A review of the satellite remote sensing techniques for assessment of runoff and sediment in soil erosion

Alewell, C., Borrelli, P., Meusburger, K., Panagos, P., 2019. Using the USLE: Chances, challenges and limitations of soil erosion modelling. International Soil and Water Conservation Research, 7, 3, 203–225. Search in Google Scholar

Arnold, J.G., 1990. SWRRB; A Basin Scale Simulation Model for Soil and Water Resources Management. Texas A & M University Press, 140 p. Search in Google Scholar

Avand, M., Mohammadi, M., Mirchooli, F., Kavian, A., Tiefenbacher, J.P., 2023. A new approach for smart soil erosion modeling: integration of empirical and machinelearning models. Environmental Modeling & Assessment, 28, 1, 145–160. Search in Google Scholar

Bagarello, V., Ferro, V., Giordano, G., Mannocchi, F., Todisco, F., Vergni, L., 2018. Statistical check of USLE‐M and USLEMM to predict bare plot soil loss in two Italian environments. Land Degradation & Development, 29, 8, 2614–2628. Search in Google Scholar

Batista, P.V., Davies, J., Silva, M.L., Quinton, J.N., 2019. On the evaluation of soil erosion models: Are we doing enough? Earth-Science Reviews, 197, 102898. Search in Google Scholar

Beasley, D.B., Huggins, L.F., Monke, E.J., 1980. ANSWERS: A model for watershed planning. Transactions of the ASAE, 23, 4, 938–944. Search in Google Scholar

Ben-Dor, E., Chabrillat, S., Demattê, J.A.M., Taylor, G.R., Hill, J., Whiting, M.L., Sommer, S., 2009. Using imaging spectroscopy to study soil properties. Remote Sensing of Environment, 113, Suppl. 1, S38–S55. Search in Google Scholar

Ben-Dor, E., Demattê, J.A.M., 2015. Remote sensing of soil in the optical domains. In: Thenkabail, P.S.: Remote Sensing Handbook, vol II: Land Resources Monitoring, Modeling, and Mapping with Remote Sensing. CRC Press, pp. 733–788. Search in Google Scholar

Benavidez, R., Jackson, B., Maxwell, D., Norton, K., 2018. A review of the (Revised) Universal Soil Loss Equation ((R) USLE): with a view to increasing its global applicability and improving soil loss estimates. Hydrology and Earth System Sciences, 22, 11, 6059–6086. Search in Google Scholar

Bezak, N. et al., 2021. Soil erosion modelling: A bibliometric analysis. Environmental Research, 197, 111087. Search in Google Scholar

Bilous, A., Myroniuk, V., Holiaka, D., Bilous, S., See, L., Schepaschenko. D., 2017. Mapping growing stock volume and forest live biomass: a case study of the Polissya region of Ukraine. Environmental Research Letters, 12, 10, 105001. Search in Google Scholar

Borrelli, P. et al., 2021. Soil erosion modelling: A global review and statistical analysis. Science of The Total Environment, 780, 146494. Search in Google Scholar

Brazier, R.E., Beven, K.J., Anthony, S.G., Rowan, J.S., 2001. Implications of model uncertainty for the mapping of hillslope‐scale soil erosion predictions. Earth Surface Processes and Landforms, 26, 12, 1333–1352. Search in Google Scholar

Cai, J., Ren, Z., Li, Y., 2002. Discussion on related technical issues of remote sensing investigation on soil erosion. Bulletin of Soil and Water Conservation, 22, 6, 45–47. Search in Google Scholar

Chen, R. et al., 2024. Towards accurate mapping of loess waterworn gully by integrating google earth imagery and DEM using deep learning. International Soil and Water Conservation Research, 12, 1, 13–28. Search in Google Scholar

De Jong, S. et al., 1999. Regional assessment of soil erosion using the distributed model SEMMED and remotely sensed data. Catena, 37, 3–4, 291–308. Search in Google Scholar

