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  • Peijun DU, Hong FANG, Shanchuan GUO, Chenghan YANG, Pengfei TANG
    Remote Sensing Technology and Application. 2025, 40(4): 783-794. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0783

    Change detection refers to the technology of extracting land cover changes by comparing and analyzing multi-temporal remote sensing images acquired at different periods covering the same area. With the advancements in satellite and sensor technologies, there has been a significant increase in Earth observation data. Change detection plays an important role in various fields, including geoinformation survey and ecological environment protection. In recent years, deep learning technology has become an advanced method for change detection due to its powerful feature mining ability. This paper provides a comprehensive overview of deep learning-based change detection methods from three aspects: pixel-level, object-level, and scene-level. Furthermore, this paper discusses the practical implementation of deep learning in change detection through three research examples. Finally, the study concludes by outlining future development trends in deep learning-based change detection.

  • Chengquan ZOU, Jiangcheng HUANG, Zhengbao SUN, Yutong YANG
    Remote Sensing Technology and Application. 2025, 40(4): 969-989. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0969

    The super-resolution reconstruction of remote sensing images is a type of method that uses image analysis methods to reconstruct high-resolution images from one or more low resolution images, in order to restore high-frequency details lost during sensor imaging, storage, and transmission, and improve the quality of remote sensing image data. The core lies in constructing a mapping relationship between high- and low- resolution images. This paper reviews the mainstream methods and representative research works in image super-resolution reconstruction and focuses on analyzing the recent advances in traditional methods and deep learning methods in the field of remote sensing image super-resolution reconstruction. The results indicates that: (1) Methods based on deep learning frameworks are the main focus and frontier of research in remote sensing image super-resolution reconstruction methods; (2) Model lightweighting and real-time performance are the main challenges faced by super-resolution reconstruction methods for multispectral remote sensing images in complex scenes; (3) There is an urgent need to construct public datasets for research on remote sensing image super-resolution reconstruction methods and to improve the evaluation index system. In addition, this paper also discusses the effects of methods based on bicubic interpolation, CNNs, GANs, and DPMs frameworks on remote sensing image super-resolution reconstruction in complex scenes through experiments.

  • Liangyun Liu, Shanshan Du, Xinjie Liu, Chu Zou, Mengjia Qi, Dianrun Zhao, Yulu Du, Wenyu Li, Mengchen Li, Shaoyang Chen
    Remote Sensing Technology and Application. 2026, 41(1): 1-22. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0001

    Solar-Induced chlorophyll Fluorescence (SIF), a proxy for vegetation photosynthetic activity, has gained widespread applications. This review synthesizes the principles, progress, and key frontiers in satellite SIF remote sensing. Firstly, we introduced the SIF retrieval principles and algorithms at both ground and spaceborne platforms. The SIF retrieval methods can be divided into two categories: physically-based inversion and data-driven algorithms. The accurate separation of SIF from reflected radiance in upwelling radiation is the key challenge. The current ground-based retrievals are still limited by spectrometer resolution and Signal-to-Noise Ratio (SNR), developing instrument-agnostic, high-robustness algorithms remains a research priority. Data-driven approaches dominate satellite SIF retrievals. However, huge uncertainties persist in red-band SIF retrieval, demanding transformative algorithmic breakthroughs. Second, we analyze global SIF satellite developments over 30 years, highlighting China’s rapid progress (e.g., successful experiments with TanSat and Goumang). Nevertheless, gaps persist in satellite longevity, data sharing, and scientific utilization compared to international counterparts. The next-generation TanSat-2 (to be launched in 2026) is expected to revolutionize SIF remote sensing, offering 2-km resolution, global daily coverage, and dual-band (red/far-red) SIF data—resolving critical limitations of low resolution, SNR, and revisit frequency. Finally, we investigated the progresses of spatiotemporal fusion of SIF satellite data. Machine Learning (ML)-based simulation methods have achieved high-precision simulation of SIF data and have been widely used. However, the ML-based SIF datasets represent the modeled signals driven by reflectance and meteorology, not observations. Spatial downscaling of satellite SIF products preserves observational fidelity despite lower spatiotemporal continuity than ML counterparts. Emerging multi-sensor, long-term (1995—2024), 0.05°-resolution downscaled products hold potential to accelerate SIF science applications. Therefore, despite the inherent challenge of high-precision retrieval of weak SIF signal, advances in payload technology and quantitative remote sensing are rapidly transforming SIF monitoring capabilities. China’s SIF remote sensing program (TanSat-2) is positioned to play an increasingly pivotal role in guiding global SIF science and applications.

  • Jing YANG, Hui ZHAO, Yaohua LUO, Jundi WANG
    Remote Sensing Technology and Application. 2025, 40(4): 923-935. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0923

    The classification of wetlands with high-resolution images is one of the research hotspots of remote sensing classification. Aiming at the complex mottling of high-resolution image wetlands and wetland hydrological boundaries fluctuate seasonally, the traditional classification of high-resolution image wetlands adopts the manual extraction feature interpretation method, which is time-consuming, laborious and has low accuracy. Therefore, how to achieve automatic and efficient interpretation of wetlands is an urgent problem to be solved. In recent years, with the rapid development of artificial intelligence technology, the use of deep learning to achieve high-resolution image wetland classification has become a new research direction. In order to promote the development of high-resolution image wetland classification technology, the latest research results of deep learning models commonly used in high-resolution image wetland classification, including deep neural networks, convolutional neural networks, and generative adversarial networks, are summarized, and the application and innovation of various deep learning models in high-resolution image wetland classification were analyzed and discussed, such as the application of ensemble learning and the construction of semi-supervised models. Finally, from the aspects of samples and models, the problems of deep learning in the classification of wetlands with high-resolution images and the possible research trends in the future are prospected.

  • Jingwei SONG, Changhua LIU, Pengfei ZHAN, Chunqiao SONG
    Remote Sensing Technology and Application. 2025, 40(4): 936-955. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0936

    As the main surface water resource carrier, lakes play an important role in regulating river water volume and meeting water demand for life, production and ecology. Similarly, artificial lakes (reservoirs) also play a key role in water supply, irrigation, power generation and ecological protection. In recent years, affected by climate change and human activities, the water volume and quality of lakes and reservoirs (referred to as "lakes and reservoirs") have changed greatly. Long-term remote sensing monitoring can more objectively and accurately understand the temporal and spatial changes. The study combined multi-source remote sensing image data and satellite altimetry data to extract the area and water level of China's key monitored lakes (83) and reservoirs (118) from 2013 to 2022, estimated the changes in the water volume of lakes and reservoirs, and sorted out the monitoring data of key lakes and reservoirs through the monthly water quality reports issued by relevant national departments, analyzed the changes in their eutrophication levels, and finally conducted a comprehensive analysis of the two. The results show that: in terms of water volume, the water volume of China's key lakes and reservoirs showed an overall increasing trend during 2013~2022, with the water volume of lakes increasing by 10.65 km³ and the water volume of reservoirs increasing by 2.50 km³; in terms of water quality, the water quality of most monitored lakes was poor, ranging from mesotrophic to mildly eutrophic, and the number of lakes with mesotrophic to mildly eutrophic levels generally increased year by year; the water quality of reservoirs was relatively good, but the water quality of some reservoirs showed a trend of deterioration. The combined analysis of water volume and water quality change information found that the water volume of lakes and reservoirs changed greatly when they were at the mesotrophic level, and there were different correlations between water volume and water quality. Among them, the water volume and water quality changes of 33 lakes showed a negative correlation, especially Chengxi Lake and Shijiu Lake in the eastern plains, with correlation coefficients of -0.67 and -0.90, respectively. In addition, the water volume and water quality changes of nearly half of the reservoirs showed a positive correlation. By combining the water quantity and water quality monitoring data of lakes and reservoirs and exploring the relationship between the two, we can provide an important scientific basis for the comprehensive water resources management and ecological protection of lakes and reservoirs.

