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Journals & Magazines >IEEE Transactions on Power Sy... >Volume: 33 Issue: 3

Model-Free Renewable Scenario Generation Using Generative Adversarial Networks

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Yize Chen; Yishen Wang; Daniel Kirschen; Baosen Zhang
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Abstract:

Scenario generation is an important step in the operation and planning of power systems with high renewable penetrations. In this work, we proposed a data-driven approach...Show More

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Abstract:

Scenario generation is an important step in the operation and planning of power systems with high renewable penetrations. In this work, we proposed a data-driven approach for scenario generation using generative adversarial networks, which is based on two interconnected deep neural networks. Compared with existing methods based on probabilistic models that are often hard to scale or sample from, our method is data-driven, and captures renewable energy production patterns in both temporal and spatial dimensions for a large number of correlated resources. For validation, we use wind and solar times-series data from NREL integration data sets. We demonstrate that the proposed method is able to generate realistic wind and photovoltaic power profiles with full diversity of behaviors. We also illustrate how to generate scenarios based on different conditions of interest by using labeled data during training. For example, scenarios can be conditioned on weather events (e.g., high wind day, intense ramp events, or large forecasts errors) or time of the year (e.g., solar generation for a day in July). Because of the feedforward nature of the neural networks, scenarios can be generated extremely efficiently without sophisticated sampling techniques.
Published in: IEEE Transactions on Power Systems ( Volume: 33, Issue: 3, May 2018)
Page(s): 3265 - 3275
Date of Publication: 17 January 2018

ISSN Information:

DOI: 10.1109/TPWRS.2018.2794541

Funding Agency:

References is not available for this document.
Contents

I. Introduction

High levels of renewables penetration pose challenges in the operation, scheduling, and planning of power systems. Since renewables are intermittent and stochastic, accurately modeling the uncertainties in them is key to overcoming these challenges [1], [2]. One widely used approach to capture the uncertainties in renewable resources is by using a set of time-series scenarios [3]. By using a set of possible power generation scenarios, renewables producers and system operators are able to make decisions that take uncertainties into account, such as stochastic economic dispatch/unit commitment, optimal operation of wind and storage systems, and trading strategies (e.g., see [4]–[7] and the references within).

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