De Roo, A., Wesseling, C., Ritsema, C., 1996. LISEM: a singleevent physically based hydrological and soil erosion model for drainage basins. I: theory, input and output. Hydrological Processes, 10, 8, 1107–1117. Search in Google Scholar

De Sy, V., Herold, M., Achard, F., Beuchle, R., Clevers, J.G.P.W., Lindquist, E., Verchot, L., 2015. Land use patterns and related carbon losses following deforestation in South America. Environmental Research Letters, 10, 12, 124004. Search in Google Scholar

De Vente, J., Poesen, J., Verstraeten, G., Govers, G., Vanmaercke, M., Van Rompaey, A., Arabkhedri, M., Boix-Fayos, C., 2013. Predicting soil erosion and sediment yield at regional scales: where do we stand? Earth-Science Reviews, 127, 16–29. Search in Google Scholar

Ding, W. L., Xia, J., She, D.X., Zhang, X.Y., Chen, T., Huang, S., Zheng, H.Y., 2023. Assessing multivariate effect of best management practices on non-point source pollution management using the coupled Copula-SWAT model. Ecological Indicators, 153, 110393. Search in Google Scholar

El Haj Tahir, M., Kääb, A., Xu, C.-Y., 2010. Identification and mapping of soil erosion areas in the Blue Nile, Eastern Sudan using multispectral ASTER and MODIS satellite data and the SRTM elevation model. Hydrology and Earth System Sciences, 14, 7, 1167–1178. Search in Google Scholar

Elnaggar, A.A., Noller, J.S., 2010. Application of remotesensing data and decision-tree analysis to mapping saltaffected soils over large areas. Remote Sensing, 2, 1, 151–165. Search in Google Scholar

Elyagoubi, S., Mezrhab, A., 2022. Using GIS and remote sensing for mapping land sensitivity to wind erosion hazard in the middle Moulouya Basin (North-Eastern Morocco). Journal of Arid Environments, 202, 104753. Search in Google Scholar

Fawzy, H.E.-D., Basha, A.M., Botross, M.N., 2020. Estimating a mathematical formula of soil erosion under the effect of rainfall simulation by digital close range photogrammetry technique. Alexandria Engineering Journal, 59, 6, 5079–5097. Search in Google Scholar

Feng, J. X., Chen G.K., Zuo L.J., Wen Q.K., Zhao J.J., Wang, Y.W., 2022. Quantitative evaluation and characteristic analysis of cultivated land erosion in mountain area using GF- 6 WFV and CSLE model. Transactions of the Chinese Society of Agricultural Engineering, 38, 21, 169–179. Search in Google Scholar

Flanagan, D., Frankenberger, J., Ascough II, J., 2012. WEPP: Model use, calibration, and validation. Transactions of the ASABE, 55, 4, 1463–1477. Search in Google Scholar

Fu, B., Merritt, W.S., Croke, B.F.W., Weber, T.R., Jakeman, A.J., 2019. A review of catchment-scale water quality and erosion models and a synthesis of future prospects. Environmental Modelling & Software, 114, 75–97. Search in Google Scholar

Fu, B., Zhao, W., Chen, L., Lv, Y., wang, D., 2006. Multi-scale soil erosion evaluation index. Chinese Science Bulletin, 51, 16, 1936–1943. DOI: https://doi.org/10.1360/972005-1288 Search in Google Scholar

Gelder, B. et al., 2018. The Daily Erosion Project–daily estimates of water runoff, soil detachment, and erosion. Earth Surface Processes and Landforms, 43, 5, 1105–1117. Search in Google Scholar

Gironás, J., Roesner, L.A., Rossman, L.A., Davis, J., 2010. A new applications manual for the Storm Water Management Model (SWMM). Environmental Modelling & Software, 25, 6, 813–814. Search in Google Scholar

Govers, G., 2010. Misapplications and misconceptions of erosion models. In: Morgan, R.P.C., Nearing, M.A. (Eds.): Handbook of Erosion Modelling. Blackwell Publishing Ltd. Search in Google Scholar

