2022-05-28 更新
A Physical-World Adversarial Attack Against 3D Face Recognition
Authors:Yanjie Li, Yiquan Li, Bin Xiao
3D face recognition systems have been widely employed in intelligent terminals, among which structured light imaging is a common method to measure the 3D shape. However, this method could be easily attacked, leading to inaccurate 3D face recognition. In this paper, we propose a novel, physically-achievable attack on the fringe structured light system, named structured light attack. The attack utilizes a projector to project optical adversarial fringes on faces to generate point clouds with well-designed noises. We firstly propose a 3D transform-invariant loss function to enhance the robustness of 3D adversarial examples in the physical-world attack. Then we reverse the 3D adversarial examples to the projector’s input to place noises on phase-shift images, which models the process of structured light imaging. A real-world structured light system is constructed for the attack and several state-of-the-art 3D face recognition neural networks are tested. Experiments show that our method can attack the physical system successfully and only needs minor modifications of projected images.
PDF 10 pages, 5 figures, Submit to NeurIPS 2022
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SFace: Sigmoid-Constrained Hypersphere Loss for Robust Face Recognition
Authors:Yaoyao Zhong, Weihong Deng, Jiani Hu, Dongyue Zhao, Xian Li, Dongchao Wen
Deep face recognition has achieved great success due to large-scale training databases and rapidly developing loss functions. The existing algorithms devote to realizing an ideal idea: minimizing the intra-class distance and maximizing the inter-class distance. However, they may neglect that there are also low quality training images which should not be optimized in this strict way. Considering the imperfection of training databases, we propose that intra-class and inter-class objectives can be optimized in a moderate way to mitigate overfitting problem, and further propose a novel loss function, named sigmoid-constrained hypersphere loss (SFace). Specifically, SFace imposes intra-class and inter-class constraints on a hypersphere manifold, which are controlled by two sigmoid gradient re-scale functions respectively. The sigmoid curves precisely re-scale the intra-class and inter-class gradients so that training samples can be optimized to some degree. Therefore, SFace can make a better balance between decreasing the intra-class distances for clean examples and preventing overfitting to the label noise, and contributes more robust deep face recognition models. Extensive experiments of models trained on CASIA-WebFace, VGGFace2, and MS-Celeb-1M databases, and evaluated on several face recognition benchmarks, such as LFW, MegaFace and IJB-C databases, have demonstrated the superiority of SFace.
PDF 12 pages, 9 figures
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