Partition-based formulations for mixed-integer optimization of trained ReLU neural networks

Add code
Feb 08, 2021
Calvin Tsay, Jan Kronqvist, Alexander Thebelt, Ruth Misener
Figure 1 for Partition-based formulations for mixed-integer optimization of trained ReLU neural networks
Figure 2 for Partition-based formulations for mixed-integer optimization of trained ReLU neural networks
Figure 3 for Partition-based formulations for mixed-integer optimization of trained ReLU neural networks
Figure 4 for Partition-based formulations for mixed-integer optimization of trained ReLU neural networks

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon

This paper introduces a class of mixed-integer formulations for trained ReLU neural networks. The approach balances model size and tightness by partitioning node inputs into a number of groups and forming the convex hull over the partitions via disjunctive programming. At one extreme, one partition per input recovers the convex hull of a node, i.e., the tightest possible formulation for each node. For fewer partitions, we develop smaller relaxations that approximate the convex hull, and show that they outperform existing formulations. Specifically, we propose strategies for partitioning variables based on theoretical motivations and validate these strategies using extensive computational experiments. Furthermore, the proposed scheme complements known algorithmic approaches, e.g., optimization-based bound tightening captures dependencies within a partition.

* 10 pages  
View paper onarxiv iconopen_review iconOpenReview

Share this with someone who'll enjoy it:

Twitter IconFacebook IconLinkedin IconWhatsapp IconMessenger Icon