A Concise Overview on Solar Resource Assessment and Forecasting

被引：1

作者：

Dazhi YANG ^{[1
]}

Wenting WANG ^{[1
]}

Xiangao XIA ^{[2
]}

机构：

[1] School of Electrical Engineering and Automation, Harbin Institute of Technology

[2] Key Laboratory for Middle Atmosphere and Global Environment Observation (LAGEO),Institute of Atmospheric Physics, Chinese Academy of Sciences

来源：

AdvancesinAtmosphericSciences | 2022年 / 39卷 / 08期

关键词：

D O I：

暂无

中图分类号：

TK51 [太阳能技术];

学科分类号：

080703 ;

摘要：

China's recently announced directive on tackling climate change, namely, to reach carbon peak by 2030 and to achieve carbon neutrality by 2060, has led to an unprecedented nationwide response among the academia and industry. Under such a directive, a rapid increase in the grid penetration rate of solar in the near future can be fully anticipated. Although solar radiation is an atmospheric process, its utilization, as to produce electricity, has hitherto been handled by engineers. In that,it is thought important to bridge the two fields, atmospheric sciences and solar engineering, for the common good of carbon neutrality. In this überreview, all major aspects pertaining to solar resource assessment and forecasting are discussed in brief. Given the size of the topic at hand, instead of presenting technical details, which would be overly lengthy and repetitive, the overarching goal of this review is to comprehensively compile a catalog of some recent, and some not so recent, review papers, so that the interested readers can explore the details on their own.

引用

页码：1239 / 1251

页数：13

共 44 条

[1]

Probabilistic post-processing of gridded atmospheric variables and its application to site adaptation of shortwave solar radiation[J] . Yang Dazhi,Gueymard Christian A..Solar Energy . 2021

[2]

Operational solar forecasting for grid integration: Standards, challenges, and outlook[J] . Yang Dazhi,Li Weixing,Yagli Gokhan Mert,Srinivasan Dipti.Solar Energy . 2021

[3]

Worldwide performance assessment of 95 direct and diffuse clear-sky irradiance models using principal component analysis[J] . Xixi Sun,Jamie M. Bright,Christian A. Gueymard,Xinyu Bai,Brendan Acord,Peng Wang.Renewable and Sustainable Energy Reviews . 2021

[4]

Extensive comparison of physical models for photovoltaic power forecasting[J] . Mayer Martin János,Gróf Gyula.Applied Energy . 2020 (prep)

[5]

Ensemble model output statistics for the separation of direct and diffuse components from 1-min global irradiance[J] . Dazhi Yang,Christian A. Gueymard.Solar Energy . 2020

[6]

Probabilistic solar irradiance transposition models[J] . Hao Quan,Dazhi Yang.Renewable and Sustainable Energy Reviews . 2020 (C)

[7]

Benchmarking on improvement and site-adaptation techniques for modeled solar radiation datasets[J] . Jesus Polo,Carlos Fernández-Peruchena,Vasileios Salamalikis,Luis Mazorra-Aguiar,Mathieu Turpin,Luis Martín-Pomares,Andreas Kazantzidis,Philippe Blanc,Jan Remund.Solar Energy . 2020 (C)

[8]

A review of power system planning and operational models for flexibility assessment in high solar energy penetration scenarios[J] . Michael Emmanuel,Kate Doubleday,Burcin Cakir,Marija Markovi?,Bri-Mathias Hodge.Solar Energy . 2020

[9]

Probability Forecasts and Their Combination: A Research Perspective[J] . Robert L. Winkler,Yael Grushka-Cockayne,Kenneth C. Lichtendahl,Victor Richmond R. Jose.Decision Analysis . 2019

[10]

Worldwide performance assessment of 75 global clear-sky irradiance models using Principal Component Analysis[J] . Xixi Sun,Jamie M. Bright,Christian A. Gueymard,Brendan Acord,Peng Wang,Nicholas A. Engerer.Renewable and Sustainable Energy Reviews . 2019

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