Analysis of robust optimization for decentralized microgrid energy management under uncertainty
Authored by Elizaveta Kuznetsova, Yan-Fu Li, Carlos Ruiz, Enrico Zio
Date Published: 2015
DOI: 10.1016/j.ijepes.2014.07.064
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Abstract
The present paper provides an extended analysis of a microgrid energy
management framework based on Robust Optimization (RO). Uncertainties in
wind power generation and energy consumption are described in the form
of Prediction Intervals (Pis), estimated by a Non-dominated Sorting
Genetic Algorithm (NSGA-II) - trained Neural Network (NN). The framework
is tested and exemplified in a microgrid formed by a middle-size train
station (TS) with integrated photovoltaic power production system (PV), an urban wind power plant (WPP) and a surrounding residential district
(D). The system is described by Agent-Based Modelling (ABM): each
stakeholder is modeled as an individual agent, which aims at a specific
goal, either of decreasing its expenses from power purchasing or
increasing its revenues from power selling. The aim of this paper is to
identify which is the uncertainty level associated to the ``extreme{''}
conditions upon which robust management decisions perform better than a
microgrid management based on expected values. This work shows how the
probability of occurrence of some specific uncertain events, e.g., failures of electrical lines and electricity demand and price peaks, highly conditions the reliability and performance indicators of the
microgrid under the two optimization approaches: (i) RO based on the PIs
of the uncertain parameters and (ii) optimization based on expected
values. (C) 2014 Elsevier Ltd. All rights reserved.
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