English

Learnable Heterogeneous Convolution: Learning both topology and strength

Computer Vision and Pattern Recognition 2023-01-16 v1

Abstract

Existing convolution techniques in artificial neural networks suffer from huge computation complexity, while the biological neural network works in a much more powerful yet efficient way. Inspired by the biological plasticity of dendritic topology and synaptic strength, our method, Learnable Heterogeneous Convolution, realizes joint learning of kernel shape and weights, which unifies existing handcrafted convolution techniques in a data-driven way. A model based on our method can converge with structural sparse weights and then be accelerated by devices of high parallelism. In the experiments, our method either reduces VGG16/19 and ResNet34/50 computation by nearly 5x on CIFAR10 and 2x on ImageNet without harming the performance, where the weights are compressed by 10x and 4x respectively; or improves the accuracy by up to 1.0% on CIFAR10 and 0.5% on ImageNet with slightly higher efficiency. The code will be available on www.github.com/Genera1Z/LearnableHeterogeneousConvolution.

Keywords

Cite

@article{arxiv.2301.05440,
  title  = {Learnable Heterogeneous Convolution: Learning both topology and strength},
  author = {Rongzhen Zhao and Zhenzhi Wu and Qikun Zhang},
  journal= {arXiv preprint arXiv:2301.05440},
  year   = {2023}
}

Comments

Published in Neural Networks journal

R2 v1 2026-06-28T08:10:57.743Z