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wiki:mapping_assessment [2018/03/16 14:11] cgiuppowiki:mapping_assessment [2021/04/15 11:42] (current) dbranca
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-=== Spatial analysis of Ecosystem Services ===+===== Mapping and assessment =====
  
-Spatial data analysis(([[https://en.wikipedia.org/wiki/Spatial_analysis|https://en.wikipedia.org/wiki/Spatial_analysis]])) is an ensemble of techniques which study entities characterized by a precise location in space. It is commonly applied to geographic information. Georeferenced in the sense that they are typically structured as a combination of attributes (the feature associate to a given location) and a couple of values, i.e. the coordinates, identifying the location within a recognized Reference System (e.g. WGS84, UTM, etc.)\\ +=== Spatial analysis of Ecosystem Services === 
-Spatial analysis includes a variety of techniques, developed to derive quantitative indicators as outcomes of algorithms applied to spatial data and in particular to their topological, geometric, or geographic properties. The algorithms are typically applied to raster based GIS layers, for example by means of spatial convolution indices, calculating descriptive context statistics by means of moving windows across the study area.\\ +[[wiki:spatial_data| 
-In the case of spatial analysis applied to ES, examples are:\\+Spatial data]] analysis(([[https://en.wikipedia.org/wiki/Spatial_analysis|https://en.wikipedia.org/wiki/Spatial_analysis]]))  is an ensemble of techniques which study entities characterized by a precise location in space. It is commonly applied to geographic information. Georeferenced in the sense that they are typically structured as a combination of attributes (the feature associate to a given location) and a couple of values, i.e. the coordinates, identifying the location within a recognized Reference System (e.g. WGS84, UTM, etc.)\\ 
 +Spatial analysis includes a variety of techniques, developed to derive quantitative [[wiki:indicators|indicators]] as outcomes of algorithms applied to spatial data and in particular to their topological, geometric, or geographic properties. The algorithms are typically applied to raster based [[wiki:gis|GIS]] layers, for example by means of spatial convolution indices, calculating descriptive context statistics by means of moving windows across the study area.\\ 
 +In the case of spatial analysis applied to [[wiki:ecosystem_services_alpes|ES]], examples are:\\
 - Cost analysis performed by calculating a proximity (or cost) surface over a friction map, e.g. to map the potential fruition of recreational areas by tourists, or the ecological connectiveness by analysing corridors between habitats.\\ - Cost analysis performed by calculating a proximity (or cost) surface over a friction map, e.g. to map the potential fruition of recreational areas by tourists, or the ecological connectiveness by analysing corridors between habitats.\\
 - Visibility analysis of landscapes, to determine all areas that can be seen from one or more viewpoints, to determine the recreational values.\\ - Visibility analysis of landscapes, to determine all areas that can be seen from one or more viewpoints, to determine the recreational values.\\
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 === ES Spatial Analysis in the AlpES Project === === ES Spatial Analysis in the AlpES Project ===
  
