Abstract

In an attempt to speed up the solution of the unit commitment (UC) problem, both machine-learning and optimization-based methods have been proposed to lighten the full UC formulation by removing as many superfluous line-flow constraints as possible. While the elimination strategies based on machine learning are fast and typically delete more constraints, they may be over-optimistic and result in infeasible UC solutions. For their part, optimization-based methods seek to identify redundant constraints in the full UC formulation by exploring the feasibility region of an LP-relaxation. In doing so, these methods only get rid of line-flow constraints whose removal leaves the feasibility region of the original UC problem unchanged. In this paper, we propose a procedure to substantially increase the line-flow constraints that are filtered out by optimization-based methods without jeopardizing their appealing ability of preserving feasibility. Our approach is based on tightening the LP-relaxation that the optimization-based method uses with a valid inequality related to the objective function of the UC problem and hence, of an economic nature. The result is that the so strengthened optimization-based method identifies not only redundant line-flow constraints but also inactive ones, thus leading to more reduced UC formulations.

Highlights

  • IntroductionT HE unit commitment (UC) problem is fundamental in the operation of power systems

  • The unit commitment (UC) problem is typically formulated as a large-scale mixed-integer program (MIP), which belongs to the class of NP-hard problems, even for a single period [3]

  • To overcome the drawback of existing optimization-based screening approaches and reduce even further the UC problem (1), we propose to tighten the LP relaxation used in the set of problems (2) by including a valid inequality on the optimal objective function of (1)

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Summary

Introduction

T HE unit commitment (UC) problem is fundamental in the operation of power systems. It is, at the core of the tools used by Regional Transmission Operators in the US, such as ISO New England and PJM, to clear their day-ahead electricity markets [1]. The UC problem is typically formulated as a large-scale mixed-integer program (MIP), which belongs to the class of NP-hard problems, even for a single period [3]. For this reason, the development of strategies to solve this problem to optimality in a computationally efficient manner has been and is still a popular research topic

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