Solar Irradiance Nowcasting using IoT with LSTM-RNN

2022 IEEE 28th International Symposium for Design and Technology in Electronic Packaging (SIITME) Pub Date : 2022-10-26 DOI:10.1109/SIITME56728.2022.9988085

Vladimir Voicu, D. Petreus, R. Etz

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Abstract

Photovoltaic (PV) power stations are dependent on weather factors that influence their yield. Among the array of meteorological sensors required to determine power production is irradiance sensing instrumentation such as thermopile pyranometers and PV reference cells. Given the relatively high cost of these sensors some alternatives are entailed. This paper follows the development of a low cost solar irradiance sensor or a PV reference cell, using ubiquitous hardware – a Raspberry Pi Zero W, an INA219 current sensor, and a 300 milliwatt [mW] solar cell, calibrated with the help of a pyranometer. Deep learning techniques are used to reconstruct the GHI from values read by the current sensor. The univariate time series values read from the reference cell's current sensor are used as input to encode information into the long short-term memory recurrent neural networks (LSTM-RNN), with univariate time series values of GHI from the pyranometer as output. A signal translator is obtained with the role of predicting univariate time series of GHI that can be later used in PV applications.

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基于LSTM-RNN的物联网太阳辐照度临近预报

光伏电站依赖于影响其发电量的天气因素。在确定发电量所需的一系列气象传感器中，有辐照度传感仪器，如热电堆高温计和PV参考电池。考虑到这些传感器相对较高的成本，需要一些替代方案。本文跟踪了一种低成本太阳辐照度传感器或PV参考电池的开发，使用无处不在的硬件-树莓派Zero W, INA219电流传感器和300毫瓦[mW]太阳能电池，在热辐射计的帮助下进行校准。深度学习技术用于从当前传感器读取的值重建GHI。从参考细胞电流传感器读取的单变量时间序列值作为输入，将信息编码到长短期记忆递归神经网络(LSTM-RNN)中，并将来自高温计的单变量GHI时间序列值作为输出。获得了具有预测GHI单变量时间序列作用的信号转换器，该转换器可稍后用于PV应用。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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2022 IEEE 28th International Symposium for Design and Technology in Electronic Packaging (SIITME)

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