  • Jiancheng SHI, Lingmei JIANG, Jie CHENG, Tianjie ZHAO, Huizhen CUI, Jinmei PAN, yonghui LEI, Huazhe SHANG, Chaolei ZHENG, Lu JI, Dabin JI, Yongqian WANG, Chuan XIONG, Tianxing WANG, Wei FENG, Yongqiang ZHANG, Xuanze ZHANG, Jianguang WEN, Hui LU, Letu HUSI
    Remote Sensing Technology and Application. 2025, 40(4): 761-782. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0761
    Abstract (565) Download PDF (1914) HTML (108)   Knowledge map   Save

    The terrain of the “Asian Water Tower” area centered on the Qinghai-Tibet Plateau is complex and the weather is changeable. Especially in the alpine areas, ground observations are scarce. The existing remote sensing observation energy and water cycle elements lack a comprehensive systematic framework, and the accuracy is not high, making it difficult to obtain the understanding of the temporal and spatial distribution and variation characteristics of water balance in the Asian Water Tower area. Relying on the special project of "The Second Comprehensive Scientific Expedition to the Qinghai-Tibet Plateau", systematic satellite remote sensing observation research on energy and water cycle in the Qinghai-Tibet Plateau was carried out. The development and sharing of satellite remote sensing datasets for 15 key elements of energy and water cycle were completed. The retrieval methods and technologies for each element were improved and developed. A satellite networking observation system for key elements of regional energy balance (6 types) and water cycle (9 types) in the Asian Water tower has been formed (including cloud, surface temperature, emissivity, radiation, albedo, Precipitation- Evapotranspiration, atmospheric water vapor, soil moisture, soil freeze-thaw, snow cover and snow depth, surface water change and terrestrial water storage, etc.), and a systematic remote sensing dataset of energy and water cycle elements with high precision, spatiotemporal continuity and high spatiotemporal resolution has been produced. The systematic analysis based on this dataset indicates that the multi-year average spatial distribution pattern of surface evapotranspiration on the Qinghai-Tibet Plateau is controlled by the precipitation distribution and shows a decreasing trend from southeast to northwest. Evapotranspiration is mainly controlled by moisture conditions in most areas (arid and semi-arid regions), and is dominated by radiation factors only in a few humid areas. The energy parameters that affect the evapotranspiration of the plateau and other factors of the water cycle, such as the downward long-wave radiation on the surface, show an increasing trend, while the surface reflectivity shows a decreasing trend, which has a significant correlation with the decreasing trend of snow coverage. In addition, key parameters of the water cycle such as atmospheric water vapor, soil moisture, lake area and land water storage all show a significant increasing trend, while snow coverage and the annual freezing days of the surface show a decreasing trend. Overall, since 2000, the Qinghai-Tibet Plateau has generally shown a trend of warming and humidification. The dataset provided in this paper is conducive to supporting the combination of remote sensing and models, and promoting the verification and improvement of models for regional climate-land surface and multi-sphere hydrology.

  • Hongliang FANG
    Remote Sensing Technology and Application. 2025, 40(4): 802-815. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0802

    Over the past two decades, studies about the spectral invariant theory have been developed rapidly in vegetation remote sensing. The theory has been widely used in vegetation parameter measurement, canopy reflectance modeling, and biophysical parameters retrieval. A review paper titled "Photon recollision probability and the spectral invariant theory: Principles, methods, and applications" was published by the author in “Remote Sensing of Environment” in 2023 (DOI: 10.1016/j.rse.2023.113859). The current paper provides a comprehensive overview of the background of spectral invariant theory, general principles of the theory, determination and applications of spectral invariants. Recent progresses of the theory are summarized and potential future developments are discussed. A special section is dedicated to the researches made by Chinese scholars. The goal is to provide a synthetic overview of the theory. Some new thoughts about the theory are also given in the paper.(1) The spectral invariant theory evolves from the successive orders of scattering approximation method of the multiple scattering process of photons in vegetation canopy. The theory faciliates the conversion of spectral parameters between different spectral bands and different scales (mainly between leaves and canopy) and provides new means for calculating the directional reflectance, albedo, and fluorescence escape probability.(2) Spectral invariants can be obtained through empirical methods, spectral methods, and structural methods. The spectral method is divided into single scale spectral method and spectral scaling method, and the structural method is divided into the Silhouette to Total Area Ratio (STAR) method, clumping index method, Stenberg method, and approximation method. Different methods can be cross-validated.(3) The spectral invariant theory has been applied in a number of canopy reflectance models. Based on these models, researchers have carried out a large number of inversion studies for vegetation structural parameters and physiological parameters. The principles, methods and applications of the theory can be further explored in the future.(4) New approximation methods for the spectral invariants are proposed and new formulae for the visible sunlit leaf area index and the hemispherical directional area scattering factor are summarized. Chinese researchers have made significant contribution to the development of the theory, especially in calculating the escape probability of the solar induced fluorescence using the theory.

  • Ming SHI, Yang SHI, Fei LIN, Xia JING, Yimin HU, Bingyu LI
    Remote Sensing Technology and Application. 2025, 40(4): 1052-1066. https://doi.org/10.11873/j.issn.1004-0323.2025.4.1052

    Soil Organic Matter (SOM), a vital component of the soil solid phase, provides essential nutrients for plant growth and serves as a key indicator of soil fertility. Recent advancements in remote sensing technology have introduced novel approaches for efficient SOM estimation and mapping, yet challenges persist due to environmental interference and data complexity. This review systematically examines the applications of multispectral and hyperspectral data in SOM inversion and mapping, alongside critical data processing methodologies. Comparative analyses demonstrate that laboratory-acquired spectral data under controlled conditions exhibit significantly higher model accuracy and robustness compared to field-collected data, attributed to stable measurement environments. Feature selection and extraction, particularly for hyperspectral datasets, enhance inversion precision by mitigating data dimensionality and multicollinearity. Ensemble modeling frameworks integrating machine learning and deep learning outperform single-model approaches by effectively characterizing the nonlinear complexity of soil systems. Multi-temporal datasets further improve predictive capabilities by incorporating seasonal vegetation dynamics and temporal evolutionary patterns. However, optical data remain susceptible to atmospheric disturbances, especially in cloud-prone regions such as southern China, while microwave remote sensing emerges as a complementary solution for its all-weather operability and topographic adaptability. Future research should prioritize multi-source synergy strategies, including optical-SAR synergies, multi-sensor platform integration, and physics-informed machine learning to address confounding factors like crop residue cover and soil moisture. Advanced preprocessing techniques, such as wavelet analysis and blind source separation, are essential for isolating soil-specific spectral signatures. Spatiotemporal modeling frameworks that integrate soil types, agronomic practices, and climatic variables will enhance prediction generalizability. Concurrently, developing interpretable artificial intelligence models and geographically adaptive spatial interpolation methods is crucial to ensure scientific rigor and global scalability. This study provides theoretical and practical insights for leveraging multi-source remote sensing in precision agriculture and sustainable land management.

  • Shangrong LIN, Yuan TAO, Yi ZHENG, Xing LI
    Remote Sensing Technology and Application. 2025, 40(4): 851-863. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0851

    Terrestrial Gross Primary Production (GPP) is the total amount of organic carbon fixed by plant photosynthesis, and it is also the start of terrestrial carbon cycles. The remote sensing data-driven GPP models can accurately monitor the spatio-temporal pattern of GPP at the regional scale. The remote sensing data-driven GPP products support the studies of terrestrial carbon cycles, ecosystem responses to climate change and ecosystem service. However, large discrepancies in absolute magnitude, spatial distribution, and interannual variability in remote sensing data-driven GPP models lead to a large uncertainty in the estimation of global GPP. The uncertainty mainly stems from the fact that different researchers have adopted different modeling frameworks and assumptions, different remote sensing data sources, and different research periods, and thus researchers have come up with diverse conclusions. For this reason, it is necessary to summarize the results of existing representative studies to form a knowledge base and understanding of the remote sensing data-driven GPP models and their applications at the macro-scale level. Meanwhile, this study also discusses the common problems in current remote sensing data-driven GPP models and provides an outlook for future model developments.

