Short-term local prediction of wind speed and wind power based on singular spectrum analysis and locality-sensitive hashing

Ling Liu,Mengshi Li,Tianyao Ji,Qinghua Wu,Ziming Chen

doi:10.1007/s40565-018-0398-0

Abstract

With the growing penetration of wind power in power systems, more accurate prediction of wind speed and wind power is required for real-time scheduling and operation. In this paper, a novel forecast model for short-term prediction of wind speed and wind power is proposed, which is based on singular spectrum analysis (SSA) and locality-sensitive hashing (LSH). To deal with the impact of high volatility of the original time series, SSA is applied to decompose it into two components: the mean trend, which represents the mean tendency of the original time series, and the fluctuation component, which reveals the stochastic characteristics. Both components are reconstructed in a phase space to obtain mean trend segments and fluctuation component segments. After that, LSH is utilized to select similar segments of the mean trend segments, which are then employed in local forecasting, so that the accuracy and efficiency of prediction can be enhanced. Finally, support vector regression is adopted for prediction, where the training input is the synthesis of the similar mean trend segments and the corresponding fluctuation component segments. Simulation studies are conducted on wind speed and wind power time series from four databases, and the final results demonstrate that the proposed model is more accurate and stable in comparison with other models.

Highlights

As fossil fuels are gradually being depleted, wind energy, as a non-polluting type of renewable energy, has been rapidly developed [1]
A forecast model based on singular spectrum analysis (SSA), locality-sensitive hashing (LSH) and Support vector regression (SVR) is proposed for short-term wind speed and wind power prediction
The training input for SVR is a synthesis of the mean trend and the fluctuation component, which helps to ensure that these two components are independent and do not interfere with each other, leading to more accurate forecast results

Summary

Introduction

As fossil fuels are gradually being depleted, wind energy, as a non-polluting type of renewable energy, has been rapidly developed [1]. The proportion of wind energy keeps increasing and this trend will continue for a long time [2]. In China, wind power has been vigorously developed. By the end of 2016, the installed capacity of wind power has increased to 149 GW, with an increment of 3% over 2015 [3]. With more and more wind power feeding into power systems, the randomness and intermittent nature of wind speed and wind power jeopardizes the stability and reliability of power system operation and raises the operating cost [4]. In order to alleviate the adverse effects of wind power integration, more accurate and stable forecasting is critical and urgently needed [5]

Objectives

Findings

Discussion

Conclusion