K = 2, W = 10) | ARIMA | (p = 0, d = 2, q = 5) |
Residue | <0.05 | PSF | (K = 2, W = 1) | ARIMA | (p = 0, d = 2, q = 0) |
Error Measures | RMSE | MAE | MAPE | |||
---|---|---|---|---|---|---|
Models | 1 Step ahead | 2 Steps ahead | 1 Step ahead | 2 Steps ahead | 1 Step ahead | 2 Steps ahead |
EEMD-PSF-ARIMA | 30.18 | 117.84 | 25.06 | 117.43 | 6.34 | 17.73 |
EEMD-PSF | 49.95 | 147.89 | 44.24 | 133.19 | 8.27 | 17.93 |
EMD-PSF-ARIMA | 98.64 | 175.67 | 92.41 | 143.95 | 16.33 | 22.02 |
EMD-PSF | 148.14 | 182.69 | 135.88 | 170.64 | 24.83 | 28.38 |
PSF | 174.73 | 185.21 | 169.02 | 175.43 | 26.92 | 28.91 |
EEMD-ARIMA | 178.22 | 193.05 | 174.66 | 180.52 | 27.11 | 29.39 |
EMD-ARIMA | 189.12 | 212.91 | 180.82 | 203.66 | 29.31 | 31.48 |
ARIMA | 195.21 | 257.8 | 193.13 | 220.98 | 41.98 | 48.82 |
EEMD-LSSVM | 202.07 | 262.37 | 197.08 | 245.06 | 43.78 | 50.43 |
LSSVM | 226.92 | 262.76 | 221.28 | 258.31 | 47.28 | 52.27 |
Horizon | 12 Hours | 24 Hours | ||||
---|---|---|---|---|---|---|
Models | RMSE | MAE | MAPE | RMSE | MAE | MAPE |
EEMD-PSF-ARIMA | 149.78 | 132.93 | 24.97 | 166.33 | 148.25 | 34.34 |
EEMD-PSF | 152.29 | 137.56 | 25.73 | 184.88 | 167.06 | 38.40 |
EMS-PSF,ARIMA | 185.8 | 157.48 | 29.3 | 216.96 | 189.85 | 46.72 |
EMD-PSF | 200.24 | 179.46 | 38.96 | 226.78 | 203.34 | 51.97 |
PSF | 205.54 | 191.94 | 39.85 | 241.88 | 217.16 | 57.59 |
EEMD-ARIMA | 299.73 | 213.26 | 54.30 | 317.81 | 282.22 | 62.02 |
EMD-ARIMA | 354.78 | 305.19 | 57.34 | 385.79 | 330.14 | 66.14 |
ARIMA | 419.65 | 380.26 | 59.10 | 449.83 | 423.78 | 71.94 |
EEMD-LSSVM | 434.60 | 406.22 | 60.52 | 482.54 | 436.06 | 74.54 |
LSSVM | 460.03 | 422.01 | 65.46 | 517.57 | 473.97 | 78.76 |
Models | Wind Power Data | Wind Speed Data |
---|---|---|
EMD-PSF-ARIMA | 9.28 | 10.18 |
EEMD-PSF-ARIMA | 8.48 | 10.95 |
EMD-PSF | 7.10 | 9.75 |
EEMD-PSF | 6.91 | 11.41 |
EMD-ARIMA | 12.57 | 13.37 |
EEMD-ARIMA | 10.37 | 7.2 |
PSF | 1.35 | 1.68 |
ARIMA | 0.49 | 0.48 |
LSSVM | 1.11 | 0.26 |
EEMD-LSSVM | 1.99 | 1.09 |
Models | Wind Power Data | Wind Speed Data |
---|---|---|
EMD-PSF-ARIMA | 1.13 | 3.01 |
EMD-PSF | 2.53 | 0.003 |
EEMD-PSF | 1.29 | 1.41 |
EMD-ARIMA | 0.087 | 4.4 |
EEMD-ARIMA | 0.009 | 0.007 |
PSF | 2.83 | 7.9 |
ARIMA | 0.043 | 5.46 |
LSSVM | 0.062 | 4.69 |
EEMD-LSSVM | 0.062 | 4.55 |
Median | Mean | Maximum | Minimum | Standard Deviation |
---|---|---|---|---|
4.66 | 5.19 | 18.34 | 0.00 | 2.88 |
IMFs | p-Value | EEMD-PSF (Method Selection) | EEMD-PSF-ARIMA (Method Selection) | ||
---|---|---|---|---|---|
IMF1 | >0.05 | PSF | (K = 6, W = 1) | PSF | (K = 6, W = 1) |
IMF2 | >0.05 | PSF | (K = 10, W = 5) | PSF | (K = 10, W = 5) |
IMF3 | >0.05 | PSF | (K = 4, W = 10) | PSF | (K = 4, W = 10) |
IMF4 | >0.05 | PSF | (K = 3, W = 10) | PSF | (K = 3, W = 10) |
IMF5 | >0.05 | PSF | (K = 6, W = 10) | PSF | (K = 6, W = 10) |
IMF6 | >0.05 | PSF | (K = 4, W = 10) | PSF | (K = 4, W = 10) |
