We propose a stochastic first-order algorithm to learn the rationality parameters of simultaneous and non-cooperative potential games, i.e., the parameters of the agents' optimization problems. Our technique combines (i.) an active-set step that enforces that the agents play at a Nash equilibrium and (ii.) an implicit-differentiation step to update the estimates of the rationality parameters. We detail the convergence properties of our algorithm and perform numerical experiments on Cournot and congestion games, showing that our algorithm effectively finds high-quality solutions (in terms of out-of-sample loss) and scales to large datasets
We study an interactive framework that explicitly allows for non-rational behavior. We do not place ...
An instance of a combinatorial optimization problem is usually described by an objective function th...
In this thesis we study search and optimization problems from computational economics with primarily...
We propose a stochastic first-order algorithm to learn the rationality parameters of simultaneous an...
Algorithmic game theory attempts to mathematically capture behavior in strategic situations, in whic...
We consider multi-agent decision making, where each agent optimizes its cost function subject to con...
In this thesis, we explore the use of policy approximation for reducing the computational cost of le...
Multi-agent reinforcement learning (MARL) has become effective in tackling discrete cooperative game...
AbstractMotivated by the increasing interest of the Computer Science community in the study and unde...
With the recent advances in solving large, zero-sum extensive form games, there is a growing interes...
We study an interactive framework that explicitly allows for nonrational behavior. We do not place a...
AbstractWe introduce efficient learning equilibrium (ELE), a normative approach to learning in non-c...
This paper shows the computational benefits of a game theoretic approach to optimization of high dim...
The theory of Reinforcement Learning provides learning algorithms that are guaranteed to converge to...
Optimizing strategic decisions (a.k.a. computing equilibrium) is key to the success of many non-coop...
We study an interactive framework that explicitly allows for non-rational behavior. We do not place ...
An instance of a combinatorial optimization problem is usually described by an objective function th...
In this thesis we study search and optimization problems from computational economics with primarily...
We propose a stochastic first-order algorithm to learn the rationality parameters of simultaneous an...
Algorithmic game theory attempts to mathematically capture behavior in strategic situations, in whic...
We consider multi-agent decision making, where each agent optimizes its cost function subject to con...
In this thesis, we explore the use of policy approximation for reducing the computational cost of le...
Multi-agent reinforcement learning (MARL) has become effective in tackling discrete cooperative game...
AbstractMotivated by the increasing interest of the Computer Science community in the study and unde...
With the recent advances in solving large, zero-sum extensive form games, there is a growing interes...
We study an interactive framework that explicitly allows for nonrational behavior. We do not place a...
AbstractWe introduce efficient learning equilibrium (ELE), a normative approach to learning in non-c...
This paper shows the computational benefits of a game theoretic approach to optimization of high dim...
The theory of Reinforcement Learning provides learning algorithms that are guaranteed to converge to...
Optimizing strategic decisions (a.k.a. computing equilibrium) is key to the success of many non-coop...
We study an interactive framework that explicitly allows for non-rational behavior. We do not place ...
An instance of a combinatorial optimization problem is usually described by an objective function th...
In this thesis we study search and optimization problems from computational economics with primarily...