Poison Frogs Neural Networks

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Presented by

Eric Anderson, Chengzhi Wang, YiJing Zhou, Kai Zhong

Introduction

Poison Frogs! Targeted Clean-Label Poisoning Attacks on Neural Networks from NeurIPS 2018 is written by Ali Shafahi, W. Ronny Huang, Mahyar Najibi, Octavian Suciu, Christoph Studer, Tudor Dumitras, and Tom Goldstein.

Data poisoning attacks are performed by an attacker by adding examples (poisons) to a training set to manipulate the model’s behavior on a test set. The ability for deep learning models to tolerate such poisons is necessary if they are to be deployed in high stakes, security-critical situations. Targeted attacks aim to only manipulate classifier behavior with respect to a specific test instance, and clean-label attacks do not require the attacker to have control over the poison’s labeling.

This paper presents a method to create poisons to effectively make targeted, clean-label poisoning attacks on neural networks, along with techniques to boost lethality. The proposed poisoning technique achieves an 100% success rate on a pretrained InceptionV3 network and sees up to 70% success rate on end-to-end trained scaled-down AlexNet architecture when using watermarks and multiple poison instances.

Previous Work

Motivation

The previous section shows that while there are studies related to poisoning attacks on SVMs and Bayesian classifiers, poisons for deep neural networks (DNNs) have rarely been studied, with the existing few studies indicating DNNs are extremely susceptible to poison attacks (Steinhardt et al. 2017).

Furthermore, poisons studied prior to this paper can be classified into at least one of the following:

  • Focus on classical attacks that degrade model accuracy indiscriminately
  • Require test-time instances to be manually modified
  • Require the attacker to have some degree of control over the labelling of the training set
  • Only achieve acceptable success rates with high poison doses

The proposal of targeted, clean-label poisons in this paper thus opens the door to more efficient, deadly poisons that future neural networks will have to find ways to tolerate.


Model Architecture

Crafting the basic concoction assumes the attacker has no knowledge of the training data but does have knowledge of the model they intend to poison. Base instance b is chosen from the training set and test instance t is chosen from the testing set. The goal is to have the poisoned model misclassify t to class b at testing, while the poison p is discernible from b to the human data labeller.

Picture1.jpg

[Figure 1 (a) Schematic of the clean-label poisoning attack. (b) Schematic of how a successful attack might work by shifting the decision boundary.]

[math] \mathbf{p} = argmin_x||f(\mathbf{x}) - f(\mathbf{t})||_2^2 + ||\mathbf{x}-\mathbf{b}||_2^2 [/math]

ILSVRC 2014 Challenge Results

The proposed architecture was implemented through a deep network called GoogLeNet as a submission for ILSVRC14’s Classification Challenge and Detection Challenge.

The classification challenge is to classify images into one of 1000 categories in the Imagenet hierarchy. The top-5 error rate - the percentage of test examples for which the correct class is not in the top 5 predicted classes - is used for measuring accuracy. The results of the classification challenge is shown in Table 1. The final submission of GoogLeNet obtains a top-5 error of 6.67% on both the validation and testing data, ranking first among all participants, significantly outperforming top teams in previous years, and not utilizing external data.

Image: 500 pixels
Table 1: Classification performance

The ILSVRC detection challenge asks to produce bounding boxes around objects in images among 200 classes. Detected objects count as correct if they match the class of the groundtruth and their bounding boxes overlap by at least 50%. Each image may contain multiple objects (with different scales) or none. The mean average precision (mAP) is used to report performance. The results of the detection challenge is listed in Table 2. Using the Inception model as a region classifier, combining Selective Search and using an ensemble of 6 CNNs, GoogLeNet gave top detection results, almost doubling accuracy of the the 2013 top model.

Image: 600 pixels
Table 2: Detection performance

Conclusion

This article studied targeted clean-label poisoning methods. These attacks are difficult to detect because they involve non-suspicious (correctly labeled) training data, and do not degrade the performance on non-targeted examples. Poison images collide with a target image in feature space, therefore the network will be very hard to distinguish them. Multiple poison images and a watermarking trick will make the attack more powerful. While our poisoned dataset training does indeed make the network more robust to base-class adversarial examples designed to be misclassified as the target, it also has the effect of causing the unaltered target instance to be misclassified as a base. Finally the paper hopes that it can raise attention for the important issue of data reliability and provenance.

Critiques

By using nearly 5 million parameters, GoogLeNet, compared to previous architectures like VGGNet and AlexNet, reduced the number of parameters in the network by almost 92%. This enabled Inception to be used for many big data applications where a huge amount of data was needed to be processed at a reasonable cost while the computational capacity was limited. However, the Inception network is still complex and susceptible to scaling. If the network is scaled up, large parts of the computational gains can be lost immediately. Also, there was no clear description about the various factors that lead to the design decision of this inception architecture, making it harder to adapt to other applications while maintaining the same computational efficiency.

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References

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[2] Ross B. Girshick, Jeff Donahue, Trevor Darrell, and Jitendra Malik. Rich feature hierarchies for accurate object detection and semantic segmentation. In Computer Vision and Pattern Recognition, 2014. CVPR 2014. IEEE Conference on, 2014.

[3] Sanjeev Arora, Aditya Bhaskara, Rong Ge, and Tengyu Ma. Provable bounds for learning some deep representations. CoRR, abs/1310.6343, 2013.

[4] ¨Umit V. C¸ ataly¨urek, Cevdet Aykanat, and Bora Uc¸ar. On two-dimensional sparse matrix partitioning: Models, methods, and a recipe. SIAM J. Sci. Comput., 32(2):656–683, February 2010.

Footnote 1: Hebbian theory is a neuroscientific theory claiming that an increase in synaptic efficacy arises from a presynaptic cell's repeated and persistent stimulation of a postsynaptic cell. It is an attempt to explain synaptic plasticity, the adaptation of brain neurons during the learning process.

Footnote 2: For more explanation on 1 by 1 convolution refer to: https://iamaaditya.github.io/2016/03/one-by-one-convolution/