Using deep recurrent neural network for direct beam solar irradiance cloud screening

Maosi Chen; John M. Davis; Chaoshun Liu; Zhibin Sun; Melina Maria Zempila; Wei Gao

doi:10.1117/12.2273364

Using deep recurrent neural network for direct beam solar irradiance cloud screening

Maosi Chen
, John M. Davis
, Chaoshun Liu
, Zhibin Sun
, Melina Maria Zempila
, Wei Gao

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

2 Scopus citations

Abstract

Cloud screening is an essential procedure for in-situ calibration and atmospheric properties retrieval on (UV-)MultiFilter Rotating Shadowband Radiometer [(UV-)MFRSR]. Previous study has explored a cloud screening algorithm for direct-beam (UV-)MFRSR voltage measurements based on the stability assumption on a long time period (typically a half day or a whole day). To design such an algorithm requires in-depth understanding of radiative transfer and delicate data manipulation. Recent rapid developments on deep neural network and computation hardware have opened a window for modeling complicated End-to-End systems with a standardized strategy. In this study, a multi-layer dynamic bidirectional recurrent neural network is built for determining the cloudiness on each time point with a 17-year training dataset and tested with another 1-year dataset. The dataset is the daily 3-minute cosine corrected voltages, airmasses, and the corresponding cloud/clear-sky labels at two stations of the USDA UV-B Monitoring and Research Program. The results show that the optimized neural network model (3-layer, 250 hidden units, and 80 epochs of training) has an overall test accuracy of 97.87% (97.56% for the Oklahoma site and 98.16% for the Hawaii site). Generally, the neural network model grasps the key concept of the original model to use data in the entire day rather than short nearby measurements to perform cloud screening. A scrutiny of the logits layer suggests that the neural network model automatically learns a way to calculate a quantity similar to total optical depth and finds an appropriate threshold for cloud screening.

Original language	English
Title of host publication	Remote Sensing and Modeling of Ecosystems for Sustainability XIV
Editors	Jinnian Wang, Wei Gao, Ni-Bin Chang
Publisher	SPIE
ISBN (Electronic)	9781510612679
DOIs	https://doi.org/10.1117/12.2273364
State	Published - 2017
Externally published	Yes
Event	Remote Sensing and Modeling of Ecosystems for Sustainability XIV 2017 - San Diego, United States Duration: 9 Aug 2017 → …

Publication series

Name	Proceedings of SPIE - The International Society for Optical Engineering
Volume	10405
ISSN (Print)	0277-786X
ISSN (Electronic)	1996-756X

Conference

Conference	Remote Sensing and Modeling of Ecosystems for Sustainability XIV 2017
Country/Territory	United States
City	San Diego
Period	9/08/17 → …

Keywords

(UV-)MFRSR
Cloud Screening
Long Short-Term Memory (LSTM)
TensorFlow
Total Optical Depth (TOD)
direct normal cosine corrected voltage
interpretation of LSTM outputs
stacked dynamic bidirectional LSTM

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10.1117/12.2273364

Cite this

Chen, M., Davis, J. M., Liu, C., Sun, Z., Zempila, M. M., & Gao, W. (2017). Using deep recurrent neural network for direct beam solar irradiance cloud screening. In J. Wang, W. Gao, & N.-B. Chang (Eds.), Remote Sensing and Modeling of Ecosystems for Sustainability XIV Article 1040503 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 10405). SPIE. https://doi.org/10.1117/12.2273364

@inproceedings{ebdc67cd498a48719b2a01792971f83a,

title = "Using deep recurrent neural network for direct beam solar irradiance cloud screening",

abstract = "Cloud screening is an essential procedure for in-situ calibration and atmospheric properties retrieval on (UV-)MultiFilter Rotating Shadowband Radiometer [(UV-)MFRSR]. Previous study has explored a cloud screening algorithm for direct-beam (UV-)MFRSR voltage measurements based on the stability assumption on a long time period (typically a half day or a whole day). To design such an algorithm requires in-depth understanding of radiative transfer and delicate data manipulation. Recent rapid developments on deep neural network and computation hardware have opened a window for modeling complicated End-to-End systems with a standardized strategy. In this study, a multi-layer dynamic bidirectional recurrent neural network is built for determining the cloudiness on each time point with a 17-year training dataset and tested with another 1-year dataset. The dataset is the daily 3-minute cosine corrected voltages, airmasses, and the corresponding cloud/clear-sky labels at two stations of the USDA UV-B Monitoring and Research Program. The results show that the optimized neural network model (3-layer, 250 hidden units, and 80 epochs of training) has an overall test accuracy of 97.87\% (97.56\% for the Oklahoma site and 98.16\% for the Hawaii site). Generally, the neural network model grasps the key concept of the original model to use data in the entire day rather than short nearby measurements to perform cloud screening. A scrutiny of the logits layer suggests that the neural network model automatically learns a way to calculate a quantity similar to total optical depth and finds an appropriate threshold for cloud screening.",

keywords = "(UV-)MFRSR, Cloud Screening, Long Short-Term Memory (LSTM), TensorFlow, Total Optical Depth (TOD), direct normal cosine corrected voltage, interpretation of LSTM outputs, stacked dynamic bidirectional LSTM",

author = "Maosi Chen and Davis, \{John M.\} and Chaoshun Liu and Zhibin Sun and Zempila, \{Melina Maria\} and Wei Gao",

