Beyond Local Nash Equilibria for Adversarial Networks

Frans A. Oliehoek; Rahul Savani; Jose Gallego; Elise van der Pol; Roderich Gross

Beyond Local Nash Equilibria for Adversarial Networks

Frans A. Oliehoek, Rahul Savani, Jose Gallego, Elise van der Pol, Roderich Gross

Interactive Intelligence

Research output: Chapter in Book/Conference proceedings/Edited volume › Conference contribution › Scientific › peer-review

55 Downloads (Pure)

Abstract

Save for some special cases, current training methods for Generative Adversarial Networks (GANs) are at best guaranteed to converge to a `local Nash quilibrium' (LNE). Such LNEs, however, can be arbitrarily far from an actual Nash equilibrium (NE), which implies that there are no guarantees on the quality of the found generator or clas-sier. This paper proposes to model GANs explicitly as nite games in mixed strategies, thereby ensuring that every LNE is an NE. We use the Parallel Nash Memory as a solution method, which is proven to monotonically converge to a resource-bounded Nash equilibrium. We empirically demonstrate that our method is less prone to typical GAN problems such as mode collapse and produces solutions that are less exploitable than those produced by GANs and MGANs

Original language	Undefined/Unknown
Title of host publication	Proceedings of the 27th Annual Machine Learning Conference of Belgium and the Netherlands (Benelearn)
Pages	1-15
Number of pages	15
Publication status	Published - 1 Nov 2018
Event	30th Benelux Conference on Artificial Intelligence (BNAIC 2018) - 's-Hertogenbosch, Netherlands Duration: 8 Nov 2018 → 9 Nov 2018 Conference number: 30

Conference

Conference	30th Benelux Conference on Artificial Intelligence (BNAIC 2018)
Abbreviated title	BNAIC'18
Country/Territory	Netherlands
City	's-Hertogenbosch
Period	8/11/18 → 9/11/18

Bibliographical note

Accepted author manuscript

Access to Document

Oliehoek18benelearnAccepted author manuscript, 1.27 MB

Cite this

@inproceedings{307626a079594c0f885516c9036adf65,

title = "Beyond Local Nash Equilibria for Adversarial Networks",

abstract = "Save for some special cases, current training methods for Generative Adversarial Networks (GANs) are at best guaranteed to converge to a `local Nash quilibrium' (LNE). Such LNEs, however, can be arbitrarily far from an actual Nash equilibrium (NE), which implies that there are no guarantees on the quality of the found generator or clas-sier. This paper proposes to model GANs explicitly as nite games in mixed strategies, thereby ensuring that every LNE is an NE. We use the Parallel Nash Memory as a solution method, which is proven to monotonically converge to a resource-bounded Nash equilibrium. We empirically demonstrate that our method is less prone to typical GAN problems such as mode collapse and produces solutions that are less exploitable than those produced by GANs and MGANs",

author = "Oliehoek, {Frans A.} and Rahul Savani and Jose Gallego and Pol, {Elise van der} and Roderich Gross",

note = "Accepted author manuscript; 30th Benelux Conference on Artificial Intelligence (BNAIC 2018) ; Conference date: 08-11-2018 Through 09-11-2018",

year = "2018",

month = nov,

day = "1",

language = "Undefined/Unknown",

pages = "1--15",

booktitle = "Proceedings of the 27th Annual Machine Learning Conference of Belgium and the Netherlands (Benelearn)",

}

TY - GEN

T1 - Beyond Local Nash Equilibria for Adversarial Networks

AU - Oliehoek, Frans A.

AU - Savani, Rahul

AU - Gallego, Jose

AU - Pol, Elise van der

AU - Gross, Roderich

N1 - Conference code: 30

PY - 2018/11/1

Y1 - 2018/11/1

N2 - Save for some special cases, current training methods for Generative Adversarial Networks (GANs) are at best guaranteed to converge to a `local Nash quilibrium' (LNE). Such LNEs, however, can be arbitrarily far from an actual Nash equilibrium (NE), which implies that there are no guarantees on the quality of the found generator or clas-sier. This paper proposes to model GANs explicitly as nite games in mixed strategies, thereby ensuring that every LNE is an NE. We use the Parallel Nash Memory as a solution method, which is proven to monotonically converge to a resource-bounded Nash equilibrium. We empirically demonstrate that our method is less prone to typical GAN problems such as mode collapse and produces solutions that are less exploitable than those produced by GANs and MGANs

AB - Save for some special cases, current training methods for Generative Adversarial Networks (GANs) are at best guaranteed to converge to a `local Nash quilibrium' (LNE). Such LNEs, however, can be arbitrarily far from an actual Nash equilibrium (NE), which implies that there are no guarantees on the quality of the found generator or clas-sier. This paper proposes to model GANs explicitly as nite games in mixed strategies, thereby ensuring that every LNE is an NE. We use the Parallel Nash Memory as a solution method, which is proven to monotonically converge to a resource-bounded Nash equilibrium. We empirically demonstrate that our method is less prone to typical GAN problems such as mode collapse and produces solutions that are less exploitable than those produced by GANs and MGANs

M3 - Conference contribution

SP - 1

EP - 15

BT - Proceedings of the 27th Annual Machine Learning Conference of Belgium and the Netherlands (Benelearn)

T2 - 30th Benelux Conference on Artificial Intelligence (BNAIC 2018)

Y2 - 8 November 2018 through 9 November 2018

ER -