English

HCNet: Hierarchical Context Network for Semantic Segmentation

Computer Vision and Pattern Recognition 2020-10-21 v2

Abstract

Global context information is vital in visual understanding problems, especially in pixel-level semantic segmentation. The mainstream methods adopt the self-attention mechanism to model global context information. However, pixels belonging to different classes usually have weak feature correlation. Modeling the global pixel-level correlation matrix indiscriminately is extremely redundant in the self-attention mechanism. In order to solve the above problem, we propose a hierarchical context network to differentially model homogeneous pixels with strong correlations and heterogeneous pixels with weak correlations. Specifically, we first propose a multi-scale guided pre-segmentation module to divide the entire feature map into different classed-based homogeneous regions. Within each homogeneous region, we design the pixel context module to capture pixel-level correlations. Subsequently, different from the self-attention mechanism that still models weak heterogeneous correlations in a dense pixel-level manner, the region context module is proposed to model sparse region-level dependencies using a unified representation of each region. Through aggregating fine-grained pixel context features and coarse-grained region context features, our proposed network can not only hierarchically model global context information but also harvest multi-granularity representations to more robustly identify multi-scale objects. We evaluate our approach on Cityscapes and the ISPRS Vaihingen dataset. Without Bells or Whistles, our approach realizes a mean IoU of 82.8% and overall accuracy of 91.4% on Cityscapes and ISPRS Vaihingen test set, achieving state-of-the-art results.

Keywords

Cite

@article{arxiv.2010.04962,
  title  = {HCNet: Hierarchical Context Network for Semantic Segmentation},
  author = {Yanwen Chong and Congchong Nie and Yulong Tao and Xiaoshu Chen and Shaoming Pan},
  journal= {arXiv preprint arXiv:2010.04962},
  year   = {2020}
}
R2 v1 2026-06-23T19:14:00.712Z