DL-SFA: Deeply-Learned Slow Feature Analysis for Action Recognition

• Published in: 2014 IEEE Conference on Computer Vision and Pattern Recognition pp. 2625 - 2632
• Main Authors: Sun, Lin, Jia, Kui, Chan, Tsung-Han, Fang, Yuqiang, Wang, Gang, Yan, Shuicheng
• Format: Conference Proceeding Journal Article
• Language: English
• Published: IEEE 01.06.2014
• Subjects: Abstracts; action recognition; Computer vision; Convolution; deep learning; Feature extraction; Feature recognition; Invariants; Kernel; Learning; Pattern recognition; Recognition; Representations; Sampling; slow feature analysis; Three dimensional; Three-dimensional displays; Video sequences; Visualization
• ISSN: 1063-6919; 1063-6919; 2575-7075
• DOI: 10.1109/CVPR.2014.336

Most of the previous work on video action recognition use complex hand-designed local features, such as SIFT, HOG and SURF, but these approaches are implemented sophisticatedly and difficult to be extended to other sensor modalities. Recent studies discover that there are no universally best hand-engineered features for all datasets, and learning features directly from the data may be more advantageous. One such endeavor is Slow Feature Analysis (SFA) proposed by Wiskott and Sejnowski [33]. SFA can learn the invariant and slowly varying features from input signals and has been proved to be valuable in human action recognition [34]. It is also observed that the multi-layer feature representation has succeeded remarkably in widespread machine learning applications. In this paper, we propose to combine SFA with deep learning techniques to learn hierarchical representations from the video data itself. Specifically, we use a two-layered SFA learning structure with 3D convolution and max pooling operations to scale up the method to large inputs and capture abstract and structural features from the video. Thus, the proposed method is suitable for action recognition. At the same time, sharing the same merits of deep learning, the proposed method is generic and fully automated. Our classification results on Hollywood2, KTH and UCF Sports are competitive with previously published results. To highlight some, on the KTH dataset, our recognition rate shows approximately 1% improvement in comparison to state-of-the-art methods even without supervision or dense sampling.