We consider potential games with mixed-integer variables, for which we propose two distributed, proximal-like equilibrium seeking algorithms. Specifically, we focus on two scenarios: i) the underlying game is generalized ordinal and the agents update through iterations by choosing an exact optimal strategy; ii) the game admits an exact potential and the agents adopt approximated optimal responses. By exploiting the properties of integer-compatible regularization functions used as penalty terms, we show that both algorithms converge to either an exact or an $\epsilon$-approximate equilibrium. We corroborate our findings on a numerical instance of a Cournot oligopoly model
We develop an efficient algorithm for computing pure strategy Nash equilibria that satisfy various c...
An instance of a combinatorial optimization problem is usually described by an objective function th...
Finding a Nash equilibrium of a game and in particular a bimatrix game is one of the most central pr...
We consider potential games with mixed-integer variables, for which we propose two distributed, prox...
We consider the problem of computing a mixed-strategy generalized Nash equilibrium (MS-GNE) for a cl...
We consider generalized potential games, that constitute a fundamental subclass of generalized Nash ...
We present, to our knowledge, the first mixed integer program (MIP) formulations for finding Nash equi...
We present, to our knowledge, the first mixed integer pro-gram (MIP) formulations for finding Nash e...
We address the Nash equilibrium problem in a partial-decision information scenario, where each agent...
We address the generalized Nash equilibrium seeking problem for a population of noncooperative agent...
Designing efficient algorithms to compute Nash equilibria poses considerable challenges in Algorithm...
In game theory, Nash equilibria, the states where no players can gain by unilaterally changing their...
We consider Cournot oligopoly models in which some variables represent indivisible quantities. These...
We present a new, distributed method to compute approximate Nash equilibria in bimatrix games. In co...
We develop an efficient algorithm for computing pure strategy Nash equilibria that satisfy various c...
An instance of a combinatorial optimization problem is usually described by an objective function th...
Finding a Nash equilibrium of a game and in particular a bimatrix game is one of the most central pr...
We consider potential games with mixed-integer variables, for which we propose two distributed, prox...
We consider the problem of computing a mixed-strategy generalized Nash equilibrium (MS-GNE) for a cl...
We consider generalized potential games, that constitute a fundamental subclass of generalized Nash ...
We present, to our knowledge, the first mixed integer program (MIP) formulations for finding Nash equi...
We present, to our knowledge, the first mixed integer pro-gram (MIP) formulations for finding Nash e...
We address the Nash equilibrium problem in a partial-decision information scenario, where each agent...
We address the generalized Nash equilibrium seeking problem for a population of noncooperative agent...
Designing efficient algorithms to compute Nash equilibria poses considerable challenges in Algorithm...
In game theory, Nash equilibria, the states where no players can gain by unilaterally changing their...
We consider Cournot oligopoly models in which some variables represent indivisible quantities. These...
We present a new, distributed method to compute approximate Nash equilibria in bimatrix games. In co...
We develop an efficient algorithm for computing pure strategy Nash equilibria that satisfy various c...
An instance of a combinatorial optimization problem is usually described by an objective function th...
Finding a Nash equilibrium of a game and in particular a bimatrix game is one of the most central pr...