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Multi-Label Noise Robust Collaborative Learning for Remote Sensing Image Classification.

Ahmet Kerem Aksoy, Mahdyar Ravanbakhsh, Begum Demir

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    This study introduces a robust collaborative learning method to handle noisy labels in remote sensing image classification. The approach effectively identifies and excludes incorrect labels, improving model accuracy without prior noise assumptions.

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    Area of Science:

    • Remote Sensing
    • Computer Vision
    • Machine Learning

    Background:

    • Accurate multi-label classification (MLC) of remote sensing (RS) images is crucial.
    • Convolutional neural network (CNN) based MLC methods require extensive, accurately labeled data, which is costly and time-consuming to acquire.
    • Publicly available thematic products offer a cost-effective annotation source but often contain noisy labels, hindering model performance.

    Purpose of the Study:

    • To develop a novel method for robust multi-label classification in remote sensing images.
    • To address the challenges posed by multi-label noise (incorrect and missing labels) in training data.
    • To improve the performance of CNN models for RS image MLC despite the presence of noisy labels.

    Main Methods:

    • Proposes a robust multi-label noise-robust collaborative learning (RCML) method.
    • RCML utilizes three modules: discrepancy, group lasso, and swap, to identify, rank, and exclude noisy labels.
    • The method does not make prior assumptions about the noise distribution in the training data.

    Main Results:

    • Demonstrates the robustness of the RCML method under extreme multi-label noise rates.
    • Experimental results on two multi-label RS image archives validate the effectiveness of the proposed approach.
    • The developed RCML method alleviates the negative effects of multi-label noise during CNN model training.

    Conclusions:

    • The proposed RCML method offers a robust solution for multi-label classification of remote sensing images with noisy labels.
    • RCML enhances the reliability of training data by effectively handling label noise without specific noise distribution assumptions.
    • The publicly available code facilitates further research and application of noise-robust learning in remote sensing.