Output Range Analysis for Deep Neural Networks
September 26, 2017 ยท Declared Dead ยท ๐ arXiv.org
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Authors
Souradeep Dutta, Susmit Jha, Sriram Sanakaranarayanan, Ashish Tiwari
arXiv ID
1709.09130
Category
cs.LG: Machine Learning
Cross-listed
stat.ML
Citations
123
Venue
arXiv.org
Last Checked
4 months ago
Abstract
Deep neural networks (NN) are extensively used for machine learning tasks such as image classification, perception and control of autonomous systems. Increasingly, these deep NNs are also been deployed in high-assurance applications. Thus, there is a pressing need for developing techniques to verify neural networks to check whether certain user-expected properties are satisfied. In this paper, we study a specific verification problem of computing a guaranteed range for the output of a deep neural network given a set of inputs represented as a convex polyhedron. Range estimation is a key primitive for verifying deep NNs. We present an efficient range estimation algorithm that uses a combination of local search and linear programming problems to efficiently find the maximum and minimum values taken by the outputs of the NN over the given input set. In contrast to recently proposed "monolithic" optimization approaches, we use local gradient descent to repeatedly find and eliminate local minima of the function. The final global optimum is certified using a mixed integer programming instance. We implement our approach and compare it with Reluplex, a recently proposed solver for deep neural networks. We demonstrate the effectiveness of the proposed approach for verification of NNs used in automated control as well as those used in classification.
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