%0 Journal Article %1 raghu2017reinforcement %A Raghu, Maithra %A Irpan, Alex %A Andreas, Jacob %A Kleinberg, Robert %A Le, Quoc V. %A Kleinberg, Jon %D 2017 %K deep-learning game-theory %T Can Deep Reinforcement Learning Solve Erdos-Selfridge-Spencer Games? %U http://arxiv.org/abs/1711.02301 %X Deep reinforcement learning has achieved many recent successes, but our understanding of its strengths and limitations is hampered by the lack of rich environments in which we can fully characterize optimal behavior, and correspondingly diagnose individual actions against such a characterization. Here we consider a family of combinatorial games, arising from work of Erdos, Selfridge, and Spencer, and we propose their use as environments for evaluating and comparing different approaches to reinforcement learning. These games have a number of appealing features: they are challenging for current learning approaches, but they form (i) a low-dimensional, simply parametrized environment where (ii) there is a linear closed form solution for optimal behavior from any state, and (iii) the difficulty of the game can be tuned by changing environment parameters in an interpretable way. We use these Erdos-Selfridge-Spencer games not only to compare different algorithms, but test for generalization, make comparisons to supervised learning, analyse multiagent play, and even develop a self play algorithm. Code can be found at: https://github.com/rubai5/ESS_Game

@article{raghu2017reinforcement, abstract = {Deep reinforcement learning has achieved many recent successes, but our understanding of its strengths and limitations is hampered by the lack of rich environments in which we can fully characterize optimal behavior, and correspondingly diagnose individual actions against such a characterization. Here we consider a family of combinatorial games, arising from work of Erdos, Selfridge, and Spencer, and we propose their use as environments for evaluating and comparing different approaches to reinforcement learning. These games have a number of appealing features: they are challenging for current learning approaches, but they form (i) a low-dimensional, simply parametrized environment where (ii) there is a linear closed form solution for optimal behavior from any state, and (iii) the difficulty of the game can be tuned by changing environment parameters in an interpretable way. We use these Erdos-Selfridge-Spencer games not only to compare different algorithms, but test for generalization, make comparisons to supervised learning, analyse multiagent play, and even develop a self play algorithm. Code can be found at: https://github.com/rubai5/ESS_Game}, added-at = {2019-04-12T14:33:22.000+0200}, author = {Raghu, Maithra and Irpan, Alex and Andreas, Jacob and Kleinberg, Robert and Le, Quoc V. and Kleinberg, Jon}, biburl = {https://www.bibsonomy.org/bibtex/2ce0959ef47ea2064b71fd90f1a1db51d/kirk86}, description = {[1711.02301] Can Deep Reinforcement Learning Solve Erdos-Selfridge-Spencer Games?}, interhash = {73c71952ad6e77a36d562c8010e68875}, intrahash = {ce0959ef47ea2064b71fd90f1a1db51d}, keywords = {deep-learning game-theory}, note = {cite arxiv:1711.02301Comment: Accepted to ICML 2018, code opensourced at: https://github.com/rubai5/ESS_Game}, timestamp = {2019-04-12T14:33:22.000+0200}, title = {Can Deep Reinforcement Learning Solve Erdos-Selfridge-Spencer Games?}, url = {http://arxiv.org/abs/1711.02301}, year = 2017 }