Guo, C., Xie, L., ZHu, M., Sun, J., LIU, J., 2013. Research on soil erosion prediction model based on BP Neural Network. Journal of Shenyang Aricultural University, 44, 4, 495–497. Search in Google Scholar

Guohong, S., Dongwei, L., 2010. Study on Soil Erosion Dynamic Monitoring System Base GIS in Chongqing, China. Disaster Advances, 3, 4, 47–50. Search in Google Scholar

Hong, H., Huang, J., Zhang, L., Du, P., 2005. Modelling pollutant loads and management alternatives in Jiulong River watershed with AnnAGNPS. Environmental Science, 26, 4, 63–69. Search in Google Scholar

Hu, Y., Tian, G., Mayer, A.L., He, R., 2015. Risk assessment of soil erosion by application of remote sensing and GIS in Yanshan Reservoir catchment, China. Natural Hazards, 79, 277–289. Search in Google Scholar

Huang, H., Ji, X.L., Xia, F., Huang, S.H., Shang, X., Chen, H., Zhang, M.H., Dahlgren, R.A., Mei, K., 2020. Multivariate adaptive regression splines for estimating riverine constituent concentrations. Hydrological Processes, 34, 5, 1213–1227. Search in Google Scholar

Huang, S., Zhong, S., Xu, M., 2001. Categorical model of estimating soil erosion based on GIS – A case study in Xihanshui watershed. Journal of Soil and Water Conservation, 02, 105–107+116. https://doi.org/10.13870/j.cnki.stbcxb.2001.02.029 Search in Google Scholar

Hussin, Y.A., Gilani, H., van Leeuwen, L., Murthy, M.S.R., Shah, R., Baral, S., Tsendbazar, N.-E., Shrestha, S., Shah, S.K., Qamer, F.M., 2014. Evaluation of object-based image analysis techniques on very high-resolution satellite image for biomass estimation in a watershed of hilly forest of Nepal. Applied Geomatics, 6, 59–68. Search in Google Scholar

Islam, F., Ahmad, M.N., Janjuhah, H.T., Ullah, M., Islam, I.U., Kontakiotis, G., Skilodimou, H.D., Bathrellos, G.D., 2022. Modelling and mapping of soil erosion susceptibility of Murree, Sub-Himalayas using GIS and RS-based models. Applied Sciences, 12, 23, 12211. Search in Google Scholar

Islam, T., Srivastava, P.K., Dai, Q., Gupta, M., Zhuo, L., 2015. Rain rate retrieval algorithm for conical-scanning microwave imagers aided by random forest, RReliefF, and multivariate adaptive regression splines (RAMARS). IEEE Sensors Journal, 15, 4, 2186–2193. Search in Google Scholar

Jakeman, A., Croke, B., Fu, B., 2019. Uncertainty in environmental water quality modelling: where do we stand? In: Mannina, G. (Ed.): New Trends in Urban Drainage Modelling. Springer, Cham, pp. 557–565. Search in Google Scholar

Jetten, V., Govers, G., Hessel, R., 2003. Erosion models: quality of spatial predictions. Hydrological Processes, 17, 5, 887–900. Search in Google Scholar

Johanson, R.C., Imhoff, J.C., Davis, H.H., 1980. Users manual for hydrological simulation program-Fortran (HSPF). US Environmental Protection Agency, Washington, D.C. EPA/600/9-80/015. Search in Google Scholar

Kandel, D., Western, A., Grayson, R., Turral, H.J.H.P., 2004. Process parameterization and temporal scaling in surface runoff and erosion modelling. Hydrological Processes, 18, 8, 1423–1446. Search in Google Scholar

Karlson, M., Reese, H., Ostwald, M.J.S., 2014. Tree crown mapping in managed woodlands (parklands) of semi-arid West Africa using WorldView-2 imagery and geographic object based image analysis. Sensors, 14, 12, 22643–22669. Search in Google Scholar

Ke, Z., Yongqing, Y., Yanna, Z., Ru, M., 2021. Review of land use classification methods based on optical remote sensing images. Science Technology and Engineering, 21, 32, 13603–13613. Search in Google Scholar

