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Semi-Supervised Hyperspectral Image Classification with Edge-Aware Superpixel Label Propagation and Adaptive Pseudo-Labeling

Yunfei Qiu, Qiqiong Ma, Tianhua Lv, Li Fang, Shudong Zhou, Wei Yao

TL;DR

A novel semi-supervised hyperspectral classification framework integrating spatial prior information with a dynamic learning mechanism, and the Dynamic Reliability-Enhanced Pseudo-Label Framework, composed of DHP and ATSC, strengthens pseudo-label stability across temporal and sample domains.

Abstract

Significant progress has been made in semi-supervised hyperspectral image (HSI) classification regarding feature extraction and classification performance. However, due to high annotation costs and limited sample availability, semi-supervised learning still faces challenges such as boundary label diffusion and pseudo-label instability. To address these issues, this paper proposes a novel semi-supervised hyperspectral classification framework integrating spatial prior information with a dynamic learning mechanism. First, we design an Edge-Aware Superpixel Label Propagation (EASLP) module. By integrating edge intensity penalty with neighborhood correction strategy, it mitigates label diffusion from superpixel segmentation while enhancing classification robustness in boundary regions. Second, we introduce a Dynamic History-Fused Prediction (DHP) method. By maintaining historical predictions and dynamically weighting them with current results, DHP smoothens pseudo-label fluctuations and improves temporal consistency and noise resistance. Concurrently, incorporating condifence and consistency measures, the Adaptive Tripartite Sample Categorization (ATSC) strategy implements hierarchical utilization of easy, ambiguous, and hard samples, leading to enhanced pseudo-label quality and learning efficiency. The Dynamic Reliability-Enhanced Pseudo-Label Framework (DREPL), composed of DHP and ATSC, strengthens pseudo-label stability across temporal and sample domains. Through synergizes operation with EASLP, it achieves spatio-temporal consistency optimization. Evaluations on four benchmark datasets demonstrate its capability to maintain superior classification performance.

Semi-Supervised Hyperspectral Image Classification with Edge-Aware Superpixel Label Propagation and Adaptive Pseudo-Labeling

TL;DR

A novel semi-supervised hyperspectral classification framework integrating spatial prior information with a dynamic learning mechanism, and the Dynamic Reliability-Enhanced Pseudo-Label Framework, composed of DHP and ATSC, strengthens pseudo-label stability across temporal and sample domains.

Abstract

Significant progress has been made in semi-supervised hyperspectral image (HSI) classification regarding feature extraction and classification performance. However, due to high annotation costs and limited sample availability, semi-supervised learning still faces challenges such as boundary label diffusion and pseudo-label instability. To address these issues, this paper proposes a novel semi-supervised hyperspectral classification framework integrating spatial prior information with a dynamic learning mechanism. First, we design an Edge-Aware Superpixel Label Propagation (EASLP) module. By integrating edge intensity penalty with neighborhood correction strategy, it mitigates label diffusion from superpixel segmentation while enhancing classification robustness in boundary regions. Second, we introduce a Dynamic History-Fused Prediction (DHP) method. By maintaining historical predictions and dynamically weighting them with current results, DHP smoothens pseudo-label fluctuations and improves temporal consistency and noise resistance. Concurrently, incorporating condifence and consistency measures, the Adaptive Tripartite Sample Categorization (ATSC) strategy implements hierarchical utilization of easy, ambiguous, and hard samples, leading to enhanced pseudo-label quality and learning efficiency. The Dynamic Reliability-Enhanced Pseudo-Label Framework (DREPL), composed of DHP and ATSC, strengthens pseudo-label stability across temporal and sample domains. Through synergizes operation with EASLP, it achieves spatio-temporal consistency optimization. Evaluations on four benchmark datasets demonstrate its capability to maintain superior classification performance.
Paper Structure (22 sections, 22 equations, 8 figures, 6 tables)

This paper contains 22 sections, 22 equations, 8 figures, 6 tables.

Figures (8)

  • Figure 1: The overall framework of the proposed semi-supervised HSIC method.
  • Figure 2: Classification maps for the PaviaU dataset. (a) False color image. (b) Ground-truth. (c) A2S2K. (d) DMSGer. (e) SSTN. (f) CTF-SSCL. (g) DEMAE. (h) RMAE. (i) Ours. (j) Color labels.
  • Figure 3: Classification maps for the Houston2013 dataset. (a) False color image. (b) Ground-truth. (c) A2S2K. (d) DMSGer. (e) SSTN. (f) CTF-SSCL. (g) DEMAE. (h) RMAE. (i) Ours. (j) Color labels
  • Figure 4: Classification maps for the KSC dataset. (a) False color image. (b) Ground-truth. (c) A2S2K. (d) DMSGer. (e) SSTN. (f) CTF-SSCL. (g) DEMAE. (h) RMAE. (i) Ours. (j) Color labels
  • Figure 5: Classification maps for the Botswana dataset. (a) False color image. (b) Ground-truth. (c) A2S2K. (d) DMSGer. (e) SSTN. (f) CTF-SSCL. (g) DEMAE. (h) RMAE. (i) Ours. (j) Color labels
  • ...and 3 more figures