基于流量的分布式鲁棒优化

Chen Xu;Jonghyeok Lee;Xiuyuan Cheng;Yao Xie
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引用次数: 0

摘要

我们提出了一种计算高效的框架,称为 FlowDRO,用于解决具有 Wasserstein 不确定性集的基于流量的分布鲁棒优化(DRO)问题,同时旨在找到连续的最坏情况分布(也称为最小有利分布,LFD)并从中采样。LFD 必须是连续的,这样算法才能扩展到样本量更大的问题,并为诱导鲁棒算法实现更好的泛化能力。为了解决在计算上具有挑战性的无限维优化问题,我们利用基于流的模型和数据分布与目标分布之间的连续时间可逆传输映射,开发了一种 Wasserstein 近似梯度流类型算法。在理论上,我们建立了最优传输映射解与原始公式的等价性,并通过瓦瑟斯坦微积分和布雷尼尔定理建立了问题的对偶形式。在实践中,我们通过梯度下降法对神经网络序列进行分块渐进式训练,从而确定传输图的参数。我们展示了该方法在对抗学习、分布稳健假设检验以及数据驱动分布扰动差分隐私新机制中的应用,所提出的方法在高维真实数据上具有很强的经验性能。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Flow-Based Distributionally Robust Optimization
We present a computationally efficient framework, called FlowDRO , for solving flow-based distributionally robust optimization (DRO) problems with Wasserstein uncertainty sets while aiming to find continuous worst-case distribution (also called the Least Favorable Distribution, LFD) and sample from it. The requirement for LFD to be continuous is so that the algorithm can be scalable to problems with larger sample sizes and achieve better generalization capability for the induced robust algorithms. To tackle the computationally challenging infinitely dimensional optimization problem, we leverage flow-based models and continuous-time invertible transport maps between the data distribution and the target distribution and develop a Wasserstein proximal gradient flow type algorithm. In theory, we establish the equivalence of the solution by optimal transport map to the original formulation, as well as the dual form of the problem through Wasserstein calculus and Brenier theorem. In practice, we parameterize the transport maps by a sequence of neural networks progressively trained in blocks by gradient descent. We demonstrate its usage in adversarial learning, distributionally robust hypothesis testing, and a new mechanism for data-driven distribution perturbation differential privacy, where the proposed method gives strong empirical performance on high-dimensional real data.
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CiteScore
8.20
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