  • Limin CHEN, Ainong LI, Jinhu BIAN, Zhengjian ZHANG, Guangbin LEI, Guyue HU, Ziyang HUANG, Xiaohan LIN
    Remote Sensing Technology and Application. 2025, 40(5): 1067-1079. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1067

    Leaf Area Index (LAI) is an important parameter for studying vegetation canopy structure and physiological and biochemical characteristics. Due to the high complexity and heterogeneity of mountain’s surface and forest canopy structure, there is no unified standard for mountain LAI ground measurement methods, resulting in significant differences in ground measurement between different methods. In order to analyze the effect of various factors on the ground measurement, and improve the accuracy and reliability of LAI ground measurement data in mountainous areas, this article uses LAI2200 Plant Canopy Analyzers (LAI2200) and Digital Hemisphere Photography (DHP) to conduct LAI ground observation experiments in typical mountain forest scenes, quantitatively analyzing different optical measurement instruments, vegetation clumping effects, the impact of terrain and other factors on the LAI ground measurement in mountainous areas. The results showed that both LAI2200 and DHP optical instrument could be used to measure LAI in mountain forests. The experiment found that LAI2200 was more sensitive to LAI of coniferous forest than DHP; Regarding the impact of terrain factors on LAI ground measurement, the hinder of incident radiation by surrounding terrain fluctuations is an important factor that causes measurement errors and needs to be eliminated in the measurement; In addition, the vegetation clumping effect has a significant impact on the measurement results, and it is necessary to correct the effective LAI by introducing the Clumping Index (CI) to obtain the true LAI. This article provides effective reference suggestions for improving the accuracy and precision of LAI ground measurement in mountainous forests.

  • Zhenghua CHEN, Sixiang LAN, Jinshui ZHANG, Wei ZHANG, Huade LI, Lifang ZHAO
    Remote Sensing Technology and Application. 2025, 40(4): 909-922. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0909

    Black and odorous water is an extreme water pollution phenomenon that is a common problem in many cities, seriously affecting the well-being and satisfaction of residents. Therefore, addressing the issue of urban black and odorous water is urgent. Scientifically monitoring the urban black and odorous condition of water is the first step in the remediation of black and odorous water, providing accurate targets for subsequent assessment. Compared to traditional ground-based monitoring methods, remote sensing is a more effective way to discover black and odorous water, allowing for a wider and more rapid identification of black and odorous water areas and timely comprehensive representation of the spatiotemporal evolution of black and odorous water. This paper reviews the main research advances in remote sensing monitoring of urban black and odorous water. First, it briefly introduces the overview of black and odorous water, summarizes the remote sensing feature, and common data sources for urban black and odorous water. Second, it discusses in detail the methods for remote sensing identification and classification of urban black and odorous water and compares the applicability and advantages and disadvantages of each method. Finally, it summarizes the current status of remote sensing research on urban black and odorous water and its shortcomings and looks forward to future development directions. The aim is to provide reference and thinking for related research and better decision support for the long-term management of black and odorous water.

  • Yanli ZHI, Yu ZHOU, Qing LIU, Licai YAN, Xin LIU
    Remote Sensing Technology and Application. 2025, 40(5): 1232-1242. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1232

    The previous methods for hyperspectral data classification only focus on the extraction of spectral features, which often wastes some valuable spectral spatial information and leads to unsatisfactory classification results. In view of this, this paper proposes a method that combines Principal Component Analysis (PCA), guided filtering and deep learning architecture into hyperspectral data classification. First, PCA, as a mature dimension reduction architecture, can effectively reduce the redundancy of hyperspectral information; Then, guided filtering is used to provide a simple and effective channel to obtain spatial dominant information; Finally, the stack Autoencoder model is used as a deep learning architecture to effectively process deep level multi feature image data. Train and test the algorithm using two common datasets, and then use a third common dataset to test the models trained on the other two datasets. The experimental results show that the proposed GF-FSAE algorithm achieves classification accuracy above 99%, demonstrating good classification performance and generalization ability. Compared to the CNN-AL model, the algorithm’s accuracy is slightly higher, verifying the superiority of the spectrum-spatial hyperspectral image classification framework。

  • Yudi YANG, Ying GUO, Xin TIAN, Qingwang LIU, Guoqi CHAI, Jianwen HUANG, Xin LUO, Shuxin CHEN, Haiyi WANG
    Remote Sensing Technology and Application. 2025, 40(4): 1026-1035. https://doi.org/10.11873/j.issn.1004-0323.2025.4.1026

    Forest ecosystems play a crucial role in regulating climate, maintaining water and soil, and balancing carbon. However, in recent years, this system has been increasingly disturbed by climate change and human activities, making precise and timely forest change monitoring urgently needed. Remote sensing technology, with its advantage of multi-temporal resolution data and automated processing capabilities, has become a key means for forest change detection. This paper focuses on multi-temporal resolution remote sensing change detection methods, systematically reviews and compares two types of technologies: bi-temporal and time series remote sensing. Bi-temporal change detection includes manual visual interpretation, traditional machine learning, and deep learning techniques; time series include research on temporal trend analysis, dynamic change monitoring, and multi-algorithm integration. By summarizing the related problems of deep learning and multi-modal time series data in practical applications, relevant solutions are proposed, providing references for improving the accuracy of forest change detection.

  • Bin YANG, Xianfeng LI, Junqiang ZHANG, Huawei WAN, Yongshuai YU, Jixi GAO, Yongcai WANG
    Remote Sensing Technology and Application. 2025, 40(5): 1333-1343. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1333

    Above Ground Biomass (AGB) is an important indicator of grassland ecosystem function and grassland productivity. Accurate estimation of AGB is of great significance for grassland management and ecological environment assessment. Taking part of grassland in Xilinhot, Hulunbuir and Ordos grassland of three different types as the research area, based on UAV multi-spectral data, LiDAR data and field measured sample data, multiple texture and vegetation index were obtained, and different feature combinations were obtained through various feature screening methods. Five regression analysis algorithms, including Random Forest(RF), Multiple Linear Regression(MLR), BP neural network(BP), Support Vector Regression(SVR), and Long Short-Term Memory neural network(LSTM), were used to construct a grassland AGB estimation model, and the optimal estimation model was obtained after comparison and evaluation, and the spatial biomass estimation was carried out. The results indicate that: (1) The feature combination selected by the feature importance method, including spectral indices and the measured average plant height (Mean Height) within the sample plots, achieved high accuracy in multi-model comparisons for grassland AGB estimation; (2) The Random Forest model outperformed other models in estimation accuracy. Using the coefficient of determination(R²),Root Mean Squared Error(RMSE),and Mean Absolute Error(MAE) as evaluation metrics,the test sample achieved an R² of 0.859, with RMSE and MAE values of 35.17 g/m² and 28.22 g/m², respectively. The study demonstrates that integrating multi-source remote sensing features with machine learning algorithms can effectively overcome the limitations of traditional AGB estimation methods. The Random Forest model based on optimized feature combinations provides a reliable methodological reference for accurate grassland AGB estimation.

