Your search keyword '"Matti Pietikainen"' showing total 3 results

1. Uncertainty-Guided Semi-Supervised Few-Shot Class-Incremental Learning With Knowledge Distillation

Author

Yawen Cui, Wanxia Deng, Xin Xu, Zhen Liu, Zhong Liu, Matti Pietikainen, and Li Liu

Subjects

semi-supervised learning, knowledge distillation, Few-shot learning, uncertainty estimation, class-incremental learning, Signal Processing, Media Technology, deep learning, object classification, Electrical and Electronic Engineering, computer vision, Computer Science Applications

Abstract

Class-Incremental Learning (CIL) aims at incrementally learning novel classes without forgetting old ones. This capability becomes more challenging when novel tasks contain one or a few labeled training samples, which leads to a more practical learning scenario, i.e., Few-Shot Class-Incremental Learning (FSCIL). The dilemma on FSCIL lies in serious overfitting and exacerbated catastrophic forgetting caused by the limited training data from novel classes. In this paper, excited by the easy accessibility of unlabeled data, we conduct a pioneering work and focus on a Semi-Supervised Few-Shot Class-Incremental Learning (Semi-FSCIL) problem, which requires the model incrementally to learn new classes from extremely limited labeled samples and a large number of unlabeled samples. To address this problem, a simple but efficient framework is first constructed based on the knowledge distillation technique to alleviate catastrophic forgetting. To efficiently mitigate the overfitting problem on novel categories with unlabeled data, uncertainty-guided semi-supervised learning is incorporated into this framework to select unlabeled samples into incremental learning sessions considering the model uncertainty. This process provides extra reliable supervision for the distillation process and contributes to better formulating the class means. Our extensive experiments on CIFAR100, miniImageNet and CUB200 datasets demonstrate the promising performance of our proposed method, and define baselines in this new research direction.

Published

2022

2. Importance-Aware Information Bottleneck Learning Paradigm for Lip Reading

Author

Changchong Sheng, Li Liu, Wanxia Deng, Liang Bai, Zhong Liu, Songyang Lao, Gangyao Kuang, and Matti Pietikainen

Subjects

Signal Processing, Media Technology, Electrical and Electronic Engineering, Computer Science Applications

Published

2022

3. Adaptive semantic-spatio-temporal graph convolutional network for lip reading

Author

Changchong Sheng, Xinzhong Zhu, Huiying Xu, Matti Pietikainen, and Li Liu

Subjects

Signal Processing, semantic-spatio-temporal, 0202 electrical engineering, electronic engineering, information engineering, Media Technology, two-stream, 020201 artificial intelligence & image processing, 02 engineering and technology, Electrical and Electronic Engineering, adaptive graph convolution network, lip reading, Computer Science Applications

Abstract

The goal of this work is to recognize words, phrases, and sentences being spoken by a talking face without given the audio. Current deep learning approaches for lip reading focus on exploring the appearance and optical flow information of videos. However, these methods do not fully exploit the characteristics of lip motion. In addition to appearance and optical flow, the mouth contour deformation usually conveys significant information that is complementary to others. However, the modeling of dynamic mouth contour has received little attention than that of appearance and optical flow. In this work, we propose a novel model of dynamic mouth contours called Adaptive Semantic-Spatio-Temporal Graph Convolution Network (ASST-GCN), to go beyond previous methods by automatically learning both the spatial and temporal information from videos. To combine the complementary information from appearance and mouth contour, a two-stream visual front-end network is proposed. Experimental results demonstrate that the proposed method significantly outperforms the state-of-the-art lip reading methods on several large-scale lip reading benchmarks.

Published

2022