R Libraries {dendextend} and {magrittr} and Clustering Package scipy.cluster of Python For Modelling Diagrams of Dendrogram Trees

Lemenkova, Polina

doi:10.2478/cjece-2020-0002

Cited by 14 publications

(8 citation statements)

References 28 publications

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“…Application of various machine learning methods in geosciences using algorithms of automatization allow precise cartographic mapping that significantly updates the traditional cartographic routine, through the application of scripting languages, [37,38,39,51], which is noticeable in comparison to previous studies with traditional GIS applications, [53,54,44,26,27,30,45]. Supported by scripting approaches such studies rely on the processing of high-resolution datasets [36,42]. Using machine learning methods in geosciences increases the speed of the data processing and the precision of the resulting graphs and maps.…”

Section: Discussionmentioning

confidence: 99%

Distance-based vegetation indices computed by SAGA GIS: A comparison of the perpendicular and transformed soil adjusted approaches for the LANDSAT TM image

Lemenkova¹

2021

Poljoprivredna tehnika

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Landsat-TM of 2001 covering Iceland (15.5°W-21°W, 64.5°N-67°N) was processed using SAGA GIS for testing distance-based Vegetation Indices (VIs): four approaches of Perpendicular Vegetation Index (PVI) and two approaches of Transformed Soil Adjusted Vegetation Index TSAVI. The PVI of vegetation from the soil background line indicated healthiness as a leaf area index (LAI). The results showed that the reflectance for vegetation has a linear relation with soil background line. Four PVI models and two TSAVI shown coefficients of determination with LAI. The dataset demonstrate variations in the calculated coefficients. The mode in the histograms of the PVI based on four different algorithms show the difference:-7.1,-8.36, 2.78 and 7.0. The dataset for the two approaches of TSAVI: first case ranges in 4.4.-80.6 with a bell-shape mode of a histogram (8.09 to 23.29) for the first algorithm and an irregular shape for the second algorithm with several modes starting from 0.11 to 0.2 and decreasing to 0.26. SAGA GIS permits the calculation of PVI and TSAVI by computed NDVI based on the intersection of vegetation and soil background. Masking the NIR and R, a linear regression of grids was performed using an equation embedded in SAGA GIS. The advantages of the distance-based PVI and TSAVI consists in the adjusted position of pixels on the soil brightness line which refines it comparing to the slope-based VIs. The paper demonstrates SAGA GIS application in agricultural studies.

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Section: Discussionmentioning

confidence: 99%

Distance-based vegetation indices computed by SAGA GIS: A comparison of the perpendicular and transformed soil adjusted approaches for the LANDSAT TM image

Lemenkova¹

2021

Poljoprivredna tehnika

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“…There are various approaches trying to find best and effective solutions in data processing and visualization in geoscience. Multiple examples of using statistical libraries and packages of R or Python languages exist for data analysis in Earth and general sciences (CHAMBERS, 2008;LEMENKOVA, 2019c;SARKAR, 2008;SKØIEN et al, 2014;BIVAND et al, 2013;LEMENKOVA, 2020b;HOFER;PAPRITZ, 2011;LEMENKOVA, 2020b). A vast variety of the examples of the geospatial mapping is supported by using traditional GIS (e.g., KLAUČO, et al 2017;LEMENKOVA et al 2012;KLAUČO et al, 2014).…”

Section: Discussionmentioning

confidence: 99%

Scripting Cartographic Methods of GMT for Mapping the New Britain and San Cristobal Trenches, Solomon Sea, Papua New Guinea

