Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea

Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea

Although data-driven methods including deep neural network (DNN) were introduced, there was not enough assessment about spatial characteristics when using limited ground observation as reference. This work aimed to interpret the feasibility of several machine learning approaches to assess the spatia...

Full description

Bibliographic Details
Main Authors: Jong-Min Yeom, Seonyoung Park, Taebyeong Chae, Jin-Young Kim, Chang Suk Lee
Format: Article
Language:English
Published: MDPI AG 2019-05-01
Series:Sensors
Subjects:
solar radiation
artificial neural network
random forest
support vector machine
deep neural network
COMS MI
Online Access:https://www.mdpi.com/1424-8220/19/9/2082
id doaj-f4bd73f51d5d43e79b2ef78a145397cd
record_format Article
spelling doaj-f4bd73f51d5d43e79b2ef78a145397cd2020-11-25T01:34:05ZengMDPI AGSensors1424-82202019-05-01199208210.3390/s19092082s19092082Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South KoreaJong-Min Yeom0Seonyoung Park1Taebyeong Chae2Jin-Young Kim3Chang Suk Lee4Satellite Application Division, Korea Aerospace Research Institute, 115 Gwahangno Yuseong-gu, Daejeon 34133, KoreaSatellite Application Division, Korea Aerospace Research Institute, 115 Gwahangno Yuseong-gu, Daejeon 34133, KoreaSatellite Application Division, Korea Aerospace Research Institute, 115 Gwahangno Yuseong-gu, Daejeon 34133, KoreaNew and Renewable Energy Resource & Policy Center, Korea Institute of Energy Research, 152 Gajeong-ro Yuseong-gu, Daejeon 34129, KoreaEnvironmental Satellite Center, National Institute of Environmental Research, 42, Hwangyeong-ro, Seogu, Incheon 22689, KoreaAlthough data-driven methods including deep neural network (DNN) were introduced, there was not enough assessment about spatial characteristics when using limited ground observation as reference. This work aimed to interpret the feasibility of several machine learning approaches to assess the spatial distribution of solar radiation on Earth based on the Communication, Ocean, and Meteorological Satellite (COMS) Meteorological Imager (MI) geostationary satellite. Four data-driven models were selected (artificial neural network (ANN), random forest (RF), support vector regression (SVR), and DNN), to compare their accuracy and spatial estimating performance. Moreover, we used a physical model to probe the ability of data-driven methods, implementing hold-out and k-fold cross-validation approaches based on pyranometers located in South Korea. The results of analysis showed the RF had the highest accuracy in predicting performance, although the difference between RF and the second-best technique (DNN) was insignificant. Temporal variations in root mean square error (RMSE) were dependent on the number of data samples, while the physical model showed relatively less sensitivity. Nevertheless, DNN and RF showed less variability in RMSE than the others. To examine spatial estimation performance, we mapped solar radiation over South Korea for each model. The data-driven models accurately simulated the observed cloud pattern spatially, whereas the physical model failed to do because of cloud mask errors. These exhibited different spatial retrieval performances according to their own training approaches. Overall analysis showed that deeper layers of networks approaches (RF and DNN), could best simulate the challenging spatial pattern of thin clouds when using satellite multispectral data.https://www.mdpi.com/1424-8220/19/9/2082solar radiationartificial neural networkrandom forestsupport vector machinedeep neural networkCOMS MI
collection DOAJ
language English
format Article
sources DOAJ
author Jong-Min Yeom
Seonyoung Park
Taebyeong Chae
Jin-Young Kim
Chang Suk Lee
spellingShingle Jong-Min Yeom
Seonyoung Park
Taebyeong Chae
Jin-Young Kim
Chang Suk Lee
Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
Sensors
solar radiation
artificial neural network
random forest
support vector machine
deep neural network
COMS MI
author_facet Jong-Min Yeom
Seonyoung Park
Taebyeong Chae
Jin-Young Kim
Chang Suk Lee
author_sort Jong-Min Yeom
title Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
title_short Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
title_full Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
title_fullStr Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
title_full_unstemmed Spatial Assessment of Solar Radiation by Machine Learning and Deep Neural Network Models Using Data Provided by the COMS MI Geostationary Satellite: A Case Study in South Korea
title_sort spatial assessment of solar radiation by machine learning and deep neural network models using data provided by the coms mi geostationary satellite: a case study in south korea
publisher MDPI AG
series Sensors
issn 1424-8220
publishDate 2019-05-01
description Although data-driven methods including deep neural network (DNN) were introduced, there was not enough assessment about spatial characteristics when using limited ground observation as reference. This work aimed to interpret the feasibility of several machine learning approaches to assess the spatial distribution of solar radiation on Earth based on the Communication, Ocean, and Meteorological Satellite (COMS) Meteorological Imager (MI) geostationary satellite. Four data-driven models were selected (artificial neural network (ANN), random forest (RF), support vector regression (SVR), and DNN), to compare their accuracy and spatial estimating performance. Moreover, we used a physical model to probe the ability of data-driven methods, implementing hold-out and k-fold cross-validation approaches based on pyranometers located in South Korea. The results of analysis showed the RF had the highest accuracy in predicting performance, although the difference between RF and the second-best technique (DNN) was insignificant. Temporal variations in root mean square error (RMSE) were dependent on the number of data samples, while the physical model showed relatively less sensitivity. Nevertheless, DNN and RF showed less variability in RMSE than the others. To examine spatial estimation performance, we mapped solar radiation over South Korea for each model. The data-driven models accurately simulated the observed cloud pattern spatially, whereas the physical model failed to do because of cloud mask errors. These exhibited different spatial retrieval performances according to their own training approaches. Overall analysis showed that deeper layers of networks approaches (RF and DNN), could best simulate the challenging spatial pattern of thin clouds when using satellite multispectral data.
topic solar radiation
artificial neural network
random forest
support vector machine
deep neural network
COMS MI
url https://www.mdpi.com/1424-8220/19/9/2082
work_keys_str_mv AT jongminyeom spatialassessmentofsolarradiationbymachinelearninganddeepneuralnetworkmodelsusingdataprovidedbythecomsmigeostationarysatelliteacasestudyinsouthkorea
AT seonyoungpark spatialassessmentofsolarradiationbymachinelearninganddeepneuralnetworkmodelsusingdataprovidedbythecomsmigeostationarysatelliteacasestudyinsouthkorea
AT taebyeongchae spatialassessmentofsolarradiationbymachinelearninganddeepneuralnetworkmodelsusingdataprovidedbythecomsmigeostationarysatelliteacasestudyinsouthkorea
AT jinyoungkim spatialassessmentofsolarradiationbymachinelearninganddeepneuralnetworkmodelsusingdataprovidedbythecomsmigeostationarysatelliteacasestudyinsouthkorea
AT changsuklee spatialassessmentofsolarradiationbymachinelearninganddeepneuralnetworkmodelsusingdataprovidedbythecomsmigeostationarysatelliteacasestudyinsouthkorea
_version_ 1725073742260862976

Similar Items