DeepSplit: Scalable Verification of Deep Neural Networks via Operator Splitting

Shaoru Chen;Eric Wong;J. Zico Kolter;Mahyar Fazlyab
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引用次数: 11

Abstract

Analyzing the worst-case performance of deep neural networks against input perturbations amounts to solving a large-scale non-convex optimization problem, for which several past works have proposed convex relaxations as a promising alternative. However, even for reasonably-sized neural networks, these relaxations are not tractable, and so must be replaced by even weaker relaxations in practice. In this work, we propose a novel operator splitting method that can directly solve a convex relaxation of the problem to high accuracy, by splitting it into smaller sub-problems that often have analytical solutions. The method is modular, scales to very large problem instances, and compromises of operations that are amenable to fast parallelization with GPU acceleration. We demonstrate our method in bounding the worst-case performance of large convolutional networks in image classification and reinforcement learning settings, and in reachability analysis of neural network dynamical systems.
DeepSplit:通过算子分裂对深度神经网络进行可扩展验证
分析深度神经网络对输入扰动的最坏情况性能相当于解决一个大规模的非凸优化问题,过去的几项工作已经提出了凸松弛作为一种有前途的替代方案。然而,即使对于大小合理的神经网络,这些松弛也是不可处理的,因此在实践中必须用更弱的松弛来取代。在这项工作中,我们提出了一种新的算子分裂方法,通过将问题分裂成较小的子问题,通常具有解析解,可以直接高精度地解决问题的凸松弛。该方法是模块化的,可以扩展到非常大的问题实例,并且可以折衷操作,以适应GPU加速的快速并行化。我们在图像分类和强化学习设置中,以及在神经网络动态系统的可达性分析中,演示了我们的方法来限制大型卷积网络的最坏情况性能。
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