Day-Ahead Solar Irradiation Forecasting Utilizing Gramian Angular Field and Convolutional Long Short-Term Memory

Ying-Yi Hong,John Joel F Martinez,Arnel C Fajardo

doi:10.1109/access.2020.2967900

Ying-Yi Hong, John Joel F Martinez + Show 1 more

Open Access

https://doi.org/10.1109/access.2020.2967900

Copy DOI

Journal: IEEE Access	Publication Date: Jan 1, 2020
Citations: 59	License type: CC BY 4.0

Affiliation: Technological Institute of the Philippines

Abstract

The operations of power systems are becoming more challenging on account of the high penetration of renewable power generation, including photovoltaic systems. One method for improving the power system operation involves making accurate forecasts of day-ahead solar irradiation, enabling operators to minimize uncertainty in managing the balance between generation and load. To overcome the limitations of Long Short-term Memory (LSTM) in a one-dimensional forecasting problem, this work proposes a novel method in forecasting solar irradiation by encoding time-series data into images using the Gramian Angular Field and the Convolutional LSTM (ConvLSTM) network. The pre-processed data become a five-dimensional input tensor that is perfectly suitable for ConvLSTM. The ConvLSTM network uses convolution operations in its input-to-state transition and state-to-state transition. The network thus enables time-series forecasting by a feature-rich approach, which ultimately provides competitive forecasting performance despite the use of a small dataset. The proposed method was evaluated in day-ahead solar irradiation forecasting using a univariate dataset of Global Horizontal Irradiation (GHI) data from Fuhai in Taiwan. The proposed method was resampled using 5×2-fold cross-validation, and assessed using the Wilcoxon signed-rank test to determine the statistical significance of the result. It outperformed benchmark methods such as Autoregressive Integrated Moving Average (ARIMA), Convolutional Neural Network cascaded with Long Short-term Memory (CNN-LSTM), and LSTM cascaded with a fully-connected (FC) network.

Highlights

The capital cost for a renewable energy system has been falling over recent years
Considering the above information, this paper presents a novel approach by applying Gramian Angular Field (GAF) transformation to time-series data such as Global Horizontal Irradiation (GHI) for solar irradiation forecasting
The resulting image dataset is converted to a 5D tensor that will serve as an input to the ConvLSTM network

Summary

Introduction

The capital cost for a renewable energy system has been falling over recent years. The cost of solar PV systems has declined by 75% since 2010, causing a significant increase in investment in the field [1]. Owing to the high penetration of renewable power generation, power system operations are becoming increasingly challenging. The power generated by PV plants depends on the intermittent energy that is provided by the sun. The variability caused by the daily sun cycle and other meteorological factors gives rise to uncertainties in the determination of this power generation [2]. Power forecasting is critically important in the operation of power systems, as it helps operators dispatch/schedule the power generation from traditional fossil fuels [3]

Methods

Results

Conclusion