  • Yu LU, Xiaoying WANG, Yuke ZHOU, Xiong XIONG, Guitao PAN
    Remote Sensing Technology and Application. 2025, 40(5): 1255-1268. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1255

    The Qinba Mountain region, encompassing the transition zone between North and South China, holds significant ecological importance. Investigating the phenological changes in vegetation and their response to climate change in this region is crucial for understanding the complexity of the ecological environment in the transitional zone and reconstructing historical climate patterns. Based on MODIS MCD12Q2 data and meteorological remote sensing data, this study employs trend analysis and correlation analysis methods to explore the spatiotemporal characteristics of vegetation phenology in the Qinba Mountain region from 2001 to 2020 and its relationship with climate change. Results indicate that the start, end, and length of the growing season in the Qinba Mountain region exhibit distinct vertical zonal distribution characteristics from east to west. The start of the growing season is primarily distributed from mid-to-late March to late April (70-110 days), while the end of the growing season is concentrated from late October to late November (290-320 days), with the majority of growing seasons falling between 180 and 260 days. Over the 20-year period, the overall characteristics of phenological interannual variation in the Qinba Mountain region show an average advancement of 0.38 days per year. The end of the growing season exhibits an average delay of 0.43 days per year. The length of the growing season displays an average extension of 0.80 days per year. Significant trend of change. Regarding the time lag response to climate factors, the start of phenology in the Qinba Mountain region shows the highest correlation with monthly temperature and potential evapotranspiration without significant time lag effects, while precipitation exhibits a time lag of approximately 1.73 months. Altitude to some extent determines the response relationship between the start of phenology and various meteorological elements in the Qinba Mountain region.

  • Yingqi Yan, Fei Li, Qidan Huang, Shengxi Bai, Yongguang Zhang
    Remote Sensing Technology and Application. 2026, 41(1): 23-33. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0023

    Approximately 60% of global methane emissions originate from anthropogenic sources, making their effective control a critical aspect of greenhouse gas reduction efforts. The energy sector is a major contributor to anthropogenic methane emissions, with emission events traceable to specific facilities and characterized by a heavy-tailed distribution of emission rates. High-resolution hyperspectral satellite remote sensing data enable methane emission monitoring at the point-source scale and facilitate attribution to specific facilities. A high-resolution remote sensing monitoring system for methane point sources in the global energy sector has been developed based on hyperspectral retrieval methods and a WebGIS platform. The system comprises a point-source retrieval algorithm, a methane emission retrieval dataset, and a monitoring platform. By the end of 2024, effective monitoring of 573 methane emission events worldwide has been achieved. The system is designed to detect sudden methane emissions from coal mining and oil and gas extraction and storage, enabling facility-specific attribution. Support and validation data for emission source identification and estimation in the energy sector are provided, contributing to global methane reduction efforts.

  • Duo CHU, Zhuoma LABA, Dunzhu ZHAXI, Sangdan PINGCUO
    Remote Sensing Technology and Application. 2025, 40(6): 1367-1380. https://doi.org/10.11873/j.issn.1004-0323.2025.6.1367

    In this study, a comprehensive overview of snow avalanche hazards occurred in the past in Xizang area was reviewed first, followed in-depth analysis on the spatial distribution and main driving factors of snow avalanche hazards in the Xizang mountain region. Snow avalanche-prone areas for the study area were then mapped based on the spatial distribution of snow cover and DEM (Digital Elevation Model) data, and were validated using in-situ observations in southeastern Xizang. Results indicated that there are the highest frequencies of avalanche occurrences in southeastern Nyainqentanglha mountains and southern slope of the Himalayas. In the interior of plateau, avalanche occurrence is constrained due to less precipitation and flatter terrain. The perennially snow avalanche-prone areas in Xizang account for 1.6% of total area of the plateau, while it reaches 2.9% and 4.9% of total area of Xizang in winter and spring, respectively. Snow avalanche hazards and fatalities present increasing trends under global climate warming due to more human activities at higher altitudes. In addition to continuous implementation of engineering prevention and control measures in the key regions, such as in Sichuan-Xizang highway and railway sections, enhancing monitoring, early warning and forecasting services are important to prevent and mitigate avalanche hazards in the Xizang high mountain regions.

  • Yu CHEN, Huibin CHENG, Peijun DU, Jun WEI, Fengkai LANG, Kaiwen DING, Zhihui SUO
    Remote Sensing Technology and Application. 2025, 40(4): 816-834. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0816

    Underground coal fires are regarded as a global disaster "without geographical boundaries", not only resulting in substantial waste of coal resources but also posing serious threats to ecological environments and the safe development of society. Remote sensing technology has demonstrated unique advantages in the long-term detection and identification of underground coal fires, providing critical technical support for monitoring and remediation efforts. Focusing on the typical surface response characteristics induced by underground coal fires, this paper elaborates on the fundamental principles of remote sensing detection and identification in coal fire areas, systematically analyzes and reviews the existing remote sensing-based methods for detecting and identifying underground coal fire zones, highlighting the strengths and limitations of each approach. Building on this analysis, the paper discusses the existing research gaps and provides a forward-looking perspective on the existing challenges and future development directions in this field.

  • Shan XU, Xiya ZHOU, Zixiao GUO
    Remote Sensing Technology and Application. 2025, 40(4): 1036-1051. https://doi.org/10.11873/j.issn.1004-0323.2025.4.1036

    It is of great significance to have a detailed and accurate inventory of anthropogenic CO2 emissions and to strengthen the effective control of CO2 emissions in order to achieve the carbon peak and neutrality targets. Therefore, this study evaluated the reliability of EDGAR and ODIAC global anthropogenic CO2 emission inventories in China and developed a high-accuracy and high-resolution estimation model for anthropogenic CO2 emission based on multi-source remote sensing data and the Random Forest algorithm. The anthropogenic CO2 emissions from 2005 to 2020 at the resolution of 1 km×1 km were estimated and the clustering patterns of anthropogenic CO2 emissions were explored using the spatial autocorrelation. The spatial and temporal variations of anthropogenic CO2 emissions in China and key areas of clustering patterns were then analysed. Results show that the estimation model of anthropogenic CO2 emissions in China can effectively integrate the advantages of global inventory and remote sensing data, providing valid support for the spatial and temporal estimation of anthropogenic CO2 emissions at a fine scale; from 2005 to 2013, China's anthropogenic CO2 emissions increased dramatically from 5.53 billion tonnes to 10.73 billion tonnes; the growth rate of CO2 emissions declined in 2013-2020, with changes tending to flatten out; China's overall anthropogenic carbon emissions demonstrate regional characteristics of "high in the east and low in the west, high in the coastal and low in the inland", clustering in the focus areas of Yangtze River Delta, Beijing-Tianjin-Hebei region and western region; the characteristics of anthropogenic carbon emissions in different regions are closely related to their industrialization process, level of economic development, scale of counties and so on.

  • Hao JIANG, Wei ZHANG, Jing CHEN, Xiren MIAO, Zhuo LIN, Jiahuang WEI
    Remote Sensing Technology and Application. 2025, 40(5): 1243-1254. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1243

    In response to the challenge of significantly degraded image quality and difficulties in target detection caused by heavy fog during typhoon weather, as well as the limited generalization of existing research in power scenarios, an improved algorithm that integrated dark channel defogging with YOLOv8 is proposed. The proposed algorithm employs a two-stage processing technique. Initially, color adaptive defogging is applied based on an analysis of the image's color distribution using cumulative distribution functions and the dark channel algorithm to enhance the visibility of targets within foggy environments. Subsequently, to further enhance detection accuracy for multi-scale targets in remote sensing images,A small target detection layer is introduced into the YOLOv8 network architecture. This addition facilitates deeper feature extraction for small targets while employing MPDIoU instead of CIoU to reduce computational complexity. Experimental results demonstrate that the proposed algorithm improves detection accuracy for power towers and wind turbines by 8.1% and 3.9%, respectively. These findings validate both the feasibility and effectiveness of the proposed algorithm in processing foggy remote sensing images and recognizing targets, thereby providing reliable technical support for defogging operations on such images and identifying large-scale outdoor power facilities.