note = "Publisher Copyright: {\textcopyright} 2017 SPIE.; Remote Sensing and Modeling of Ecosystems for Sustainability XIV 2017 ; Conference date: 09-08-2017",

year = "2017",

doi = "10.1117/12.2273364",

language = "英语",

series = "Proceedings of SPIE - The International Society for Optical Engineering",

publisher = "SPIE",

editor = "Jinnian Wang and Wei Gao and Ni-Bin Chang",

booktitle = "Remote Sensing and Modeling of Ecosystems for Sustainability XIV",

address = "美国",

}

Chen, M, Davis, JM, Liu, C, Sun, Z, Zempila, MM & Gao, W 2017, Using deep recurrent neural network for direct beam solar irradiance cloud screening. in J Wang, W Gao & N-B Chang (eds), Remote Sensing and Modeling of Ecosystems for Sustainability XIV., 1040503, Proceedings of SPIE - The International Society for Optical Engineering, vol. 10405, SPIE, Remote Sensing and Modeling of Ecosystems for Sustainability XIV 2017, San Diego, United States, 9/08/17. https://doi.org/10.1117/12.2273364

Using deep recurrent neural network for direct beam solar irradiance cloud screening. / Chen, Maosi; Davis, John M.; Liu, Chaoshun et al.
Remote Sensing and Modeling of Ecosystems for Sustainability XIV. ed. / Jinnian Wang; Wei Gao; Ni-Bin Chang. SPIE, 2017. 1040503 (Proceedings of SPIE - The International Society for Optical Engineering; Vol. 10405).

Research output: Chapter in Book/Report/Conference proceeding › Conference contribution › peer-review

TY - GEN

T1 - Using deep recurrent neural network for direct beam solar irradiance cloud screening

AU - Chen, Maosi

AU - Davis, John M.

AU - Liu, Chaoshun

AU - Sun, Zhibin

AU - Zempila, Melina Maria

AU - Gao, Wei

PY - 2017

Y1 - 2017

N2 - Cloud screening is an essential procedure for in-situ calibration and atmospheric properties retrieval on (UV-)MultiFilter Rotating Shadowband Radiometer [(UV-)MFRSR]. Previous study has explored a cloud screening algorithm for direct-beam (UV-)MFRSR voltage measurements based on the stability assumption on a long time period (typically a half day or a whole day). To design such an algorithm requires in-depth understanding of radiative transfer and delicate data manipulation. Recent rapid developments on deep neural network and computation hardware have opened a window for modeling complicated End-to-End systems with a standardized strategy. In this study, a multi-layer dynamic bidirectional recurrent neural network is built for determining the cloudiness on each time point with a 17-year training dataset and tested with another 1-year dataset. The dataset is the daily 3-minute cosine corrected voltages, airmasses, and the corresponding cloud/clear-sky labels at two stations of the USDA UV-B Monitoring and Research Program. The results show that the optimized neural network model (3-layer, 250 hidden units, and 80 epochs of training) has an overall test accuracy of 97.87% (97.56% for the Oklahoma site and 98.16% for the Hawaii site). Generally, the neural network model grasps the key concept of the original model to use data in the entire day rather than short nearby measurements to perform cloud screening. A scrutiny of the logits layer suggests that the neural network model automatically learns a way to calculate a quantity similar to total optical depth and finds an appropriate threshold for cloud screening.

AB - Cloud screening is an essential procedure for in-situ calibration and atmospheric properties retrieval on (UV-)MultiFilter Rotating Shadowband Radiometer [(UV-)MFRSR]. Previous study has explored a cloud screening algorithm for direct-beam (UV-)MFRSR voltage measurements based on the stability assumption on a long time period (typically a half day or a whole day). To design such an algorithm requires in-depth understanding of radiative transfer and delicate data manipulation. Recent rapid developments on deep neural network and computation hardware have opened a window for modeling complicated End-to-End systems with a standardized strategy. In this study, a multi-layer dynamic bidirectional recurrent neural network is built for determining the cloudiness on each time point with a 17-year training dataset and tested with another 1-year dataset. The dataset is the daily 3-minute cosine corrected voltages, airmasses, and the corresponding cloud/clear-sky labels at two stations of the USDA UV-B Monitoring and Research Program. The results show that the optimized neural network model (3-layer, 250 hidden units, and 80 epochs of training) has an overall test accuracy of 97.87% (97.56% for the Oklahoma site and 98.16% for the Hawaii site). Generally, the neural network model grasps the key concept of the original model to use data in the entire day rather than short nearby measurements to perform cloud screening. A scrutiny of the logits layer suggests that the neural network model automatically learns a way to calculate a quantity similar to total optical depth and finds an appropriate threshold for cloud screening.

KW - (UV-)MFRSR

KW - Cloud Screening

KW - Long Short-Term Memory (LSTM)

KW - TensorFlow

KW - Total Optical Depth (TOD)

KW - direct normal cosine corrected voltage

KW - interpretation of LSTM outputs

KW - stacked dynamic bidirectional LSTM

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DO - 10.1117/12.2273364

M3 - 会议稿件

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T3 - Proceedings of SPIE - The International Society for Optical Engineering

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A2 - Wang, Jinnian

A2 - Gao, Wei

A2 - Chang, Ni-Bin

PB - SPIE

T2 - Remote Sensing and Modeling of Ecosystems for Sustainability XIV 2017

Y2 - 9 August 2017

ER -

Using deep recurrent neural network for direct beam solar irradiance cloud screening

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