English

Arbitrary Bit-width Network: A Joint Layer-Wise Quantization and Adaptive Inference Approach

Computer Vision and Pattern Recognition 2022-04-22 v1

Abstract

Conventional model quantization methods use a fixed quantization scheme to different data samples, which ignores the inherent "recognition difficulty" differences between various samples. We propose to feed different data samples with varying quantization schemes to achieve a data-dependent dynamic inference, at a fine-grained layer level. However, enabling this adaptive inference with changeable layer-wise quantization schemes is challenging because the combination of bit-widths and layers is growing exponentially, making it extremely difficult to train a single model in such a vast searching space and use it in practice. To solve this problem, we present the Arbitrary Bit-width Network (ABN), where the bit-widths of a single deep network can change at runtime for different data samples, with a layer-wise granularity. Specifically, first we build a weight-shared layer-wise quantizable "super-network" in which each layer can be allocated with multiple bit-widths and thus quantized differently on demand. The super-network provides a considerably large number of combinations of bit-widths and layers, each of which can be used during inference without retraining or storing myriad models. Second, based on the well-trained super-network, each layer's runtime bit-width selection decision is modeled as a Markov Decision Process (MDP) and solved by an adaptive inference strategy accordingly. Experiments show that the super-network can be built without accuracy degradation, and the bit-widths allocation of each layer can be adjusted to deal with various inputs on the fly. On ImageNet classification, we achieve 1.1% top1 accuracy improvement while saving 36.2% BitOps.

Keywords

Cite

@article{arxiv.2204.09992,
  title  = {Arbitrary Bit-width Network: A Joint Layer-Wise Quantization and Adaptive Inference Approach},
  author = {Chen Tang and Haoyu Zhai and Kai Ouyang and Zhi Wang and Yifei Zhu and Wenwu Zhu},
  journal= {arXiv preprint arXiv:2204.09992},
  year   = {2022}
}
R2 v1 2026-06-24T10:54:28.292Z