Khosravi, K. et al., 2023. Soil water erosion susceptibility assessment using deep learning algorithms. Journal of Hydrology, 618, 129229. Search in Google Scholar

Kinnell, P., 2016. Comparison between the USLE, the USLE-M and replicate plots to model rainfall erosion on bare fallow areas. Catena, 145, 39–46. Search in Google Scholar

Knisel, W., Douglas-Mankin, K., 2012. CREAMS/GLEAMS: Model use, calibration, and validation. Transactions of the ASABE, 55, 4, 1291–1302. Search in Google Scholar

Lee, Y., Han, D., Ahn, M.-H., Im, J., Lee, S.J., 2019. Retrieval of total precipitable water from Himawari-8 AHI Data: A comparison of random forest, extreme gradient boosting, and deep neural network. Remote Sensing, 11, 15, 1741. Search in Google Scholar

Li, G., Wang, G., Feng, J., Zheng, X., 2003. The present advance and trend of study on the model of soil erosion. Journal of Taiyuan University of Technology, 34, 1, 99–101. Search in Google Scholar

Li, J., Pei, Y.Q., Zhao, S.H., Xiao, R.L., Sang, X., Zhang, C.Y., 2020. A review of remote sensing for environmental monitoring in China. Remote Sensing, 12, 7, 1130. Search in Google Scholar

Li, Z.-A., Yang, Q., Gao, Y., Yan, M., Ceng, G., 2008. Remote sensing monitoring for soil erosion and its thinking. Science of Soil and Water Conservation, 6, 3, 7–12. Search in Google Scholar

Li, Z., Xue, W., Winijkul, E., Shrestha, S., 2023. Spatio-temporal dynamics of non-point source pollution in Jiulong River basin (China) using the Soil & Water Assessment Tool model in combination with the GeoSOS-FLUS model. Water, 15, 15, 2763. Search in Google Scholar

Liang, S., Fang, H., 2021. Quantitative analysis of driving factors in soil erosion using geographic detectors in Qiantang River catchment, Southeast China. Journal of Soils and Sediments, 21, 134–147. Search in Google Scholar

Lin, C., Zhou, S.-L., Wu, S.-H., Zhu, Q., Dang, Q., 2014. Spectral response of different eroded soils in subtropical china: A case study in Changting County, China. Journal of Mountain Science, 11, 697–707. Search in Google Scholar

Lin, C., Zhou, S.-L., Wu, S.-H., 2013. Using hyperspectral reflectance to detect different soil erosion status in the Subtropical Hilly Region of Southern China: a case study of Changting, Fujian Province. Environmental Earth Sciences, 70, 1661–1670. Search in Google Scholar

Liu, B., Zhang, K., Xie, Y., 2002. An empirical soil loss equation. In: Proceedings of the 12th International Soil Conservation Organization Conference, Beijing, China, pp. 21–25. Search in Google Scholar

Liu, E. et al., 2018. Comparison of fusion algorithms for gf-1 data from extracted of distribution information on production and construction projects. Journal of Soil and Water Conservation, 3, 358–363. Search in Google Scholar

Luo, J., 2000. Remote-sensing intelligent geo-interpretation model and its geo-cognition issue. Progress in Geography, 19, 4, 289–296. Search in Google Scholar

Man, P., Zhangshu, W., Wangrang, H., Cangli, P., Yangjiu, C., 2016. Analysis of Erosion Gully Information Extraction Based on Multi-resource Remote Sensing Images. Geography and Geo-information Science, 32, 1, 90–94. Search in Google Scholar

Merritt, W.S., Letcher, R.A., Jakeman, A.J., 2003. A review of erosion and sediment transport models. Environmental Modelling & Software, 18, 8–9, 761–799. Search in Google Scholar

Mishra, S.K., Singh, V., 2003. Soil Conservation Service Curve Number (SCS-CN) Methodology. Water Science and Technology Library, vol 42. Springer, Dordrecht. Search in Google Scholar

