Robust Face Recognition via Sparse Representation
TLDR
This work considers the problem of automatically recognizing human faces from frontal views with varying expression and illumination, as well as occlusion and disguise, and proposes a general classification algorithm for (image-based) object recognition based on a sparse representation computed by C1-minimization.Abstract:
We consider the problem of automatically recognizing human faces from frontal views with varying expression and illumination, as well as occlusion and disguise. We cast the recognition problem as one of classifying among multiple linear regression models and argue that new theory from sparse signal representation offers the key to addressing this problem. Based on a sparse representation computed by C1-minimization, we propose a general classification algorithm for (image-based) object recognition. This new framework provides new insights into two crucial issues in face recognition: feature extraction and robustness to occlusion. For feature extraction, we show that if sparsity in the recognition problem is properly harnessed, the choice of features is no longer critical. What is critical, however, is whether the number of features is sufficiently large and whether the sparse representation is correctly computed. Unconventional features such as downsampled images and random projections perform just as well as conventional features such as eigenfaces and Laplacianfaces, as long as the dimension of the feature space surpasses certain threshold, predicted by the theory of sparse representation. This framework can handle errors due to occlusion and corruption uniformly by exploiting the fact that these errors are often sparse with respect to the standard (pixel) basis. The theory of sparse representation helps predict how much occlusion the recognition algorithm can handle and how to choose the training images to maximize robustness to occlusion. We conduct extensive experiments on publicly available databases to verify the efficacy of the proposed algorithm and corroborate the above claims.read more
Citations
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Dynamic functional connectomics signatures for characterization and differentiation of PTSD patients.
Xiang Li,Dajiang Zhu,Xi Jiang,Changfeng Jin,Xin Zhang,Xin Zhang,Lei Guo,Jing Zhang,Xiaoping Hu,Lingjiang Li,Tianming Liu +10 more
TL;DR: Based on the structural connectomes constructed from diffusion tensor imaging data, FCs are derived from resting‐state fMRI (R‐fMRI) data and are then temporally divided into quasi‐stable segments via a sliding time window approach, suggesting that dynamic functional connectomics signatures can effectively characterize and differentiate PTSD patients.
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Learning Discriminative Sparse Representations for Modeling, Source Separation, and Mapping of Hyperspectral Imagery
Alexey Castrodad,Zhengming Xing,John B. Greer,Edward H. Bosch,Lawrence Carin,Guillermo Sapiro +5 more
TL;DR: Results when the data have been significantly undersampled and then reconstructed are presented, still retaining high-performance classification, showing the potential role of compressive sensing and sparse modeling techniques in efficient acquisition/transmission missions for hyperspectral imagery.
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Human Gait Recognition Using Patch Distribution Feature and Locality-Constrained Group Sparse Representation
TL;DR: Detailed experiments on the benchmark USF HumanID database demonstrate the effectiveness of the newly proposed feature Gabor-PDF and the new classification method LGSR for human gait recognition, which achieves the best average Rank-1 and Rank-5 recognition rates on this database among all gait Recognition algorithms proposed to date.
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Towards 3D Face Recognition in the Real: A Registration-Free Approach Using Fine-Grained Matching of 3D Keypoint Descriptors
TL;DR: This paper significantly extends the SIFT-like matching framework to mesh data and proposes a novel approach using fine-grained matching of 3D keypoint descriptors, which accounts for the average reconstruction error of probe face descriptors sparsely represented by a large dictionary of gallery descriptors in identification.
Proceedings ArticleDOI
Image inpainting via sparse representation
TL;DR: A novel patch-wise image inpainting algorithm using the image signal sparse representation over a redundant dictionary, which merits in both capabilities to deal with large holes and to preserve image details while taking less risk.
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