Cloud optical depth retrieval via sky's infrared image for solar radiation prediction

Photovoltaic (PV) system is developed to harness solar energy as an alternative energy to reduce the dependency on fossil fuel energy. However, the output of the PV system is not stable due to the fluctuation of solar radiation. Hence, solar radiation prediction in advanced is needed to make sure th...

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Main Authors: Yee, Lai Kok, Ken, Tan Lit, Asako, Yutaka, Quen, Lee Kee, Liang, Chuan Zun, Syahidah, Wan Nur, Homma, Koji, Arada, Gerald Pacaba, Siang, Gan Yee, Yen, Tey Wah, Sing, Calvin Kong Leng, Kamadinata, Jane Oktavia, Taguchi, Akira
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Published: Animo Repository 2019
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Online Access:https://animorepository.dlsu.edu.ph/faculty_research/1900
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Institution: De La Salle University
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spelling oai:animorepository.dlsu.edu.ph:faculty_research-28992021-07-30T01:06:17Z Cloud optical depth retrieval via sky's infrared image for solar radiation prediction Yee, Lai Kok Ken, Tan Lit Asako, Yutaka Quen, Lee Kee Liang, Chuan Zun Syahidah, Wan Nur Homma, Koji Arada, Gerald Pacaba Siang, Gan Yee Yen, Tey Wah Sing, Calvin Kong Leng Kamadinata, Jane Oktavia Taguchi, Akira Photovoltaic (PV) system is developed to harness solar energy as an alternative energy to reduce the dependency on fossil fuel energy. However, the output of the PV system is not stable due to the fluctuation of solar radiation. Hence, solar radiation prediction in advanced is needed to make sure the tap changer in PV system has enough time to respond. In this research, the cloud base temperature is identified from the sky's thermal image. From the cloud base temperature, cloud optical depth (COD) is calculated. Artificial neural network (ANN) models are established by using different combinations of current solar radiation and COD to predict the solar radiation several minutes in advanced. R-squared value is used to measure the accuracy of the models. For prediction in advanced for every minute, with COD as input, always show the highest R-squared value. The highest R-squared value is 0.8899 for the prediction for 1 minute in advanced and dropped to 0.5415 as the minute of prediction in advanced increase to 5. This shows that the proposed methodology is suitable for prediction of solar radiation for short term in advanced. © 2019 Penerbit Akademia Baru. 2019-06-01T07:00:00Z text https://animorepository.dlsu.edu.ph/faculty_research/1900 Faculty Research Work Animo Repository Solar radiation—Forecasting Infrared imaging Neural networks (Computer science) Electrical and Computer Engineering Electrical and Electronics Systems and Communications
institution De La Salle University
building De La Salle University Library
continent Asia
country Philippines
Philippines
content_provider De La Salle University Library
collection DLSU Institutional Repository
topic Solar radiation—Forecasting
Infrared imaging
Neural networks (Computer science)
Electrical and Computer Engineering
Electrical and Electronics
Systems and Communications
spellingShingle Solar radiation—Forecasting
Infrared imaging
Neural networks (Computer science)
Electrical and Computer Engineering
Electrical and Electronics
Systems and Communications
Yee, Lai Kok
Ken, Tan Lit
Asako, Yutaka
Quen, Lee Kee
Liang, Chuan Zun
Syahidah, Wan Nur
Homma, Koji
Arada, Gerald Pacaba
Siang, Gan Yee
Yen, Tey Wah
Sing, Calvin Kong Leng
Kamadinata, Jane Oktavia
Taguchi, Akira
Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
description Photovoltaic (PV) system is developed to harness solar energy as an alternative energy to reduce the dependency on fossil fuel energy. However, the output of the PV system is not stable due to the fluctuation of solar radiation. Hence, solar radiation prediction in advanced is needed to make sure the tap changer in PV system has enough time to respond. In this research, the cloud base temperature is identified from the sky's thermal image. From the cloud base temperature, cloud optical depth (COD) is calculated. Artificial neural network (ANN) models are established by using different combinations of current solar radiation and COD to predict the solar radiation several minutes in advanced. R-squared value is used to measure the accuracy of the models. For prediction in advanced for every minute, with COD as input, always show the highest R-squared value. The highest R-squared value is 0.8899 for the prediction for 1 minute in advanced and dropped to 0.5415 as the minute of prediction in advanced increase to 5. This shows that the proposed methodology is suitable for prediction of solar radiation for short term in advanced. © 2019 Penerbit Akademia Baru.
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author Yee, Lai Kok
Ken, Tan Lit
Asako, Yutaka
Quen, Lee Kee
Liang, Chuan Zun
Syahidah, Wan Nur
Homma, Koji
Arada, Gerald Pacaba
Siang, Gan Yee
Yen, Tey Wah
Sing, Calvin Kong Leng
Kamadinata, Jane Oktavia
Taguchi, Akira
author_facet Yee, Lai Kok
Ken, Tan Lit
Asako, Yutaka
Quen, Lee Kee
Liang, Chuan Zun
Syahidah, Wan Nur
Homma, Koji
Arada, Gerald Pacaba
Siang, Gan Yee
Yen, Tey Wah
Sing, Calvin Kong Leng
Kamadinata, Jane Oktavia
Taguchi, Akira
author_sort Yee, Lai Kok
title Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
title_short Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
title_full Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
title_fullStr Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
title_full_unstemmed Cloud optical depth retrieval via sky's infrared image for solar radiation prediction
title_sort cloud optical depth retrieval via sky's infrared image for solar radiation prediction
publisher Animo Repository
publishDate 2019
url https://animorepository.dlsu.edu.ph/faculty_research/1900
_version_ 1707059170438545408