TR2019-045
Game Theoretic Optimization via Gradient-based Nikaido-Isoda Function
-
- , "Game Theoretic Optimization via Gradient-based Nikaido-Isoda Function", International Conference on Machine Learning (ICML), Lawrence, N. and Reid, M., Eds., June 2019, pp. 5291-5300.BibTeX TR2019-045 PDF Software
- @inproceedings{Raghunathan2019jun,
- author = {Raghunathan, Arvind and Cherian, Anoop and Jha, Devesh K.},
- title = {Game Theoretic Optimization via Gradient-based Nikaido-Isoda Function},
- booktitle = {International Conference on Machine Learning (ICML)},
- year = 2019,
- editor = {Lawrence, N. and Reid, M.},
- pages = {5291--5300},
- month = jun,
- publisher = {PMLR},
- issn = {2640-3498},
- url = {https://www.merl.com/publications/TR2019-045}
- }
- , "Game Theoretic Optimization via Gradient-based Nikaido-Isoda Function", International Conference on Machine Learning (ICML), Lawrence, N. and Reid, M., Eds., June 2019, pp. 5291-5300.
-
MERL Contacts:
-
Research Areas:
Abstract:
Computing Nash equilibrium (NE) of multiplayer games has witnessed renewed interest due to recent advances in generative adversarial networks. However, computing equilibrium efficiently is challenging. To this end, we introduce the Gradient-based Nikaido-Isoda (GNI) function which serves: (i) as a merit function, vanishing only at the first-order stationary points of each player’s optimization problem, and (ii) provides error bounds to a stationary Nash point. Gradient descent is shown to converge sublinearly to a first-order stationary point of the GNI function. For the particular case of bilinear min-max games and multi-player quadratic games the GNI function is convex. Hence, the application of gradient descent in this case yields linear convergence to an NE (when one exists). In our numerical experiments we observe that the GNI formulation always converges to the first-order stationary point of each player’s optimization problem.