Misra, R., Rose, C., 1996. Application and sensitivity analysis of process‐based erosion model GUEST. European Journal of Soil Science, 47, 4, 593–604. Search in Google Scholar

Moayedi, H., Ahmadi Dehrashid, A., Nguyen Le, B., 2024. A novel problem-solving method by multi-computational optimisation of artificial neural network for modelling and prediction of the flow erosion processes. Engineering Applications of Computational Fluid Mechanics, 18, 1, 2300456. Search in Google Scholar

Mohammed, S., Al-Ebraheem, A., Holb, I.J., Alsafadi, K., Dikkeh, M., Pham, Q.B., Linh, N.T.T., Szabo, S., 2020. Soil management effects on soil water erosion and runoff in central Syria – A comparative evaluation of general linear model and random forest regression. Water, 12, 9, 2529. Search in Google Scholar

Morgan, R., Quinton, J.N., Smith, R.E., Govers, G., Poesen, J.W.A., Auerswald, K., Chisci, G., Torri, D., Styczen, M.E., 1998. The European Soil Erosion Model (EUROSEM): a dynamic approach for predicting sediment transport from fields and small catchments. Earth Surface Processes and Landforms, 23, 6, 527–544. Search in Google Scholar

Ni, G., 2003. Vegetation index and its advances. Journal of Arid Meteorology, 21, 4, 71–75. Search in Google Scholar

Niu, J., 2015. Review of research progress in soil erosion prediction model. China Population, Resources and Environment, S2, 386–389. Search in Google Scholar

Pampalone, V., Nicosia, A., Palmeri, V., Serio, M.A., Ferro, V., 2023. Rill and interrill soil loss estimations using the USLEMB equation at the Sparacia Experimental Site (South Italy). Water, 15, 13, 2396. Search in Google Scholar

Patil, R., Sharma, S., Tignath, S., 2015. Remote sensing and GIS based soil erosion assessment from an agricultural watershed. Arabian Journal of Geosciences, 8, 6967–6984. Search in Google Scholar

Peleg, N., Skinner, C., Ramirez, J.A., Molnar, P., 2021. Rainfall spatial-heterogeneity accelerates landscape evolution processes. Geomorphology, 390, 107863. Search in Google Scholar

Pengra, B., Long, J., Dahal, D., Stehman, S.V., Loveland, T.R., 2015. A global reference database from very high resolution commercial satellite data and methodology for application to Landsat derived 30 m continuous field tree cover data. Remote Sensing of Environment, 165, 234–248. Search in Google Scholar

Renard, K.G., Foster, G.R., Weesies, G.A., Porter, J.P., 1991. RUSLE: Revised universal soil loss equation. Journal of Soil and Water Conservation, 46, 1, 30–33. Search in Google Scholar

Sadeghi, S., Gholami, L., Khaledi Darvishan, A., Saeidi, P., 2014. A review of the application of the MUSLE model worldwide. Hydrological Sciences Journal, 59, 2, 365–375. Search in Google Scholar

Saha, S., Sarkar, R., Thapa, G., Roy, J., 2021. Modeling gully erosion susceptibility in Phuentsholing, Bhutan using deep learning and basic machine learning algorithms. Environmental Earth Sciences, 80, 1–21. Search in Google Scholar

Sahour, H., Gholami, V., Vazifedan, M., Saeedi, S., 2021. Machine learning applications for water-induced soil erosion modeling and mapping. Soil and Tillage Research, 211, 105032. Search in Google Scholar

Schepaschenko, D., See, L., Lesiv, M., Bastin, J.-F., Mollicone, D., Tsendbazar, N.-E., Bastin, L., McCallum, I., Bayas, J.C.L., Baklanov, A., Perger, C., Dürauer, M., Fritz, S., 2019. Recent advances in forest observation with visual interpretation of very high-resolution imagery. Surveys in Geophysics, 40, 839–862. Search in Google Scholar

