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Deep Echo State Network with Variable Memory Pattern for Solar Irradiance Prediction

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Listed:
  • Qian Li
  • Tao Li
  • Jiangang Ouyang
  • Dayong Yang
  • Zhijun Guo
  • Inés P. Mariño

Abstract

Accurate solar irradiance prediction plays an important role in ensuring the security and stability of renewable energy systems. Solar irradiance modeling is usually a time-dependent dynamic model. As a new kind of recurrent neural network, echo state network (ESN) shows excellent performance in the field of time series prediction. However, the memory length of classical ESN is fixed and finite, which makes it hard to map sufficient features of solar irradiance with long-range dependency. Therefore, a novel deep echo state network with variable memory pattern (VMP-DESN) is proposed in this brief. VMP-DESN consists of multiple connected reservoirs in series, and there exist different types of memory modes in VMP-DESN. To remember more input history information in the states, the time delay links are added in each reservoir and between every two reservoirs. The VMP-DESN is more flexible to deal with different input signals due to its variable memory modes in the reservoir states. Additionally, the effect of different memory patterns on the VMP-DESN performance is discussed in detail, including the antidisturbance ability, memory capacity, and prediction accuracy. Finally, the effectiveness of VMP-DESN is evaluated by predicting the real solar irradiance task.

Suggested Citation

  • Qian Li & Tao Li & Jiangang Ouyang & Dayong Yang & Zhijun Guo & Inés P. Mariño, 2022. "Deep Echo State Network with Variable Memory Pattern for Solar Irradiance Prediction," Complexity, Hindawi, vol. 2022, pages 1-11, October.
    • Handle: RePEc:hin:complx:8506312
    DOI: 10.1155/2022/8506312
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