Bid Cost Minimization Versus Payment Cost Minimization: A Game Theoretic Study of Electricity Auctions

Currently, most independent system operators in the U.S. run auctions by minimizing the total bid cost ["bid cost minimization" (BCM)], and then calculate payments based on market clearing prices. Under this setup, the payment cost could be significantly higher than the minimized bid cost....

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Bibliographic Details
Published in:IEEE transactions on power systems 2010-02, Vol.25 (1), p.181-194
Main Authors: Feng Zhao, Luh, P.B., Yan, J.H., Stern, G.A., Shi-Chung Chang
Format: Article
Language:English
Subjects:
Bid cost minimization (BCM)
Bids
Computational efficiency
Cost engineering
Costs
discretization
Economic models
Electric power generation
electricity auction
Electricity supply industry deregulation
Game theory
Games
hockey-stick bidding
ISO
Marketing
Markets
Mathematical models
matrix game
Minimization
Nash equilibrium
Optimization
payment cost minimization (PCM)
Phase change materials
Production
production efficiency
Reduction
strategic behavior
Strategic planning
Strategy
Studies
Testing
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Summary:Currently, most independent system operators in the U.S. run auctions by minimizing the total bid cost ["bid cost minimization" (BCM)], and then calculate payments based on market clearing prices. Under this setup, the payment cost could be significantly higher than the minimized bid cost. Recently, an alternative auction mechanism that minimizes the consumer payment cost ["payment cost minimization" (PCM)] has been discussed. Literature has shown that for the same set of bids, PCM leads to reduced consumer payments. However, market participants may bid differently under the two auctions, and therefore, the payment reduction may not be realized. This necessitates the study of strategic behaviors of participants. In this paper, suppliers' bidding strategies in a day-ahead energy market are investigated for both auctions by using a game theoretic framework with Nash equilibrium as the solution concept. To simplify the solution process, the originally continuous strategies are discretized to form matrix games. Discretization may cause the loss of equilibria and the creation of artificial solutions. To reduce these side effects, "approximate Nash equilibria" are introduced to recover lost equilibria, and additional strategy samples are evaluated to eliminate artificially created solutions. Games are then solved by examining supplier payoffs obtained from running auctions. Characteristics of auctions are exploited, leading to improved computational efficiency. Numerical testing results show that the PCM leads to significant payment reductions and relatively small increases of production costs as compared to BCM. Also, the ¿hockey-stick¿ bidding is more likely to occur under BCM. Finally, long-term impacts of PCM are discussed, and whether it would lower costs to consumers in the long run, including capacity payments, remains to be investigated.
ISSN:0885-8950
1558-0679
DOI:10.1109/TPWRS.2009.2036824