  • Xuanzhi LU, Jiancheng LUO, Tianjun WU, Jing ZHANG, Manjia LI
    Remote Sensing Technology and Application. 2025, 40(5): 1080-1093. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1080

    In the process of obtaining agricultural planting structure through remote sensing images, the uncertainty of remote sensing images itself and the classification process will inevitably reduce the accuracy and reliability of mapping results. As the basic unit of agriculture, parcels have the advantages of classification accuracy and uncertainty control. However, current remote sensing classification uncertainty research methods mostly use pixels as the basic unit, which is difficult to directly apply to parcels crop classification. Therefore, using parcels as the basic spatial unit and selects information entropy as the posterior uncertainty evaluation index to carry out crop classification and uncertainty analysis experiments in the Ningxia Irrigation District of the Yellow River. With the help of temporal characteristics and multiple value characteristics inside the parcel, the influence effects of random uncertainty and fuzzy uncertainty in remote sensing data on posterior classification uncertainty are analyzed. The experimental results show that: (1) Compared with pixel-scale classification, parcel-scale classification can effectively weaken posterior uncertainty; (2) Random uncertainty has a significant impact on posterior uncertainty and is significantly correlated with temporal characteristics; (3) The fuzzy uncertainty introduced by mixed pixels at the edge of the parcel and internal mixed heterogeneity amplifies the random uncertainty and further affects the posterior uncertainty. Targeted reduction measures can effectively reduce classification uncertainty, and the reduction effect is basically consistent with the correlation analysis results. The research results can provide ideas and methods for subsequent improvement of crop classification process and uncertainty control.

  • Sihui FAN, Jianjie WANG, Jingwen XIA, Yanzhen QIAN, Chengming ZHANG, Yang KONG
    Remote Sensing Technology and Application. 2025, 40(5): 1344-1354. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1344

    Geostationary meteorological satellite imagers enable extensive and continuous monitoring of sea fog. However, when cloud layers cover the fog region, the signals received by the satellite primarily originate from the upper cloud layers, making it challenging to ascertain the presence of sea fog in the lower layers. In the East China Sea, occurrences of fog events beneath cloud cover are frequent, impeding the operational application of satellite remote sensing in sea fog detection. Based on the channel design features of the Advanced Himawari Imagers (AHI) on-board the Himawari-8 geostationary meteorological satellite, we creatively proposed an algorithm aiming at detecting sea fog covered by high-level ice clouds combined with radiation transfer theory simulation and real observations. Two long-wave infrared channels (8.5 μm and 11 μm) were utilized to identify the cloud-top phase (ice clouds or water clouds). Low-level water clouds and sea fog beneath ice clouds were distinguished by the differences in radiation characteristics in the short-wave infrared (1.6 μm and 2.25 μm) and visible (0.64 μm) channels when ice clouds were identified. Finally, the accuracy of this algorithm was verified according to Cloud-Aerosol Lidar with Orthogonal Polarization (CALIOP) data. The results showed good consistency between our algorithm and CALIOP, with an average probability of detection of 49%, a false alarm ratio of 7%, and a critical success index of 46%. Due to the difficulty of detecting fog under clouds in the field of satellite remote sensing, the results demonstrate that this algorithm can detect sea fog under ice clouds.

  • Junli XU, Donghui SHANGGUAN, Jian WANG, Chao JIANG
    Remote Sensing Technology and Application. 2025, 40(6): 1381-1393. https://doi.org/10.11873/j.issn.1004-0323.2025.6.1381

    Monitoring of glacial lakes based on remote sensing is one of the current research hotpots in cryospheric science. Imageries from the Multispectral Imager for Inshore of SDGSAT⁃1 would be one of important data resource for glacial lake researches. Our study focuses on nearly 2 000 glacial lakes in the Mount Everest region. An automatic extraction for glacial lakes is applied to the multispectral bands of SDGSAT-1 images. The accuracy of the glacial lakes on SDGSAT-1 MII images is assessed by comparing with lakes from both Sentinel-2 MSI and Landsat 8 OLI. The area difference of glacial lakes between SDGSAT-1 and Sentinel-2 MSI or Landsat 8 OLI is quantified as error. And the Jaccard coefficient performances the ratio of overlapping between glacial lakes from SDGSAT-1 and Sentinel-2 MSI, which indicates the position bias between two lakes. Coregistration error between bands 2 and 7 of SDGSAT-1, band 2 of SDGSAT-1 and band 3 of Sentinel-2 is calculated by COSI-Corr software. And the correlation analysis between co⁃registration error and area error, Jaccard coefficient is employed in SPSS software. The results indicate that the decision tree based on Normalized Difference Water Index enables rapid extraction of glacial lake vector data from SDGSAT-1 multispectral imagery. The accuracy of glacial lakes on SDGSAT-1 is higher than those from Landsat 8 OLI but lower than those from Sentinel-2 MSI, with an average error of 16.6%. Glacial lakes in shadowed areas on imagery of SDGSAT-1 after atmospheric correction was more exactly outlined than that before, although there was 10% more error compared to other glacial lakes. The area error of glacial lake on SDGSAT-1 is mainly defined by co-registration error of bands 2 and 7 of SDGSAT-1, while the Jaccard coefficient is influenced by the error from both bands 2 and 7 of SDGSAT-1, and band 2 of SDGSAT-1 and band 3 of Sentinel-2. SDGSAT-1 multispectral data serves as a robust data source for studying glacial lakes. Although its accuracy of identifying supraglacial lakes on SDGSAT-1 MII is lower than for other lakes, SDGSAT-1 MII will be the potential data for researches of the identification of supraglacial lakes and the change of supraglacial lakes.

  • Jianfeng Jia, Qiyuan Wang, Xiao Wang, Yu Huan, He Ren, Li Li
    Remote Sensing Technology and Application. 2026, 41(1): 104-116. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0104

    Spartina alterniflora, as a typical invasive species in China's coastal wetlands, poses a severe threat to ecosystem structure and function due to its rapid expansion. There is an urgent need to establishan efficient, accurate, and operational large-scale monitoring system to support ecological risk assessment, invasive species control, and wetland conservation decision-making. Given the limitations of traditional monitoring methods—such as low efficiency and challenges in large-scale applications—and the constrained accuracy of remote sensing in complex environments, this study systematically reviews recent progress in remote sensing monitoring of S. alterniflora invasions, focusing on three key aspects: identification methods, spatiotemporal analysis, and ecological impact assessment.In terms of identification methods, remote sensing relies primarily on the unique spectral and phenological characteristics of S. alterniflora. The application of traditional machine learning and deep learning methods has significantly improved identification accuracy, while phenology-based strategies effectively mitigate interference from the "different objects with similar spectra" phenomenon. Numerous studies indicate that the spread of S. alterniflora along China's coast has undergone distinct stages—from scattered distribution to rapid expansion—with spatial patterns exhibiting clear regional differences. Its invasion systematically damages wetland ecosystems such as salt marshes, tidal flats, and mangroves, significantly compressing native vegetation habitats, degrading habitat quality, reducing waterbird habitat ranges, and altering tidal flat sedimentation processes. This leads to biodiversity loss, soil degradation, and ultimately undermines the stability and service functions of wetland ecosystems.Overall, while significant progress has been made in identification accuracy and understanding invasion mechanisms, challenges remain, including difficulties in identifying small patches, insufficient model generalizability, and inadequate synergistic application of multi-source data. Future research should integrate high spatiotemporal resolution and multi-source remote sensing data to enhance monitoring capabilities, develop transfer learning and few-shot learning methods to improve model generalizability, deepen the fusion of phenological, spectral, and texture features, and further elucidate the driving mechanisms and ecological effects of invasion. These efforts will provide scientific support for the control of invasive species in coastal wetlands and the maintenance of ecological security.