Lemenkova

2020

Rev. C. Geog. Sobral

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The study present a case study of the Generic Mapping Tools (GMT) applied for cartographic modelling, mapping and comparative analysis of the deep-sea trenches located in southwest Pacific Ocean: the New Britain Trench (NBT) and the San Cristobal Trench (SCT). The aim was to evaluate their geomorphic variation using scripting cartographic approach of GMT. The data was processed using a sequence of the GMT modules with the main module 'grdtrack' used to visualize cross-section profiles along the trenches for their geomorphological modelling. The main grid used for topographic mapping is the SRTM DEM with 15-arc second resolution. The statistical analysis shown variability in depths of both trenches by samples in two transects. The cartographic analysis demonstrated following results. The SCT is generally deeper reaching -9,000 m, while the median for the NBT less then 7,000 m. The gradient slope of SCT is more symmetric with accurate 'V' form. In a cross-section graph, the NBT landward slope is markedly asymmetric U-shaped form and has a crescent form in the east. The NBT slope dips westwards with 35° eastward, and 41° westward, while the SCT slope has 33° oceanwards and 33,69° landwards. The difference between the geomorphology of the trenches is explained by the effects of the geotectonic evolution and actual sedimentary processes affected their formation and sculptured their structure. The marine free-air gravity anomaly illustrated density anomalies at the bathymetry in the region of NBT and SCT with range <-60.0 mGal. The geoid values are 56-66 mGal. The study contributed to the submarine geomorphic mapping and presents technical application of the cartographic functionality of GMT used for geomorphological modelling.

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“…Babcock 1978, Williams 1987, Hernandez 1994) and is being continuously updated along with contemporary advances in GIS and RS and progress in computational techniques (Kloser et al 2001, Takeda et al 2002, Schenke and Lemenkova 2008, Tedesco 2009, Lemenkov and Lemenkova 2021a, Klaučo et al 2013bKlaučo et al , 2014Klaučo et al , 2017Ladroit et al 2020, Johnson et al 2020. It was followed by further methodological development of geoinformatics which resulted in a combination of spatial analysis with statistical libraries of the programming languages (Greene et al 2017, Lemenkova 2020d, Brus 2019).…”

Section: Introductionmentioning

confidence: 99%

Dataset compilation by GRASS GIS for thematic mapping of Antarctica: Topographic surface, ice thickness, subglacial bed elevation and sediment thickness

Lemenkova¹

2021

Czech Polar Rep.

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This paper presents the GRASS GIS-based thematic mapping of Antarctica using scripting approach and associated datasets on topography and geophysics. The state-of-the art in cartographic development points at two important aspects. The first one comprises shell scripting promoted repeatability of the GIS technique, increased automatization in cartographic workflow, and compatibility of GRASS with Python, PROJ and GDAL libraries which enables advanced geospatial data processing: converting formats, re-projecting and spatial analysis. The second aspect is that data visualization greatly influences geologic research through improving the interpretation between the Antarctic glaciation and surface. This includes the machine learning algorithms of image classification enabling to distinguish between glacier and non-glacier surfaces through automatically partitioning data and analysis of various types of surfaces. Presented detailed maps of Antarctic include visualized datasets from the ETOPO1, GlobSed, EGM96 and Bedmap2 projects. The grids include bed and surface elevation, ETOPO1-based bathymetry and topography, bed, ice and sediment thickness, grounded bed uncertainty, subglacial bed elevation, geoid undulations, ice mask grounded and shelves. Data show the distribution of the present-day glacier, geophysical fields and topographic landforms for analysis of processes and correlations between the geophysical and geological phenomena. Advances in scripting cartography are significant contributions to the geological and glaciological research. Processing high-resolution datasets of Southern Ocean retrieved by remote sensing methods present new steps in automatization of the digital mapping, as presented in this research, and promotes comprehensive monitoring of geological, permafrost and glacial processes in Antarctica. All maps have been plotted using GRASS GIS version 7.8. with technical details of scripts described and interpreted.

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R Libraries {dendextend} and {magrittr} and Clustering Package scipy.cluster of Python For Modelling Diagrams of Dendrogram Trees

Cited by 14 publications

References 28 publications

Distance-based vegetation indices computed by SAGA GIS: A comparison of the perpendicular and transformed soil adjusted approaches for the LANDSAT TM image

Distance-based vegetation indices computed by SAGA GIS: A comparison of the perpendicular and transformed soil adjusted approaches for the LANDSAT TM image

Scripting Cartographic Methods of GMT for Mapping the New Britain and San Cristobal Trenches, Solomon Sea, Papua New Guinea

Dataset compilation by GRASS GIS for thematic mapping of Antarctica: Topographic surface, ice thickness, subglacial bed elevation and sediment thickness

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