Journal
ATMOSPHERE
Volume 12, Issue 3, Pages -Publisher
MDPI
DOI: 10.3390/atmos12030395
Keywords
cloud cover estimation; solar irradiance estimation; solar power product estimation; deep learning; machine learning; ensemble
Funding
- Argonne National Laboratory's Laboratory-Directed Research and Development program [LDRD: 2014-160-N0]
- U.S. National Science Foundation's Mid-Scale Research Infrastructure program [NSF-OAC-1935984]
- U.S. Department of Energy, Office of Science [DE-AC02-06CHI1357]
- Exelon Corporation through CRADA [T03-PH01-PT1397]
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This study explores the use of machine learning methods with sky-facing cameras to estimate solar power output by accurately segmenting cloud pixels, as well as the direct relationship between cloud cover ratio and solar irradiance. Additionally, it confirms the close relationship between solar irradiance and solar power output, showing the potential of predicting solar irradiance to estimate solar power output.
Cloud cover estimation from images taken by sky-facing cameras can be an important input for analyzing current weather conditions and estimating photovoltaic power generation. The constant change in position, shape, and density of clouds, however, makes the development of a robust computational method for cloud cover estimation challenging. Accurately determining the edge of clouds and hence the separation between clouds and clear sky is difficult and often impossible. Toward determining cloud cover for estimating photovoltaic output, we propose using machine learning methods for cloud segmentation. We compare several methods including a classical regression model, deep learning methods, and boosting methods that combine results from the other machine learning models. To train each of the machine learning models with various sky conditions, we supplemented the existing Singapore whole sky imaging segmentation database with hazy and overcast images collected by a camera-equipped Waggle sensor node. We found that the U-Net architecture, one of the deep neural networks we utilized, segmented cloud pixels most accurately. However, the accuracy of segmenting cloud pixels did not guarantee high accuracy of estimating solar irradiance. We confirmed that the cloud cover ratio is directly related to solar irradiance. Additionally, we confirmed that solar irradiance and solar power output are closely related; hence, by predicting solar irradiance, we can estimate solar power output. This study demonstrates that sky-facing cameras with machine learning methods can be used to estimate solar power output. This ground-based approach provides an inexpensive way to understand solar irradiance and estimate production from photovoltaic solar facilities.
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