  • Mengjie REN, Hanqiu XU
    Remote Sensing Technology and Application. 2025, 40(4): 956-968. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0956

    The Tasseled Cap Transformation (TCT) is a widely used remote sensing image processing technique. For Landsat 8 satellite imagery, three TCT algorithms have been proposed by Baig et al., Zhai et al., and Liu et al., respectively. However, the consistency among these three algorithms remains unclear, leaving users uncertain about which one to choose. Additionally, while Zhai et al. provided an algorithm based on Surface Reflectance (SR) data, the other two algorithms are only applicable to Top of Atmosphere (TOA) reflectance data. It is thus essential to verify whether the TOA-based algorithms can be applied to SR data. To address these issues, three Landsat 8 images with different land cover types were selected, and three TCT algorithms were applied. The inversion results were quantitatively compared to identify differences among the algorithms. The results show that the Baig and Zhai algorithms exhibit the highest consistency, with an average R² of 0.974 4 and an average RMSE of 0.025 for the three components. In contrast, the inversion results of the Liu algorithm exhibit significant differences compared to those of the Baig and Zhai algorithms. The average R² values between Liu and Baig, and between Liu and Zhai, are 0.803 1 and 0.865 2, respectively, while the average RMSE values are 0.077 6 and 0.065 5, respectively. Therefore, the inversion results of Baig and Zhai are more comparable. Furthermore, applying the TOA-based TCT algorithms of Baig and Liu to SR data reveals substantial differences between the components derived from SR and TOA reflectance, with RMSE reaching 0.053 5 and an average |PC| of 146.07%. Thus, it is not recommended to use the TOA-based algorithms of Baig and Liu for TCT on SR data. In conclusion, the algorithm proposed by Zhai et al., which is applicable to both TOA and SR reflectance data, is recommended for Landsat 8 TCT applications.

  • Sining QIANG, Yingxin SHANG, Zhidan WEN, Ge LIU, Kaishan SONG
    Remote Sensing Technology and Application. 2025, 40(4): 886-899. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0886

    Colored Dissolved Organic Matter (CDOM) exhibits unique optical properties and significant advantages in remote sensing monitoring. However, notable differences exist in the optical characteristics of different CDOM types. This study systematically summarizes CDOM features in global water bodies and various lake types through literature review. This study demonstrates that models established based on aquatic optical properties under different natural geographical zones can more accurately identify the key factors for CDOM variation patterns. This research provides theoretical foundations for regional CDOM monitoring and water quality assessment through remote sensing techniques.

  • Zheng Wang, Zhihua Mao, Wencheng Wang, Qiping Zhang, Huan Mi, Tingting Sun, Jun Du, Chao Wang
    Remote Sensing Technology and Application. 2026, 41(1): 48-63. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0048

    Ocean color remote sensing chlorophyll a concentration data are of great significance for a wide range of scientific issues, such as global change and biogeochemical cycle studies. However, the existing operational remote sensing data on chlorophyll-a concentrations suffer from spatial incompleteness and temporal discontinuity,significantly limiting their application potential. Research shows that data reconstruction is the primary approach to address this issue. Based on recent research findings on ocean color remote sensing data reconstruction, this research summarizes the theoretical foundations and development history of data reconstruction methods. It particularly discusses the hot topics in chlorophyll-a concentration data reconstruction, including common datasets, methods, and major research areas. The paper also identifies existing challenges in chlorophyll-a concentration data reconstruction, highlighting critical issues such as data reconstruction in extremely data-scarce regions, the development of short-time scale data reconstruction methods, multivariate combined reconstruction methods, improvements in Empirical Orthogonal Function data interpolation, and the integration of remote sensing with numerical simulation for data reconstruction. The paper concludes by outlining future research directions in this field.

  • Qian WANG, Peng ZHANG, Na XU, Lin CHEN, Yanmeng BI, Ronghua WU, Jianguo LIU, Fuqi SI
    Remote Sensing Technology and Application. 2025, 40(4): 835-850. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0835

    The application of atmospheric composition data obtained from spaceborne remote sensors in climate and atmospheric environment research has promoted the rapid development of atmospheric composition remote sensing from visible, shortwave infrared to ultraviolet band, and from channel sensing to hyperspectral detection technology. The requirement for quantitative application of hyperspectral data is accurate spectral and radiometric calibration. Compared with the relatively mature calibration technology for visible and shortwave infrared remote sensors, calibration in ultraviolet band is significantly affected by the stability of the on-orbit calibration device, and atmospheric ozone absorption. Thus on-orbit calibration technology for ultraviolet hyperspectral remote sensing data is a challenging issue that urgently needs breakthrough. This paper presents the review made in on-orbit calibration methods for ultraviolet satellite remote sensors. It highlights the development of on-orbit spectral and radiometric calibration techniques, as well as alternative calibration approaches. The paper also compares the advantages and shortcomings of various calibration methods used in visible band remote sensing satellites, and analyzes the applicabilities and challenges of calibration in ultraviolet band. In light of the development of new-generation atmospheric composition remote sensors, the paper proposes major challenges that need to be solved for on-orbit calibration, with a focus on hyperspectral ultraviolet atmospheric composition remote sensing, which have important guidance for the improvement of ultraviolet spaceborne remote sensors and the enhancement of the calibration accuracy of ultraviolet remote sensors.

  • Qingwang WANG, Junlin OUYANG, Pengcheng JIN, Tao SHEN
    Remote Sensing Technology and Application. 2025, 40(4): 864-874. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0864

    This study proposes a novel method to joint utilization of visible and thermal infrared images from UAV perspectives. The method involves the development of a multimodal semantic segmentation model, termed CDFNet, which is designed based on cross-modal feature decoupling and attention refocusing. A cross-modal feature decoupling module is introduced to explicitly disentangle and enhance complementary discriminative features from different modalities, thereby improving the representational capacity of fused features in complex urban scenes. Furthermore, a focalizing attention decoder is incorporated to dynamically refine the attention scope towards small-scale objects during decoding, thereby effectively mitigating the interference from noisy backgrounds. Extensive experimentation on the Kust4K dataset demonstrates that CDFNet achieves mIoU improvements of 6.3% and 3.1% over the baseline and the current state-of-the-art multimodal method Sigma, respectively. Feature visualization and modality robustness evaluations further confirm that CDFNet yields more robust feature representations under low signal-to-noise conditions and significantly enhances segmentation accuracy for small targets in challenging urban road scenes from UAV perspectives.

  • He ZHANG, Peng GUO, Zhiqing PENG, Lu HU, Tianjie ZHAO
    Remote Sensing Technology and Application. 2025, 40(5): 1149-1161. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1149

    To monitor the spatiotemporal variations of soil moisture over the Tibetan Plateau—known as the "Roof of the World" and the "Water Tower of Asia"—in the early 21st century, this study evaluates multiple soil moisture products and adopts the AMSR-E/2 soil moisture dataset retrieved using the Multi-Channel Collaborative Algorithm (MCCA), which demonstrated the highest accuracy. Based on data from 2002 to 2022, we applied Sen’s slope estimator combined with the Mann–Kendall test to systematically analyze the spatiotemporal patterns of soil moisture changes and its relationship with precipitation across the plateau. The results show that the Tibetan Plateau has experienced a general wetting trend in the early 21st century, with the proportion of significantly increasing soil moisture trends (31.52%) far exceeding that of significantly decreasing trends (1.70%). Most river basins exhibit a pattern of “high increase in dry areas and low increase in wet areas”.Furthermore, notable differences exist in the trends among various river basins and monsoon zones. Precipitation is identified as a key driving factor influencing soil moisture changes on the Tibetan Plateau.

  • Haoming QIN, Kaishan SONG, Ge LIU, Zhuoshi LI, Chong FANG
    Remote Sensing Technology and Application. 2025, 40(4): 900-908. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0900

    In the past few decades, water bodies around the world have continued to suffer from systemic pollution and severe water quality deterioration. Total phosphorus is one of the important indicators for water quality evaluation and an important factor affecting water eutrophication and cyanobacteria bloom outbreaks. This paper discusses the relationship between total phosphorus and other optical water quality parameters, the remote sensing inversion of total phosphorus concentration in different water body types, the remote sensing algorithm of total phosphorus concentration, and the remote sensing inversion of total phosphorus concentration on different remote sensing platforms. Since the 1990s, there have been more than 300 documents on total phosphorus concentration inversion. In recent years, research hot spots have gradually focused on topics such as “remote sensing technology” and “machine learning”. For the study of inland lake water bodies, Landsat/TM and MODIS images are mainly used. Among them, the accuracy of models using the combination of green band, near-infrared band and mid-infrared band is generally higher. Observing the total phosphorus concentration of global lakes through satellite image data, it was found that the total phosphorus content of global lakes is generally on the rise, with the highest phosphorus content in Asian lakes, followed by South America, Africa and Europe. No significant increasing trend was found in Oceania. With the development of computer technology, machine learning algorithms have gradually become a current hot topic. Compared with traditional algorithms, models built using machine learning algorithms are more accurate. The random forest algorithm is widely used because the model it builds has higher accuracy than other machine learning algorithms. With the continuous development of research, the construction of a total phosphorus concentration model suitable for different water types is the general trend in the future, and the development of sensors with high spatial resolution and high temporal resolution is even more urgent.

