English

F8Net: Fixed-Point 8-bit Only Multiplication for Network Quantization

Computer Vision and Pattern Recognition 2022-02-11 v1 Artificial Intelligence Hardware Architecture Machine Learning Neural and Evolutionary Computing

Abstract

Neural network quantization is a promising compression technique to reduce memory footprint and save energy consumption, potentially leading to real-time inference. However, there is a performance gap between quantized and full-precision models. To reduce it, existing quantization approaches require high-precision INT32 or full-precision multiplication during inference for scaling or dequantization. This introduces a noticeable cost in terms of memory, speed, and required energy. To tackle these issues, we present F8Net, a novel quantization framework consisting of only fixed-point 8-bit multiplication. To derive our method, we first discuss the advantages of fixed-point multiplication with different formats of fixed-point numbers and study the statistical behavior of the associated fixed-point numbers. Second, based on the statistical and algorithmic analysis, we apply different fixed-point formats for weights and activations of different layers. We introduce a novel algorithm to automatically determine the right format for each layer during training. Third, we analyze a previous quantization algorithm -- parameterized clipping activation (PACT) -- and reformulate it using fixed-point arithmetic. Finally, we unify the recently proposed method for quantization fine-tuning and our fixed-point approach to show the potential of our method. We verify F8Net on ImageNet for MobileNet V1/V2 and ResNet18/50. Our approach achieves comparable and better performance, when compared not only to existing quantization techniques with INT32 multiplication or floating-point arithmetic, but also to the full-precision counterparts, achieving state-of-the-art performance.

Keywords

Cite

@article{arxiv.2202.05239,
  title  = {F8Net: Fixed-Point 8-bit Only Multiplication for Network Quantization},
  author = {Qing Jin and Jian Ren and Richard Zhuang and Sumant Hanumante and Zhengang Li and Zhiyu Chen and Yanzhi Wang and Kaiyuan Yang and Sergey Tulyakov},
  journal= {arXiv preprint arXiv:2202.05239},
  year   = {2022}
}

Comments

ICLR 2022 (Oral)

R2 v1 2026-06-24T09:30:50.207Z