Peak-Aware Online Economic Dispatching for Microgrids

By employing local renewable energy sources and power generation units while connected to the central grid, microgrid can usher in great benefits in terms of cost efficiency, power reliability, and environmental awareness. Economic dispatching is a central problem in microgrid operation, which aims...

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Bibliographic Details
Published inIEEE transactions on smart grid Vol. 9; no. 1; pp. 323 - 335
Main Authors Ying Zhang, Hajiesmaili, Mohammad H., Sinan Cai, Minghua Chen, Qi Zhu
Format Journal Article
LanguageEnglish
Published IEEE 01.01.2018
Subjects
Algorithm design and analysis
Dispatching
economic dispatching
Economics
Generators
Microgrids
online algorithm
peak-aware scheduling
Pricing
Uncertainty
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Summary:By employing local renewable energy sources and power generation units while connected to the central grid, microgrid can usher in great benefits in terms of cost efficiency, power reliability, and environmental awareness. Economic dispatching is a central problem in microgrid operation, which aims at effectively scheduling various energy sources to minimize the operating cost while satisfying the electricity demand. Designing intelligent economic dispatching strategies for microgrids; however, it is drastically different from that for conventional central grids due to two unique challenges. First, the demand and renewable generation uncertainty emphasizes the need for online algorithms. Second, the widely-adopted peak-based pricing scheme brings out the need for new peak-aware strategy design. In this paper, we tackle these critical challenges and devise peak-aware online economic dispatching algorithms. We prove that our deterministic and randomized algorithms achieve the best possible competitive ratios 2 - β and e/(e - 1 + β) in the fast responding generator scenario, where β ∈ [0, 1] is the ratio between the minimum grid spot price and the local-generation price. By extensive empirical evaluations using real-world traces, we show that our online algorithms achieve near offline-optimal performance. In a representative scenario, our algorithm achieves 17.5% and 9.24% cost reduction as compared with the case without local generation units and the case using peak-oblivious algorithms, respectively.
ISSN:1949-3053
1949-3061
DOI:10.1109/TSG.2016.2551282