Modeling and Computing Two-Settlement Oligopolistic Equilibrium in a Congested Electricity Network

Modeling and Computing Two-Settlement Oligopolistic Equilibrium in a Congested Electricity Network

A model of two-settlement electricity markets is introduced, which accounts for flow congestion, demand uncertainty, system contingencies, and market power. We formulate the subgame perfect Nash equilibrium for this model as an equilibrium problem with equilibrium constraints (EPEC), in which each f...

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Veröffentlicht in:Operations research 2008-01, Vol.56 (1), p.34-47
Hauptverfasser: Yao, Jian, Adler, Ilan, Oren, Shmuel S
Format: Artikel
Sprache:eng
Schlagworte:
Algorithms
Applied sciences
Cournot equilibrium
Economic aspects
Electric utilities
Electrical engineering. Electrical power engineering
Electrical power engineering
Electricity
electricity market
Equilibrium
Equilibrium (Economics)
equilibrium problem with equilibrium constraints
Evaluation
Exact sciences and technology
Forward contracts
Game theory
linear complementarity problem
Market equilibrium
Market prices
Mathematical functions
mathematical program with equilibrium constraints
Modeling
Nash equilibrium
noncooperative games
Oligopolies
Oligopoly
Operational research and scientific management
Operational research. Management science
Power networks and lines
programming
Reorganization and restructuring
Spot market
Studies
Transmission lines
two settlements
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Beschreibung
Zusammenfassung:A model of two-settlement electricity markets is introduced, which accounts for flow congestion, demand uncertainty, system contingencies, and market power. We formulate the subgame perfect Nash equilibrium for this model as an equilibrium problem with equilibrium constraints (EPEC), in which each firm solves a mathematical program with equilibrium constraints (MPEC). The model assumes linear demand functions, quadratic generation cost functions, and a lossless DC network, resulting in equilibrium constraints as a parametric linear complementarity problem (LCP). We introduce an iterative procedure for solving this EPEC through repeated application of an MPEC algorithm. This MPEC algorithm is based on solving quadratic programming subproblems and on parametric LCP pivoting. Numerical examples demonstrate the effectiveness of the MPEC and EPEC algorithms and the tractability of the model for realistic-size power systems.
ISSN:0030-364X
1526-5463
DOI:10.1287/opre.1070.0416