Yichao Wu scite author profile

Most teacher-student frameworks based on knowledge distillation (KD) depend on a strong congruent constraint on instance level. However, they usually ignore the correlation between multiple instances, which is also valuable for knowledge transfer. In this work, we propose a new framework named correlation congruence for knowledge distillation (CCKD), which transfers not only the instance-level information, but also the correlation between instances. Furthermore, a generalized kernel method based on Taylor series expansion is proposed to better capture the correlation between instances. Empirical experiments and ablation studies on image classification tasks (including CIFAR-100, ImageNet-1K) and metric learning tasks (including ReID and Face Recognition) show that the proposed CCKD substantially outperforms the original KD and achieves stateof-the-art accuracy compared with other SOTA KD-based methods. The CCKD can be easily deployed in the majority of the teacher-student framework such as KD and hintbased learning methods. Our code will be released, hoping to nourish our idea to other domains.

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Online Knowledge Distillation via Collaborative Learning

Guo

Wang

et al. 2020

247

119

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Knowledge Distillation via Route Constrained Optimization

Xiao

Peng

et al. 2019

142

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Distillation-based learning boost the performance of the miniaturized neural network based on the hypothesis that the representation of a teacher model can be used as structured and relatively weak supervision, and thus would be easily learned by a miniaturized model. However, we find that the representation of a converged heavy model is still a strong constraint for training a small student model, which leads to a high lower bound of congruence loss. In this work, inspired by [1] we consider the knowledge distillation from the perspective of curriculum learning by routing. Instead of supervising the student model with a converged teacher model, we supervised it with some anchor points selected from the route in parameter space that the teacher model passed by, as we called route constrained optimization (RCO). We experimentally demonstrate this simple operation greatly reduces the lower bound of congruence loss for knowledge distillation, hint and mimicking learning. On close-set classification tasks like CIFAR [16] and ImageNet [3], RCO improves knowledge distillation by 2.14% and 1.5% respectively. For the sake of evaluating the generalization, we also test RCO on the open-set face recognition task MegaFace. RCO achieves 84.3% accuracy on 1 vs. 1 million task with only 0.8 M parameters, which push the SOTA by a large margin.

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Improving handwritten Chinese text recognition using neural network language models and convolutional neural network shape models

Yin

Liu

2017

Pattern Recognition

159

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Yichao Wu

Correlation Congruence for Knowledge Distillation

Online Knowledge Distillation via Collaborative Learning

Knowledge Distillation via Route Constrained Optimization

Improving handwritten Chinese text recognition using neural network language models and convolutional neural network shape models

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