Review of remote sensing change detection in deep learning： Bibliometric and analysis

YANG Bin; MAO Yin; CHEN Jin; LIU Jianqiang; CHEN Jie; YAN Kai

doi:10.11834/jrs.20222156

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Review of remote sensing change detection in deep learning： Bibliometric and analysis
Vol. 27, Issue 9, Pages: 1988-2005(2023)
Published： 07 September 2023 ，
DOI： 10.11834/jrs.20222156

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杨彬，毛银，陈晋，刘建强，陈杰，闫凯.2023.深度学习的遥感变化检测综述：文献计量与分析.遥感学报，27（9）： 1988-2005

Yang B，Mao Y，Chen J，Liu J Q，Chen J and Yan K. 2023. Review of remote sensing change detection in deep learning： Bibliometric and analysis. National Remote Sensing Bulletin， 27（9）：1988-2005
杨彬，毛银，陈晋，刘建强，陈杰，闫凯.2023.深度学习的遥感变化检测综述：文献计量与分析.遥感学报，27（9）： 1988-2005 DOI： 10.11834/jrs.20222156.

Yang B，Mao Y，Chen J，Liu J Q，Chen J and Yan K. 2023. Review of remote sensing change detection in deep learning： Bibliometric and analysis. National Remote Sensing Bulletin， 27（9）：1988-2005 DOI： 10.11834/jrs.20222156.

摘要

遥感变化检测可以获取地表变化信息，对于理解人与自然相互作用，推动可持续发展具有重要意义。随着遥感成像技术的提升和计算机科学的快速发展，高光谱、高时间、高空间分辨率的遥感影像已广泛应用，促进了深度学习的遥感变化检测发展以及多领域成功应用。与传统遥感变化检测不同，基于深度学习的变化检测提取遥感影像的深度差异特征，无需构建特征工程，检测精度和效率均有所提高。本文结合文献计量学全面分析本领域研究现状和热点，发现基于深度学习的变化检测在国内机构学者的主导下快速发展并取得了大量研究成果。这些成果大都基于高分辨率图像和CNN网络，并成功应用于土地利用/覆盖和建筑变化检测等。在此基础上，从像素、对象和场景3个粒度对基于深度学习的遥感变化检测方法分类介绍，阐述开展像素、对象和场景的特征提取以及后续网络分析过程，其中基于对象和场景的方法具有优势。最后，归纳总结目前面临的挑战及未来可能发展方向。由于遥感平台的发展和应用需求的增加，多模态异质变化检测是未来发展趋势。另外，深度学习的方法还需要克服非理想样本问题，关注多元变化信息获取，以及推进变化检测的广泛应用等。

Abstract

Remote sensing change detection can provide information on land surface change

which is important for studying man-nature interactions and facilitating sustainable development. With the advancement of remote sensing imaging technology and the rapid development of computer technology

extensive remote sensing images with various modes and spectral

spatial

and temporal resolutions have been collected

enabling the development of massive remote sensing change detection methods based on deep learning and their successful application in a wide range of fields.

Unlike previous reviews

this work examines remote sensing change detection based on deep learning from the perspectives of bibliometric analysis

research scale

and critical problem exploration to provide reference materials for future remote sensing change detection research. The definition and importance of remote sensing change detection as well as the motivation for this review are briefly presented in the introduction. The literature structure and research hotspot information of existing research

such as the number of publications

distribution of journals and institutions

main researchers

common data sources

network model

and application field information

are clarified in the second section

which is combined with bibliometric analysis. In the third section

focus is on deep learning-based remote sensing change detection algorithms

which are categorized and presented on three scales: pixel

object

and scene. How to extract pixels

objects

and scenes from remote sensing images as well as how to perform network analysis are also explained. In the fourth section

the limitations of deep learning-based remote sensing change detection are covered

and the most recent research are presented to address these issues as well as future development possibilities. Next

a segment dedicated to the finale.

The bibliometric analysis reveals deep learning-based change detection has progressed rapidly in the last three years

with fruitful research results and domestic institutional scholars dominating. High-resolution images and CNN are the most used data sources and network model

and extensive land use/coverage and building change detection are hot application fields. As for methods

different research scales respond to varied data features and network model structures. The object and scene technique have advantages

and they face similar issues

which are summarized below. First is the problem of detecting changes using multimodal remote sensing data. To address this

adversarial training

attention mechanisms

and feature deep fusion methods based on feature space transformation appear promising. Multimodal data fusion and other multimodal learning approaches are among the future’s emerging directions. Second

change detection under small sample and imbalanced sample settings is difficult. Semi-supervised schemes must be improved to address the problem of small sample size

and self-supervised methods are predicted to become a research hotspot. The oversampling technique and ensemble learning in deep learning models provide a new path for unbalanced samples. The third issue is obtaining diversified change information. Semantic change detection

which obtains extensive information on change types

and Transformer for time series change detection

which obtains long-term change information

are the future trends. Furthermore

deep learning-based change detection requires advances in gathering dynamic information such as time and seasonal pattern of change.

This work systematically compiles and reviews the research status and progress of deep learning-based remote sensing image change detection. Multimodal heterogeneous change detection

semantic change detection

and time series change detection are future prospects as application needs and data diversity grow. In the areas of resources

the environment

and disaster relief

practical uses of existing knowledge are few. Continuously extending the in-depth study of new technologies and methods is required as is promoting wide

in-depth remote sensing change detection research and application.

关键词

遥感变化检测深度学习文献计量方法分类挑战及发展综述

Keywords

remote sensingchange detectiondeep learningbibliometricmethods classificationchallenges and prospectsreview

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