Asymmetric Certified Robustness via Feature-Convex Neural Networks
Pfrommer, Samuel, Anderson, Brendon G., Piet, Julien, Sojoudi, Somayeh
–arXiv.org Artificial Intelligence
Recent works have introduced input-convex neural networks (ICNNs) as learning models with advantageous training, inference, and generalization properties linked to their convex structure. In this paper, we propose a novel feature-convex neural network architecture as the composition of an ICNN with a Lipschitz feature map in order to achieve adversarial robustness. We consider the asymmetric binary classification setting with one "sensitive" class, and for this class we prove deterministic, closed-form, and easily-computable certified robust radii for arbitrary $\ell_p$-norms. We theoretically justify the use of these models by characterizing their decision region geometry, extending the universal approximation theorem for ICNN regression to the classification setting, and proving a lower bound on the probability that such models perfectly fit even unstructured uniformly distributed data in sufficiently high dimensions. Experiments on Malimg malware classification and subsets of MNIST, Fashion-MNIST, and CIFAR-10 datasets show that feature-convex classifiers attain state-of-the-art certified $\ell_1$-radii as well as substantial $\ell_2$- and $\ell_{\infty}$-radii while being far more computationally efficient than any competitive baseline.
arXiv.org Artificial Intelligence
Oct-10-2023
- Country:
- North America > United States
- California > Alameda County > Berkeley (0.04)
- Europe > United Kingdom
- England > Cambridgeshire > Cambridge (0.04)
- Asia > India
- North America > United States
- Genre:
- Research Report > New Finding (0.46)
- Industry:
- Information Technology > Security & Privacy (1.00)
- Technology: