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Short-Term Solar Forecasting from Al...

Nie, Yuhao,

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Short-Term Solar Forecasting from All-Sky Images Using Deep Learning /

紀錄類型:	書目-電子資源 : Monograph/item
正題名/作者:	Short-Term Solar Forecasting from All-Sky Images Using Deep Learning // Yuhao Nie.
作者:	Nie, Yuhao,
面頁冊數:	1 electronic resource (308 pages)
附註:	Source: Dissertations Abstracts International, Volume: 85-06, Section: B.
Contained By:	Dissertations Abstracts International85-06B.
標題:	Data processing. -
電子資源:	https://pqdd.sinica.edu.tw/twdaoapp/servlet/advanced?query=30726863
ISBN:	9798381019902

Short-Term Solar Forecasting from All-Sky Images Using Deep Learning /
Nie, Yuhao,

Short-Term Solar Forecasting from All-Sky Images Using Deep Learning /Yuhao Nie. - 1 electronic resource (308 pages)

Source: Dissertations Abstracts International, Volume: 85-06, Section: B.

Integration of renewable resources, such as solar photovoltaics (PV), has been recognized as a crucial component in transition to a decarbonized energy system. However, the intermittent nature of solar power has challenged the large-scale deployment of PV. This variability is partly caused by short-term and local cloud events. Ground-based all-sky images captured with high temporal and spatial resolution have shown great promise as a source of input to forecast such fluctuations. In recent years, the development of deep learning has provided powerful tools to extract information from sky images and enhanced short-term solar forecasting capabilities. Despite these advancements, several major challenges have been identified: (1) sky image data are often imbalanced due to the tendency of installing PV systems in sunny locations; (2) cloud dynamics are not well captured by end-to-end deep solar forecasting models and uncertainty of predictions are rarely quantified; and (3) high-quality standardized sky image datasets for solar forecasting method development and benchmark are limited. In this dissertation, we explore ways to address these challenges by focusing on predicting the power output of a roof-top 30 kW PV system up to 15-minute ahead using a locally collected sky image dataset.The first part of the dissertation focuses on how to make effective use of imbalanced sky image data for PV output prediction. We explore methods from two different perspectives, namely, modeling framework improvement and data re-balancing. In Chapter 3, we develops a classification-prediction framework to ameliorate PV output prediction under cloudy conditions. The proposed framework first classifies input images into different sky conditions and then the classified images are sent to tailored sky-condition-specific sub-models for PV output prediction. Under the best design, the proposed framework improves cloudy prediction performance by 6% while requires 6% fewer trainable parameters compared to the end-to-end convolutional neural network (CNN) baseline. Chapter 4 examines the efficacy of using resampling and data augmentation methods to enrich the minor cloudy data for model development. We employ three-stage greedy search to determine the optimal resampling approach, data augmentation techniques and over-sampling rate. We find that for the nowcast problem, resampling and data augmentation can effectively enhance the model performance, while for the forecast problem it nearly overlaps the baseline performance. The optimal resampling approach expands on the original dataset by over-sampling the minor cloudy data, with the best results from 4x ∼ 6x over-sampling rate.The second part of the dissertation explores how to enhance cloud dynamics modeling and quantification of prediction uncertainty. In Chapter 5, we leverage the recent advances in deep generative models to synthesize visually plausible yet diversified sky videos for probabilistic solar forecasting. We introduce a physics-constrained stochastic video prediction model named SkyGPT. By using past sky image sequences as input, SkyGPT is able to generate multiple possible future sky images with diverse cloud motion patterns. Extensive experiments demonstrate its effectiveness in capturing cloud dynamics and generating future sky images of high realism and diversity. We feed the collection of generated future sky images for 15-minute-ahead probabilistic solar forecasting and observe better PV output prediction reliability and sharpness by using the predicted sky images from SkyGPTcompared with other benchmark models.

English

ISBN: 9798381019902Subjects--Topical Terms:

680224
Data processing.

Short-Term Solar Forecasting from All-Sky Images Using Deep Learning /
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