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Uneven Licensed Robustness through Function-Convex Neural Networks – The Berkeley Synthetic Intelligence Analysis Weblog


Uneven Licensed Robustness through Function-Convex Neural Networks

TLDR: We suggest the uneven licensed robustness drawback, which requires licensed robustness for just one class and displays real-world adversarial eventualities. This centered setting permits us to introduce feature-convex classifiers, which produce closed-form and deterministic licensed radii on the order of milliseconds.

diagram illustrating the FCNN architecture


Determine 1. Illustration of feature-convex classifiers and their certification for sensitive-class inputs. This structure composes a Lipschitz-continuous characteristic map $varphi$ with a discovered convex perform $g$. Since $g$ is convex, it’s globally underapproximated by its tangent airplane at $varphi(x)$, yielding licensed norm balls within the characteristic area. Lipschitzness of $varphi$ then yields appropriately scaled certificates within the unique enter area.

Regardless of their widespread utilization, deep studying classifiers are acutely susceptible to adversarial examples: small, human-imperceptible picture perturbations that idiot machine studying fashions into misclassifying the modified enter. This weak spot severely undermines the reliability of safety-critical processes that incorporate machine studying. Many empirical defenses in opposition to adversarial perturbations have been proposed—typically solely to be later defeated by stronger assault methods. We due to this fact give attention to certifiably strong classifiers, which give a mathematical assure that their prediction will stay fixed for an $ell_p$-norm ball round an enter.

Typical licensed robustness strategies incur a variety of drawbacks, together with nondeterminism, gradual execution, poor scaling, and certification in opposition to just one assault norm. We argue that these points could be addressed by refining the licensed robustness drawback to be extra aligned with sensible adversarial settings.

The Uneven Licensed Robustness Drawback

Present certifiably strong classifiers produce certificates for inputs belonging to any class. For a lot of real-world adversarial purposes, that is unnecessarily broad. Take into account the illustrative case of somebody composing a phishing rip-off e-mail whereas attempting to keep away from spam filters. This adversary will all the time try to idiot the spam filter into considering that their spam e-mail is benign—by no means conversely. In different phrases, the attacker is solely trying to induce false negatives from the classifier. Comparable settings embrace malware detection, faux information flagging, social media bot detection, medical insurance coverage claims filtering, monetary fraud detection, phishing web site detection, and plenty of extra.

a motivating spam-filter diagram


Determine 2. Uneven robustness in e-mail filtering. Sensible adversarial settings typically require licensed robustness for just one class.

These purposes all contain a binary classification setting with one delicate class that an adversary is trying to keep away from (e.g., the “spam e-mail” class). This motivates the issue of uneven licensed robustness, which goals to offer certifiably strong predictions for inputs within the delicate class whereas sustaining a excessive clear accuracy for all different inputs. We offer a extra formal drawback assertion in the principle textual content.

Function-convex classifiers

We suggest feature-convex neural networks to deal with the uneven robustness drawback. This structure composes a easy Lipschitz-continuous characteristic map ${varphi: mathbb{R}^d to mathbb{R}^q}$ with a discovered Enter-Convex Neural Community (ICNN) ${g: mathbb{R}^q to mathbb{R}}$ (Determine 1). ICNNs implement convexity from the enter to the output logit by composing ReLU nonlinearities with nonnegative weight matrices. Since a binary ICNN determination area consists of a convex set and its complement, we add the precomposed characteristic map $varphi$ to allow nonconvex determination areas.

Function-convex classifiers allow the quick computation of sensitive-class licensed radii for all $ell_p$-norms. Utilizing the truth that convex capabilities are globally underapproximated by any tangent airplane, we will get hold of a licensed radius within the intermediate characteristic area. This radius is then propagated to the enter area by Lipschitzness. The uneven setting right here is essential, as this structure solely produces certificates for the positive-logit class $g(varphi(x)) > 0$.

The ensuing $ell_p$-norm licensed radius system is especially elegant:

[r_p(x) = frac{ color{blue}{g(varphi(x))} } { mathrm{Lip}_p(varphi) color{red}{| nabla g(varphi(x)) | _{p,*}}}.]

The non-constant phrases are simply interpretable: the radius scales proportionally to the classifier confidence and inversely to the classifier sensitivity. We consider these certificates throughout a variety of datasets, reaching aggressive $ell_1$ certificates and comparable $ell_2$ and $ell_{infty}$ certificates—regardless of different strategies usually tailoring for a selected norm and requiring orders of magnitude extra runtime.

cifar10 cats dogs certified radii


Determine 3. Delicate class licensed radii on the CIFAR-10 cats vs canines dataset for the $ell_1$-norm. Runtimes on the best are averaged over $ell_1$, $ell_2$, and $ell_{infty}$-radii (observe the log scaling).

Our certificates maintain for any $ell_p$-norm and are closed kind and deterministic, requiring only one forwards and backwards move per enter. These are computable on the order of milliseconds and scale properly with community measurement. For comparability, present state-of-the-art strategies resembling randomized smoothing and interval certain propagation sometimes take a number of seconds to certify even small networks. Randomized smoothing strategies are additionally inherently nondeterministic, with certificates that simply maintain with excessive likelihood.

Theoretical promise

Whereas preliminary outcomes are promising, our theoretical work suggests that there’s vital untapped potential in ICNNs, even with no characteristic map. Regardless of binary ICNNs being restricted to studying convex determination areas, we show that there exists an ICNN that achieves excellent coaching accuracy on the CIFAR-10 cats-vs-dogs dataset.

Truth. There exists an input-convex classifier which achieves excellent coaching accuracy for the CIFAR-10 cats-versus-dogs dataset.

Nevertheless, our structure achieves simply $73.4%$ coaching accuracy with no characteristic map. Whereas coaching efficiency doesn’t suggest check set generalization, this end result means that ICNNs are at the least theoretically able to attaining the fashionable machine studying paradigm of overfitting to the coaching dataset. We thus pose the next open drawback for the sector.

Open drawback. Be taught an input-convex classifier which achieves excellent coaching accuracy for the CIFAR-10 cats-versus-dogs dataset.

Conclusion

We hope that the uneven robustness framework will encourage novel architectures that are certifiable on this extra centered setting. Our feature-convex classifier is one such structure and supplies quick, deterministic licensed radii for any $ell_p$-norm. We additionally pose the open drawback of overfitting the CIFAR-10 cats vs canines coaching dataset with an ICNN, which we present is theoretically potential.

This publish is predicated on the next paper:

Uneven Licensed Robustness through Function-Convex Neural Networks

Samuel Pfrommer,
Brendon G. Anderson
,
Julien Piet,
Somayeh Sojoudi,

thirty seventh Convention on Neural Info Processing Techniques (NeurIPS 2023).

Additional particulars can be found on arXiv and GitHub. If our paper conjures up your work, please take into account citing it with:

@inproceedings{
    pfrommer2023asymmetric,
    title={Uneven Licensed Robustness through Function-Convex Neural Networks},
    creator={Samuel Pfrommer and Brendon G. Anderson and Julien Piet and Somayeh Sojoudi},
    booktitle={Thirty-seventh Convention on Neural Info Processing Techniques},
    12 months={2023}
}

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