  • Qiudong ZHAO, Rui HE, Zizhen JIN, Zhimin FENG
    Remote Sensing Technology and Application. 2025, 40(6): 1419-1433. https://doi.org/10.11873/j.issn.1004-0323.2025.6.1419

    Accurate inversion of Fractional Snow Cover (FSC) in forested areas is significant for hydrological process simulation, climate change projection and ecosystem management. This study proposed a hybrid machine learning model, RF_ART, based on the Random Forests (RF) algorithm and the Asymptotic Radiative Transfer (ART) model, aiming to improve the inversion accuracy of FSC in forested areas. The model integrated multiple environmental variables, including spectral characteristics, vegetation, terrain, angles, land surface temperature, and snow grain size. Experiments were conducted in the Altay region and the central-eastern Tianshan Mountains of Northern Xinjiang. The results showed that the average Root Mean Square Error (RMSE) of RF_ART in the training images was approximately 0.048 0, and the average RMSE in the testing images was approximately 0.096 6, which was significantly lower than those of the NDSI_FSC and NDFSI_FSC methods. Additionally, while the RMSEs of RF_ART and RF_FSC were similar, in testing images, RF_ART introduced physical constraints that enhanced the model's robustness, making it the preferred algorithm for FSC inversion in forested areas. Notably, in the predominantly deciduous forests, the RMSE of the RF_ART model gradually decreased with the incorporation of various variables. Moreover, under conditions of scarce data, the RF_ART model demonstrated strong robustness and application potential. By combining hybrid machine learning models with multi-source remote sensing data, this study provides an important reference for the inversion of FSC in forested areas.

  • Maochi XIAO, Na LIN, Shuangtao LI, Hailin QUAN, Libin TAN
    Remote Sensing Technology and Application. 2025, 40(5): 1323-1332. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1323

    Accurate farmland information is of great significance for ensuring national food security. Traditional farmland extraction methods have limitations when dealing with increasingly complex remote sensing images. The development of deep learning has brought new approaches for farmland extraction. However, the classic DeepLabV3+ network has problems such as a large number of training parameters, less than ideal image segmentation accuracy, and poor generalization ability in practical applications. To address these issues, this study proposes a lightweight DeepLabV3+ network integrated with an attention mechanism. In this network, the Xception, which is the main structure of DeepLabV3+, is replaced with MobileNetV2 to reduce the number of training parameters. The channel attention mechanism SENet is introduced to improve the segmentation accuracy. The loss function is replaced with the Hybrid function to enhance the generalization ability of the model.The research results show that: (1) After lightweighting, the average training time of the network is reduced from 7.45 minutes to 1.86 minutes, and the model training parameters are decreased from 208.7 MB to 24.73 MB; (2) The precision, recall, and Mean Intersection over Union (MIoU) of the model reach 90.26%, 90.08%, and 81.58% respectively, all of which are superior to those of other comparative models; (3) The absolute value of the relative error of the extraction results in Gaomiao Village, Yongchuan District, is 7.95%, which performs better than the DeepLabV3+ network model. In conclusion, the improved DeepLabV3+ network can effectively improve the farmland extraction effect. While reducing the number of parameters and increasing the operation speed, it also improves the extraction accuracy. It has certain universality and transferability and can provide accurate spatial distribution information of farmland for agricultural planning.

  • Lin Wang, Wenjia Wang, Fei Tang
    Remote Sensing Technology and Application. 2026, 41(1): 34-47. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0034

    Frequent extreme high-temperature weather under the background of urbanization and climate warming poses a threat to the health of urban residents. The Park Cooling Effect (PCE) is vital for alleviating these adverse effects. However, in land-scarce urban areas, it is unrealistic to expand the size of parks without limits, and maximizing the cooling effect per unit area becomes an urgent issue.Taking China’s hottest “furnace city”, Fuzhou, as the study area, this research quantifies PCE using three indicators: cooling amplitude (∆Tmax) , cooling distance (L∆max) and cooling gradient (Gtemp).It calculates the PCE indicators of 50 urban parks within the city and analyzes the influencing factors from the perspectives of external park morphology and internal landscape patch characteristics. Results reveal that: ①Among 50 parks, 42 exhibit a PCE, whereas 8 do not; ②Larger parks are not always better; it is crucial to consider both external morphological and internal patch attributes; ③Regarding external morphology, parks with simple and regular boundary shapes are more conducive to cooling effects; ④With regard to the internal patch characteristics of the parks, low impervious surface proportions, high proportions of water bodies and vegetation, and complex patch morphologies enhance PCE, while excessively high edge densities and landscape fragmentation weaken it. Therefore, efforts should be made to maintain the continuity and integrity of vegetation and water body coverage, design diverse and multi-tiered vegetation boundary structures, or leverage terrain changes to increase the vertical complexity of impervious surface boundaries to optimize cooling and alleviate urban heat island effects.

  • Weiwei Zhang, Zongyao Sun, Ruoyu Jia, Dongrui Han, Xinliang Xu, Jiawen Liu, Hui Cong, Zhi Qiao
    Remote Sensing Technology and Application. 2026, 41(1): 64-75. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0064

    In the context of global climate warming and rapid urbanization,the Urban Heat Island (UHI) effect exacerbates population heat exposure risk,accurately identifying high-risk areas of population heat exposure is crucial for adapting to and mitigating the threats posed by high temperatures.This study focuses on the area within the sixth ring road of Beijing,from the perspective of Local Climate Zones (LCZ),analyzing the temporal and spatial variations of Surface Urban Heat Island Intensity (SUHII) in different LCZs during summer,based on ECOSTRESS Land Surface Temperature(LST) data and Tencent mobility population data. The study also evaluates the daily dynamic changes in population heat exposure under different SUHII levels. The results show:①During the day,significant differences in SUHII are observed across different LCZ types. Except for LCZ 9 (Sparsely built),built-up LCZs,as well as LCZ E (Bare rock or paved) and LCZ F (Bare soil or sand),exhibit characteristics of heat sources,while other types are heat sinks.At night,the SUHII differences between LCZs decrease,and the heat sink effect of LCZ A (Dense trees) and LCZ B (Scattered trees) weakens,while LCZ G (Water) shifts from a heat sink to a heat source.②Population heat exposure is lowest between 6—7 AM and peaks between 10—11 AM.Built-up LCZs (except LCZ 9),along with LCZ E and F,show population heat exposure risk. Within the fourth ring road,where buildings are dense and population density is high,population heat exposure is particularly prominent.③When SUHII exceeds 2 ℃,the risk of population heat exposure significantly increases,particularly in areas with high building density and low green coverage,controlling SUHII to stay within 2 ℃ can effectively reduce the risk of population heat exposure. This study provides a theoretical basis and practical support for enhancing urban livability,improving living environments,and formulating urban heat risk control strategies.

