DPFL-Nets: Deep Pyramid Feature Learning Networks for Multiscale Change Detection | IEEE Journals & Magazine | IEEE Xplore
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DPFL-Nets: Deep Pyramid Feature Learning Networks for Multiscale Change Detection


Abstract:

Due to the complementary properties of different types of sensors, change detection between heterogeneous images receives increasing attention from researchers. However, ...Show More

Abstract:

Due to the complementary properties of different types of sensors, change detection between heterogeneous images receives increasing attention from researchers. However, change detection cannot be handled by directly comparing two heterogeneous images since they demonstrate different image appearances and statistics. In this article, we propose a deep pyramid feature learning network (DPFL-Net) for change detection, especially between heterogeneous images. DPFL-Net can learn a series of hierarchical features in an unsupervised fashion, containing both spatial details and multiscale contextual information. The learned pyramid features from two input images make unchanged pixels matched exactly and changed ones dissimilar and after transformed into the same space for each scale successively. We further propose fusion blocks to aggregate multiscale difference images (DIs), generating an enhanced DI with strong separability. Based on the enhanced DI, unchanged areas are predicted and used to train DPFL-Net in the next iteration. In this article, pyramid features and unchanged areas are updated alternately, leading to an unsupervised change detection method. In the feature transformation process, local consistency is introduced to constrain the learned pyramid features, modeling the correlations between the neighboring pixels and reducing the false alarms. Experimental results demonstrate that the proposed approach achieves superior or at least comparable results to the existing state-of-the-art change detection methods in both homogeneous and heterogeneous cases.
Published in: IEEE Transactions on Neural Networks and Learning Systems ( Volume: 33, Issue: 11, November 2022)
Page(s): 6402 - 6416
Date of Publication: 24 May 2021

ISSN Information:

PubMed ID: 34029198

Funding Agency:


References

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