Shi, F., Zhang, F., Shen, N., Yang, M., 2024. Quantifying interactions between slope gradient, slope length and rainfall intensity on sheet erosion on steep slopes using Multiple Linear Regression. Science of the Total Environment, 908, 168090. Search in Google Scholar

Shou, C., Du, H., Liu, X., 2019. Research progress of source and mechanism of agricultural non-point source pollution in China. Applied Ecology and Environmental Research, 17(5). Search in Google Scholar

Song, Y., 2006. Evolution of research and development direction about models of soil erosion. Shanxi Hydrotechnics, 03, 39–41. Search in Google Scholar

Sun, F., Hao, F., 2004. Research on non-point source pollution load calculation of Guanting Reservoir Watershed based on GIS. Beijing Water, 01, 16–18. Search in Google Scholar

Tamanna, M., Pradhanang, S.M., Gold, A.J., Addy, K., Vidon, P.G., Bingner, R.L., 2020. Evaluation of AnnAGNPS model for runoff simulation on watersheds from glaciated landscape of USA Midwest and Northeast. Water, 12, 12, 3525. Search in Google Scholar

Vanmaercke, M., Poesen, J., Maetens, W., de Vente, J., Verstraeten, G., 2011. Sediment yield as a desertification risk indicator. Science of the Total Environment, 409, 9, 1715–1725. Search in Google Scholar

Vrieling, A., 2006. Satellite remote sensing for water erosion assessment: A review. Catena, 65, 1, 2–18. Search in Google Scholar

Vu, D.T., Tran, X.-L., Cao, M.-T., Tran, T.C., Hoang, N.-D., 2020. Machine learning based soil erosion susceptibility prediction using social spider algorithm optimized multivariate adaptive regression spline. Measurement, 164, 108066. Search in Google Scholar

Wainwright, J., Parsons, A.J., Müller, E.N., Brazier, R.E., Powell, D.M., Fenti, B., 2008. A transport‐distance approach to scaling erosion rates: 1. Background and model development. Earth Surface Processes and Landforms, 33, 5, 813–826. Search in Google Scholar

Wang, H., Magagi, R., Goïta, K., Trudel, M., McNairn, H., Powers, J., 2019. Crop phenology retrieval via polarimetric SAR decomposition and Random Forest algorithm. Remote Sensing of Environment, 231, 111234. Search in Google Scholar

Wang, J., Lu, P.D., Valente, D., Petrosillo, I., Babu, S., Xu, S.Y., Li, C.C., Huang, D.L., Liu, M.Y., 2022. Analysis of soil erosion characteristics in small watershed of the loess tableland Plateau of China. Ecological Indicators, 137, 108765. Search in Google Scholar

Wang, L., Sousa, W.P., Gong, P., Biging, G.S., 2004. Comparison of IKONOS and QuickBird images for mapping mangrove species on the Caribbean coast of Panama. Remote Sensing of Environment, 91, 3–4, 432–440. Search in Google Scholar

Wang, Y., Zhang, Y., Chen, H., 2023. Gully erosion susceptibility prediction in Mollisols using machine learning models. Journal of Soil and Water Conservation, 78, 5, 385–396. Search in Google Scholar

Wei, C.W., Huang, J.F., Mansaray, L.R., Li, Z.H., Liu, W.W., Han, J.H., 2017. Estimation and mapping of winter oilseed rape LAI from high spatial resolution satellite data based on a hybrid method. Remote Sensing, 9, 5, 488. Search in Google Scholar

Wei, H., Zhao, Y., Jiao, F., 2000. Recognition of remote sensing images and several distinctive problems for soil erosion in Xinjiang. Soil and Water Conservation in China, 01, 34–36+47. DOI: 10.14123/j.cnki.swcc.2000.01.011 Search in Google Scholar

Williams, J.R., Jones, C.A., Dyke, P.T., 1984. A modeling approach to determining the relationship between erosion and soil productivity. Transactions of the ASAE, 27, 1, 129–0144. Search in Google Scholar

Williams, J.R., Nicks, A., Arnold, J.G., 1985. Simulator for water resources in rural basins. Journal of Hydraulic Engineering, 111, 6, 970–986. Search in Google Scholar