  • Feng Zhao, Jinguo Yuan, Jiayi Jin, Zhuolin Li, Xinjiao Wu
    Remote Sensing Technology and Application. 2026, 41(2): 291-304. https://doi.org/10.11873/j.issn.1004-0323.2026.2.0291

    Aboveground biomass of winter wheat is an important physiological indicator reflecting crop growth status and yield potential. Accurate and efficient monitoring of biomass is essential for implementing precision agricultural management, optimizing fertilization and irrigation strategies, and ensuring food security. In this study, a field experiment was conducted in the southern part of Gaocheng District, Shijiazhuang, Hebei Province, China. The aboveground biomass and canopy hyperspectral reflectance were measured at regreening stage, jointing stage, and grain filling stage of winter wheat. Sensitive wavelengths significantly correlated with aboveground biomass were preliminarily screened from the original spectra, multiplicative scatter correction spectra, First Derivative(FD) spectra, and continuum-removed spectra of winter wheat at different growth stages using Pearson correlation analysis. Based on this, feature band selection was performed using the Competitive Adaptive Reweighted Sampling (CARS) algorithm and the Successive Projections Algorithm (SPA), and biomass estimation models were then constructed by integrating the selected features with three machine learning methods: Partial Least Squares Regression (PLSR), Gaussian Process Regression (GPR), and Support Vector Machine (SVM). The results indicated that: (1) Spectral data processed using the first derivative method overall outperformed other spectral preprocessing approaches in both correlation analysis and machine learning modeling. (2) Both CARS algorithm and SPA effectively eliminated redundant information in hyperspectral data, reducing data dimensionality. Among them, SPA showed more prominent performance in simplifying bands, but the model estimation accuracy based on CARS algorithm was higher than that of SPA. The highly sensitive feature bands selected by both algorithms, which were mainly concentrated in red-edge and near-infrared spectral regions, were strongly related to aboveground biomass. (3) At different growth stages, the FD-CARS-GPR model demonstrated superior overall performance, exhibiting good adaptability and robustness. Particularly, the model achieved the highest estimation accuracy at jointing stage, with validation set R² of 0.802, RMSE of 50.97 g/m2, and RPD of 2.30, followed by regreening stage, and the lowest at filling stage. The aboveground biomass estimation model for winter wheat, developed based on first derivative spectra in combination with the CARS algorithm and constructed using GPR, demonstrated high accuracy and stability. It is suitable for quantitative estimation of aboveground biomass across different growth stages of winter wheat, providing reliable technical support for growth monitoring and precision agricultural management.

  • Shiwei LIU, Kaishan SONG, Chunlan XIONG, Ge LIU, Hui TAO, Yingxin SHANG, Zhidan WEN
    Remote Sensing Technology and Application. 2025, 40(4): 875-885. https://doi.org/10.11873/j.issn.1004-0323.2025.4.0875

    Since the Industrial Revolution, both natural and anthropogenic factors have contributed to the increase in greenhouse gas emissions, resulting in a series of environmental issues such as global warming.The global oceans have been confirmed as the primary sink for atmospheric CO2, capable of absorbing approximately one-fourth of anthropogenic CO2 emissions. In contrast, inland water bodies, acting as a source of atmospheric CO2, emit greenhouse gases equivalent to nearly 20% of global fossil fuel CO2 emissions.The accurate estimation of surface water CO2 partial pressure (pCO2) is a prerequisite for studying the carbon flux and source-sink patterns in various water bodies. Since the 1990s, researchers have accumulated a substantial amount of measured pCO2 values. This solid dataset has laid the foundation for a deeper understanding of the influencing mechanisms of water body pCO2 and the development of estimation models.Remote sensing, with its capability for large-scale and long-term observations, is currently the mainstream method for estimating water body pCO2. This involves inferring pCO2 through the remote sensing retrieval of relevant environmental variables. This paper begins by elucidating the environmental variables and relevant physicochemical processes that influence water body pCO2, providing the theoretical foundation for parameterizing pCO2. Subsequently, it summarizes remote sensing retrieval algorithms for pCO2 in different types of water bodies. While these algorithms have matured in studies over the open oceans and developed a series of empirical or semi-analytical models for nearshore waters, there is relatively less research on remote sensing retrieval algorithms for inland water bodies. This scarcity can be attributed to the complex optical properties and spatiotemporal variability of pCO2 in inland water bodies. Given the significance of inland water bodies in the global carbon cycle, researchers should pay greater attention to remote sensing estimation studies of pCO2 in these inland water systems.

  • Xinyuan CHEN, Bo WANG, Mengmeng WANG
    Remote Sensing Technology and Application. 2025, 40(5): 1301-1313. https://doi.org/10.11873/j.issn.1004-0323.2025.5.1301

    Soil erosion evaluation based on soil erosion estimation model requires high-quality input data, including land use classification data, however, the traditional land use classification method has the problems of low efficiency and the phenomenon of “heterogeneity and homogeneity” when facing the task of multi-class classification. Therefore, this study tries to apply deep learning to soil erosion evaluation, adopts the semantic segmentation model with Swin Transformer as the backbone network to realize high-precision land use classification, and applies the classification results to the RUSLE model to evaluate the degree of soil erosion. It is verified that the overall accuracy of the semantic segmentation model reaches 95% and has good generalization performance. The results of soil erosion evaluation show that soil erosion in Poyang County is dominated by light erosion, and spatially presents the distribution characteristics of band and point. The results show that land use classification based on deep learning has a wider application prospect in the field of soil erosion evaluation.

  • Qianyu Du, Qian Shen, Hongchun Peng, Yue Yao, Tengfei Long, Linlin Lu, Bo Shu
    Remote Sensing Technology and Application. 2026, 41(1): 76-89. https://doi.org/10.11873/j.issn.1004-0323.2026.1.0076

    Urban informal settlements are a global common phenomenon in the process of rapid urbanization. The research on their optical remote sensing identification is of great significance for achieving the 11th Sustainable Development Goal of sustainable cities and communities. Based on the statistics of relevant domestic and foreign literature from 2001 to 2024, this paper sorts out and analyzes the data sources and spatial resolutions of optical remote sensing images of urban informal settlements, single-class feature classification and multi-source feature fusion classification, as well as the identification methods and their advantages and disadvantages. The results show that data sources are classified into three categories according to spatial resolution: ultra-high/high, medium, and low; single-class features or data sources are classified into optical image features such as spectral, texture, geometry and context, and auxiliary data features such as GIS data; multi-source feature fusion is classified into three types: feature-level, data-level and decision-level. Compared with deep learning, traditional identification methods such as pixel-based and object-based methods have limitations such as weak adaptability and low recognition efficiency. Deep learning methods, with their strong feature extraction capabilities and good generalization ability, have broad prospects in the remote sensing identification of large-scale and long-term informal settlements. This paper aims to provide a reference for the future remote sensing identification of urban informal settlements and promote the construction and development of sustainable cities.

  • Ruozhao Deng, Kunlun Xiang, Dongyang Fu, Xi Lu, Rui Yu, Yuanhong Li, Xinggui Wu
    Remote Sensing Technology and Application. 2026, 41(2): 372-381. https://doi.org/10.11873/j.issn.1004-0323.2026.2.0372

    The Guangdong-Hong Kong-Macao Greater Bay Area (GBA) stands as a paramount symbol of China's reform and opening-up, characterized by its exceptional economic vitality. Understanding its spatiotemporal urbanization patterns is crucial for deciphering the evolution of mega-city clusters and their interplay with economic development. To address the inconsistencies between DMSP/OLS (1992—2012) and NPP/VIIRS (2012—2021) nighttime light data, this study constructed a continuous, long-term dataset by evaluating two integration approaches: simulating DMSP/OLS from NPP/VIIRS and vice versa. The optimal method was selected based on the performance of linear regression models with Gross Domestic Product (GDP), resulting in a consistent nighttime light dataset (1992—2021) for the GBA that shows a higher consistency with socioeconomic indicators. Our analysis revealed that: (1) From 1992 to 2021, the nighttime light intensity in the GBA showed a continuous increasing trend, with distinct spatial dynamics across three periods: initial rapid growth was concentrated in the core urban areas of Guangzhou, Hong Kong, and Macao (1992—2001); subsequently, the growth hotspot diffused into the suburbs (2002—2011); and finally, it expanded further into county-level towns and rural areas (2012—2021). (2) The expansion rate of urban built-up areas was higher in the northern and western parts of the GBA than in the eastern and southern parts. Moreover, the primary direction of urban expansion underwent a notable shift, transitioning from a “southeast-northwest” orientation to a predominantly “east-west” orientation.