Optimal 1-Wasserstein distance for WGANs
Copyright policy )Optimal 1-Wasserstein distance for WGANs
The mathematical forces at work behind Generative Adversarial Networks raise challenging theoretical issues. Motivated by the important question of characterizing the geometrical properties of the generated distributions, we provide a thorough analysis of Wasserstein GANs (WGANs) in both the finite sample and asymptotic regimes. We study the specific case where the latent space is univariate and derive results valid regardless of the dimension of the output space. We show in particular that for a fixed sample size, the optimal WGANs are closely linked with connected paths minimizing the sum of the squared Euclidean distances between the sample points. We also highlight the fact that WGANs are able to approach (for the 1-Wasserstein distance) the target distribution as the sample size tends to infinity, at a given convergence rate and provided the family of generative Lipschitz functions grows appropriately. We derive in passing new results on optimal transport theory in the semi-discrete setting.
- Sorbonne University France
- Université de Rennes 1 France
- Mathematics Research Institute of Rennes France
- University of Rennes 2 France
- L'Institut Agro France
shortest path, FOS: Computer and information sciences, Computer Science - Machine Learning, Optimal transportation, 330, Wasserstein Generative Adversarial Networks, Learning and adaptive systems in artificial intelligence, Mathematics - Statistics Theory, Machine Learning (stat.ML), Statistics Theory (math.ST), 510, Machine Learning (cs.LG), optimal transport theory, Limit theorems in probability theory, [MATH.MATH-ST]Mathematics [math]/Statistics [math.ST], Statistics - Machine Learning, FOS: Mathematics, Wasserstein distance, [MATH.MATH-ST] Mathematics [math]/Statistics [math.ST], optimal distribution, Wasserstein generative adversarial networks (WGANs), rate of convergence
shortest path, FOS: Computer and information sciences, Computer Science - Machine Learning, Optimal transportation, 330, Wasserstein Generative Adversarial Networks, Learning and adaptive systems in artificial intelligence, Mathematics - Statistics Theory, Machine Learning (stat.ML), Statistics Theory (math.ST), 510, Machine Learning (cs.LG), optimal transport theory, Limit theorems in probability theory, [MATH.MATH-ST]Mathematics [math]/Statistics [math.ST], Statistics - Machine Learning, FOS: Mathematics, Wasserstein distance, [MATH.MATH-ST] Mathematics [math]/Statistics [math.ST], optimal distribution, Wasserstein generative adversarial networks (WGANs), rate of convergence
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