IMF7 | <0.05 | PSF | (K = 4, W = 3) | ARIMA | (p = 1, d = 1, q = 0) |
IMF8 | <0.05 | PSF | (K = 4, W = 1) | ARIMA | (p = 1, d = 2, q = 0) |
IMF9 | <0.05 | PSF | (K = 2, W = 1) | ARIMA | (p = 1, d = 2, q = 0) |
IMF10 | <0.05 | PSF | (K = 2, W = 1) | ARIMA | (p = 0, d = 2, q = 2) |
Residue | <0.05 | PSF | (K = 2, W = 10) | ARIMA | (p = 0, d = 2, q = 5) |
Error Measures | RMSE | MAE | MAPE | |||
---|---|---|---|---|---|---|
Models | 1 Step Ahead | 2 Steps Ahead | 1 Step Ahead | 2 Steps Ahead | 1 Step Ahead | 2 Steps Ahead |
EEMD-PSF-ARIMA | 0.15 | 0.18 | 0.13 | 0.16 | 4.2 | 6.17 |
EEMD-PSF | 0.16 | 0.21 | 0.14 | 0.19 | 4.44 | 7.86 |
PSF | 0.21 | 0.28 | 0.19 | 0.22 | 6.26 | 8.74 |
EMD-PSF-ARIMA | 0.23 | 0.49 | 0.21 | 0.43 | 6.31 | 12.88 |
EEMD-ARIMA | 0.23 | 0.47 | 0.21 | 0.32 | 6.29 | 12.07 |
EMD-PSF | 0.47 | 0.71 | 0.39 | 0.63 | 12.78 | 15.18 |
EMD-ARIMA | 0.23 | 0.61 | 0.21 | 0.57 | 6.36 | 13.49 |
EEMD-LSSVM | 0.63 | 0.86 | 0.52 | 0.79 | 18.49 | 19.49 |
ARIMA | 0.58 | 0.74 | 0.50 | 0.69 | 15.69 | 18.16 |
LSSVM | 0.72 | 1.07 | 0.77 | 0.94 | 23.01 | 26.74 |
Horizon | 12 Hours | 24 Hours | ||||
---|---|---|---|---|---|---|
Models | RMSE | MAE | MAPE | RMSE | MAE | MAPE |
EEMD-PSF-ARIMA | 0.23 | 0.19 | 5.48 | 0.33 | 0.28 | 9.42 |
EEMD-PSF | 0.34 | 0.28 | 8.18 | 0.36 | 0.29 | 11.14 |
PSF | 0.42 | 0.38 | 11.03 | 0.45 | 0.34 | 15.01 |
EMD-PSF-ARIMA | 0.66 | 0.58 | 16.61 | 0.84 | 0.76 | 21.88 |
EEMD-ARIMA | 0.61 | 0.57 | 15.98 | 0.66 | 0.52 | 19.39 |
EMD-PSF | 1.12 | 0.97 | 26.74 | 1.38 | 1.25 | 34.13 |
EMD-ARIMA | 0.69 | 0.65 | 18.32 | 1.00 | 0.92 | 26.57 |
EEMD-LSSVM | 1.20 | 1.10 | 29.37 | 1.61 | 1.42 | 39.42 |
ARIMA | 1.17 | 1.00 | 27.72 | 1.46 | 1.41 | 38.47 |
LSSVM | 1.48 | 1.47 | 31.21 | 1.73 | 1.45 | 39.44 |
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Bokde, N.; Feijóo, A.; Al-Ansari, N.; Tao, S.; Yaseen, Z.M. The Hybridization of Ensemble Empirical Mode Decomposition with Forecasting Models: Application of Short-Term Wind Speed and Power Modeling. Energies 2020, 13, 1666. https://doi.org/10.3390/en13071666
Bokde N, Feijóo A, Al-Ansari N, Tao S, Yaseen ZM. The Hybridization of Ensemble Empirical Mode Decomposition with Forecasting Models: Application of Short-Term Wind Speed and Power Modeling. Energies. 2020; 13(7):1666. https://doi.org/10.3390/en13071666
Chicago/Turabian StyleBokde, Neeraj, Andrés Feijóo, Nadhir Al-Ansari, Siyu Tao, and Zaher Mundher Yaseen. 2020. "The Hybridization of Ensemble Empirical Mode Decomposition with Forecasting Models: Application of Short-Term Wind Speed and Power Modeling" Energies 13, no. 7: 1666. https://doi.org/10.3390/en13071666
APA StyleBokde, N., Feijóo, A., Al-Ansari, N., Tao, S., & Yaseen, Z. M. (2020). The Hybridization of Ensemble Empirical Mode Decomposition with Forecasting Models: Application of Short-Term Wind Speed and Power Modeling. Energies, 13(7), 1666. https://doi.org/10.3390/en13071666