Wischmeier, W.H., Smith, D.D., 1978. Predicting rainfall erosion losses: a guide to conservation planning. US Department of Agriculture, Agriculture Handbook No. 537. Search in Google Scholar

Xie, Y., Chen, H., Xu, K., 2002. The using of digital remote sensing image method in soil erosion survey. Journal of Lanzhou University, 02, 157–162. DOI: 10.13885/j.issn.0455-2059.2002.02.030 Search in Google Scholar

Xin, Z.-Y., Xia, J.-G., 2020. Soil erosion calculation in the hydro-fluctuation belt by adding water erosivity factor in the USLE model. Journal of Mountain Science, 17, 9, 2123–2135. Search in Google Scholar

Xue, L., Yang, L., 2004. Research progress on remote sensing of soil erosion in China. Journal of Soil and Water Conservation, 18, 3, 186–189. Search in Google Scholar

Yang, J., 2011. Application of visual interpretation of remote sensing image in the second national land survey Gansu Science and Technology, 27, 9, 74–76. Search in Google Scholar

Yang, Q., Li, R., Cao, M., 2006. Advances of quantitative assessment on regional soil erosion. Advances in Earth Science, 21, 8, 849. Search in Google Scholar

Yang, S., Zhu, Q., 2000. Affect of man-computer interactive interpretation method in soil erosion survey of large scale by remote sensing. Journal of Soil and Water Conservation, 03, 88–91. https://doi.org/10.13870/j.cnki.stbcxb.2000.03.019 Search in Google Scholar

Yang, W., Zhang, G., Yang, H., Lin, D., Shi, P., 2023. Review and prospect of soil compound erosion. Journal of Arid Land, 15, 9, 1007–1022. Search in Google Scholar

Young, R., Onstad, C., Bosch, D., Anderson, W., 1989. AGNPS: A nonpoint-source pollution model for evaluating agricultural watersheds. Journal of soil and water conservation, 44, 2, 168–173. Search in Google Scholar

Zhai, R. et al., 2014. Research on the image deployment scheme for remote sensing and monitoring of water and soil conservation of Loess Plateau. Yellow River, 36, 6, 97–99. Search in Google Scholar

Zhang, G., Li, Z., Shi, J., 2009. Progress of study on Soil Water Erosion Model of China Recently. Soil and Water Conservation in China, 2, 12–14. Search in Google Scholar

Zhang, H., Bian, Z., 2007. Method for vegetation information extraction from remote sensing images. Geospatial Information, 06, 65–67. Search in Google Scholar

Zhang, R., Pang, Y., Li, Z., 2016. Canopy closure estimation in a temperate forest using airborne LiDAR and LANDSAT ETM+ data. Journal of Plant Ecology, 40, 2, 102. Search in Google Scholar

Zhang, X. et al., 2010. A review of remote sensing application in soil erosion assessment. Chinese Journal of Soil Science, 4, 1010–1017. Search in Google Scholar

Zhang, X., Zhao, W., Liu, Y., 2017. Application of remote sensing technology in research of soil erosion: A review. Journal of Soil and Water Conservation, 37, 2, 228–238. Search in Google Scholar

Zhao, Y., 2013. Principles and Methods of Remote Sensing Application Analysis. Science Press. Search in Google Scholar

Zhou, W.F., Wu, B.F., 2011. Review of remote sensing approaches to soil erosion monitoring. Remote Sensing Technology and Application, 20, 5, 537–542. Search in Google Scholar

Zhou, C.W., Yu, L.F., Zhou, Y., Yan, L.B., 2019. Hydrological and ecological effect of Caohai watershed regulation project based on SWAT model. Applied Ecology and Environmental Research, 17, 1. Search in Google Scholar

Žížala, D., Zádorová, T., Kapička, J., 2017. Assessment of soil degradation by erosion based on analysis of soil properties using aerial hyperspectral images and ancillary data, Czech Republic. Remote Sensing, 9, 1, 28. Search in Google Scholar