Mixed integer linear programming formulation for chance constrained mathematical programs with equilibrium constraints

Abstract

This paper gives a mixed integer linear programming (MILP) formulation for a bi-level mathematical program with equilibrium constraints (MPEC) considering chance constraints. The particular MPEC problem relates to a power producer's bidding strategy: maximize its total benefit through determining bidding price and bidding power output while considering an electricity pool's operation and guessing the rival producer's bidding price. The entire decision-making process can be described by a bi-level optimization problem. The contribution of our paper is the MILP formulation of this problem. First, the lower-level pool operation problem is replaced by Karush-Kuhn-Tucker (KKT) optimality condition, which is further converted to an MILP formulation except a bilinear item in the objective function. Secondly, duality theory is implemented to replace the bilinear item by linear items. Finally, two types of chance constraints are examined and modeled in MILP formulation. With the MILP formulation, the entire MPEC problem considering randomness in price guessing can be solved using off-shelf MIP solvers, e.g., Gurobi. An example is given to illustrate the formulation and show the case study results.