Semi-Automated Classification of Landform Elements in Armenia Based on SRTM DEM using K-Means Unsupervised Classification-Reference-Cited by-同舟云学术

Semi-Automated Classification of Landform Elements in Armenia Based on SRTM DEM using K-Means Unsupervised Classification

Published:2017-03-01 Issue:1 Volume:36 Page:93-103
ISSN:2081-6383
Container-title:Quaestiones Geographicae
language:en
Short-container-title:

Author:

Piloyan Artak¹,Konečný Milan²

Affiliation:

1. Faculty of Geography and Geology, Yerevan State University, Armenia

2. Department of Geography, Faculty of Science, Masaryk University, Brno, Czechia

Abstract

Abstract Land elements have been used as basic landform descriptors in many science disciplines, including soil mapping, vegetation mapping, and landscape ecology. This paper presents a semi-automatic method based on k-means unsupervised classification to analyze geomorphometric features as landform elements in Armenia. First, several data layers were derived from DEM: elevation, slope, profile curvature, plan curvature and flow path length. Then, k-means algorithm has been used for classifying landform elements based on these morphomertic parameters. The classification has seven landform classes. Overall, landform classification is performed in the form of a three-level hierarchical scheme. The resulting map reflects the general topography and landform character of Armenia.

Publisher

Walter de Gruyter GmbH

Subject

General Earth and Planetary Sciences

Reference73 articles.

1. Adediran A.O., Parcharidis I., Poscolieri M., Pavlopoulos K., 2004. Computer-assisted discrimination of morphological units on north-central Crete (Greece) by applying multivariate statistics to local relief gradients. Geomorphology 58: 357-370. DOI: 10.1016/j.geomorph.2003.07.024.

2. Arakelyan A.A., Piloyan A.S., 2011. Identification and delineation of water bodies at Risk by qualitative and quantitative characteristics on example of Aghstev River Basin. Proceedings of the NAS of the Republic of Armenia - Earth Sciences 64(2): 54-64.

3. Avagyan A.A., Piloyan A.S., Yeritsian H.H., 2010. On Elevation Characteristics and Methodology of its Calculations of Terrain of the Republic of Armenia Based on 1:200000 Scale Digital Elevation Models. Proceedings of the NAS of the Republic of Armenia - Earth Sciences 63(3): 48-58.

4. Balyan S.P., 1969. Structural geomorphology of Armenian Highland and nearly territories. Geomorphology of the Armenian SSR. Yerevan University Press, Yerevan.

5. Bates P.D., Anderson M.G., Horrit M., 1998. Terrain information in geomorphological models: stability, resolution and sensitivity. In: Lane, S., Richards, K., Chandler, J. (eds), Landform Monitoring, Modelling and Analysis. Wiley, Chichester: 279-309.

Cited by 32 articles. 订阅此论文施引文献订阅此论文施引文献，注册后可以免费订阅5篇论文的施引文献，订阅后可以查看论文全部施引文献

1. Digital topographic analysis and lineament interpretation south of the Lena Delta, North Siberia: Landscape expression of its tectonic activity;Geomorphology;2024-07

2. Supervised classification of morphodiversity using artificial neural networks on the example of the Pieniny Mts (Poland);CATENA;2024-07

3. The Prediction of Cross-Regional Landslide Susceptibility Based on Pixel Transfer Learning;Remote Sensing;2024-01-15

4. Physical geomorphometry for elementary land surface segmentation and digital geomorphological mapping;Earth-Science Reviews;2024-01

5. Comparing the potentials of the different canola flower indices for canola mapping based on Landsat 9 images;All Earth;2023-12-11