Remote cartographic assessment of the erosion condition of agrolandscapes

https://doi.org/10.17221/71/2016-JFSCitation:Ovchinnikov A.S., Litvinov E.A., Rulev A.S., Fomin S.D., Kochkar' M.M., Vorob'eva O.M. (2017): Remote cartographic assessment of the erosion condition of agrolandscapes. J. For. Sci., 63: 485-489.
download PDF

The article provides an assessment methodology of the erosion condition of agricultural landscapes based on remote sensing data. The methodology is based on a multi-parametric cartographic analysis with the use of geoinformation technologies. Currently, only a cartographic image can give a holistic view of the landscape erosion and the processes occurring in them, and resorting to the modern geoinformation systems (GIS) for its obtaining and analysis is becoming a compulsory requirement of our time. The practical use of modern GIS technology in agroforestry practice allows automating the process of working with aero and space images and cartographic materials drawing up, which fully characterize the object of study. Remote cartographic studies have shown that the agricultural landscapes of the Dono-Chirskiy interfluve area need optimizing in land use and integrated agroforestry arrangement.

References:
Alatorre L.C., Beguería S. (2009): Identification of eroded areas using remote sensing in a badlands landscape on marls in the central Spanish Pyrenees. CATENA, 76, 182-190  https://doi.org/10.1016/j.catena.2008.11.005
 
Anopin V.N., Rulev A.S. (2007): Kartografirovanie degradirovannyh landshaftov Nizhnego Povolzh’ja. Volgograd, Volgograd State University of Architecture and Civil Engineering: 168. (in Russian)
 
Berljant A. M. (1995): Geoikonika. Moscow, Astreja: 219. (in Russian)
 
Bouzekraoui H., El Khalki Y., Mouaddine A., Lhissou R., El Youssi M., Barakat A. (2016): Characterization and dynamics of agroforestry landscape using geospatial techniques and field survey: a case study in central High-Atlas (Morocco). Agroforestry Systems, 90, 965-978  https://doi.org/10.1007/s10457-015-9877-8
 
Chandra A.M., Ghosh S.K. (2015): Remote Sensing and Geographical Information System. 2nd Ed. New Delhi, Narosa Publishing House: 310.
 
Colborne G. J. N., Staines S. J. (1985): Soil erosion in south Somerset. The Journal of Agricultural Science, 104, 107-  https://doi.org/10.1017/S0021859600043045
 
. Recep Efe, . Deniz Ekinci, . Isa Curebal (2008): Erosion Analysis of Sahin Creek Watershed (NW of Turkey)Using GIS Based on Rusle (3d) Method. Journal of Applied Sciences, 8, 49-58  https://doi.org/10.3923/jas.2008.49.58
 
Ivanov A.L., Kulik K.N. (2006): Agrolesomelioracija. Volgograd, All-Russian Scientific Research Institute of Agroforestry: 746. (in Russian)
 
Ivanov A.L., Svincov I.P., Ovchinnikov A.S. et al. (2009): Sistema adaptivno-landshaftnogo zemledelija Volgogradskoj oblasti na period do 2015 goda. Volgograd, Volgograd State Agricultural Academy: 304. (in Russian)
 
Jarritt N.P., Lawrence D.S.L. (2006): Simulation fine sediment delivery in lowland catchments: Model development and application of INCA-Sed. In: Owens P.N., Collins A.J. (eds): Soil Erosion and Sediment Redistribution in River Catchments: Measurement, Modelling and Management. Wallingford, CABI: 207–216.
 
Kiesel J., Schmalz B., Fohrer N. (2009): SEPAL – a simple GIS-based tool to estimate sediment pathways in lowland catchments. Advances in Geosciences, 21, 25-32  https://doi.org/10.5194/adgeo-21-25-2009
 
KLIK A., EITZINGER J. (2010): Impact of climate change on soil erosion and the efficiency of soil conservation practices in Austria. The Journal of Agricultural Science, 148, 529-541  https://doi.org/10.1017/S0021859610000158
 
Kochetov I.S., Barabanov A.T., Garshinev E.A., Zykov I.G. (1999): Agrolesomeliorativnoe adaptivno-landshaftnoe obustrojstvo vodosborov. Volgograd, All-Russian Scientific Research Institute of Agroforestry: 84. (in Russian)
 
Kulik K.N., Rulev A.S. (2000): Geoinformacionnoe kartografirovanie v agrolesomelioracii. Doklady RASHN, 1: 42–43. (in Russian)
 
Kulik K.N., Rulev A.S., Yuferev V.G. (2003): Primenenie informacionnyh tehnologij v agrolesomeliorativnom kartografi-rovanii: metod. posobie. Moscow, Russian Academy of Agricultural Sciences: 48. (in Russian)
 
Kulik K. N., Rulev A. S., Yuferev V. G. (2013): Geoinformation analysis of desertification hotspots in Astrakhan oblast. Arid Ecosystems, 3, 184-190  https://doi.org/10.1134/S2079096113030074
 
Kulik K.N., Pavlovsky E.S., Rulev A.S., Yuferev V.G., Bakurova K.B., Dorokhina Z.P., Tubalov A.A., Koshelev A.V., Bere-zovikova O.Y., Dzugaev A.A. (2007): Metodicheskie ukazanija po landshaftno-jekologicheskomu profilirovaniju pri agrolesomeliorativnom kartografirovanii. Moscow, Russian Academy of Agricultural Sciences: 41. (in Russian)
 
Rulev A.S., Juferev V.G., Juferev M.V. (2013): Geoinformacionnye issledovanija jerozionnoj degradacii v agrolandshaftah. Izvestija Nizhnevolzhskogo agrouniversitetskogo kompleksa:nauka i vysshee professional’noe obrazovanie, 2: 84–88. (in Russian)
 
Tsygankov A.V. (ed.) (1962): Osnovnye cherty morfostruktury Nizhnego Povolzh’ja. In: Geologicheskoye stroyeniye i neftegazonosnost’ Volgogradskoy oblasti. Moscow, Volgograd Oil and Gas Industry Research Institute: 141–178. (in Russian)
 
Vittal K. P. R., Vijayalakshmi K., Rao U. M. B. (1990): The Effect of Cumulative Erosion and Rainfall on Sorghum, Pearl Millet and Castor Bean Yields Under Dry Farming Conditions in Andhra Pradesh, India. Experimental Agriculture, 26, 429-  https://doi.org/10.1017/S0014479700001356
 
download PDF

© 2020 Czech Academy of Agricultural Sciences