-Biomass production for livestock uses is an ES that strictly depends on local climate and biophysical parameters. Either these spatial data are collected from local institutions or indirectly obtained from remote sensing (RM), they can be used to estimate potential productivity of pastures and grasslands. In the AlpES project, statistical models are applied to quantify kg of production in dry matter per hectare, depending on the length of the growing season. The growing season is a typical proxy used to define the number of vegetation days i.e. the days in which the temperature is sufficiently high to induce biomass accumulation through synthesis of new plant tissues. For fodder production the temperature threshold was set to 5° C. Graph 1 reports the statistical models used to estimate biomass production. These models can be implemented by using simple map algebra tools, usually available in any GIS software, like QGIS and ArcGIS. A vigor factor (VF) has been assigned to each land cover as local productivity is assumed to be different depending on the specific land cover class: for example, alpine pastures have clearly higher biomass productivity compared to moors and heathland. Consequently, different growth curves have been chosen to estimate biomass growth based on the raster map that displays the number of vegetation days per cell.+[[:wiki:grassland_biomass|Biomass production]] for livestock uses is an ES that strictly depends on local climate and biophysical parameters. Either these spatial data are collected from local institutions or indirectly obtained from [[wiki:remote_sensing|remote sensing]] (RM), they can be used to estimate potential productivity of pastures and grasslands. In the [[wiki:alpes|AlpES project]], statistical models are applied to quantify kg of production in dry matter per hectare, depending on the length of the growing season. The growing season is a typical proxy used to define the number of vegetation days i.e. the days in which the temperature is sufficiently high to induce biomass accumulation through synthesis of new plant tissues. For fodder production the temperature threshold was set to 5° C. Graph 1 reports the statistical models used to estimate biomass production. These models can be implemented by using simple map algebra tools, usually available in any GIS software, like QGIS and ArcGIS. A vigor factor (VF) has been assigned to each land cover as local productivity is assumed to be different depending on the specific land cover class: for example, alpine pastures have clearly higher biomass productivity compared to moors and heathland. Consequently, different growth curves have been chosen to estimate biomass growth based on the raster map that displays the number of vegetation days per cell.
  
-<font 10px/inherit;;inherit;;inherit>Graph 1 Biomass growth curves: VF 5 (red); VF4 (purple); VF 3 (yellow); VF 2 (dark green); VF 1 (light green). The x-axis reports the number of vegetation days. The y-axis reports the biomass productivity in deci-tons of dry mass per hectare (EURAC).</font>+{{:wiki:biomass_productivity_equations.jpg?700}} 
 + 
 +<font 11px/inherit;;inherit;;inherit>Graph 1Biomass growth curves: VF 5 (red); VF4 (purple); VF 3 (yellow); VF 2 (dark green); VF 1 (light green). The x-axis reports the number of vegetation days. The y-axis reports the biomass productivity in deci-tons of dry mass per hectare (EURAC).</font>
  
 In general, land cover data are often used to quantify spatially explicit indicators of ES supply(([[https://biodiversity.europa.eu/maes|https://biodiversity.europa.eu/maes]])).\\ In general, land cover data are often used to quantify spatially explicit indicators of ES supply(([[https://biodiversity.europa.eu/maes|https://biodiversity.europa.eu/maes]])).\\
 An example is the hemeroby index i.e. the degree of human influence. It is based on Paracchini and Capitani (2011)(([[http://agrienv.jrc.ec.europa.eu/publications/pdfs/EUR_25114.pdf|http://agrienv.jrc.ec.europa.eu/publications/pdfs/EUR_25114.pdf]])) who have classified the degree of human influence in a decreasing ranking (7 to 1), by matching ranks to each class of Corine Land Cover (CLC) classification. For example, urban areas are assumed to be low providers of recreational activities (hemeroby index 7) while forests offer several opportunities for outdoor leisure and to practice sports (hemeroby index 2, 3 or 4). Thus, within AlpES project, hemeroby indexes have been derived through the reclassification of CLC codes, as indicator of the ES “outdoor recreation activities” (Figure 1).\\ An example is the hemeroby index i.e. the degree of human influence. It is based on Paracchini and Capitani (2011)(([[http://agrienv.jrc.ec.europa.eu/publications/pdfs/EUR_25114.pdf|http://agrienv.jrc.ec.europa.eu/publications/pdfs/EUR_25114.pdf]])) who have classified the degree of human influence in a decreasing ranking (7 to 1), by matching ranks to each class of Corine Land Cover (CLC) classification. For example, urban areas are assumed to be low providers of recreational activities (hemeroby index 7) while forests offer several opportunities for outdoor leisure and to practice sports (hemeroby index 2, 3 or 4). Thus, within AlpES project, hemeroby indexes have been derived through the reclassification of CLC codes, as indicator of the ES “outdoor recreation activities” (Figure 1).\\
-For the same ES, another example is the diversity of landcover, which is based on the assumption that spatial heterogeneity provides high recreational and visual attractiveness(([[http://www.sciencedirect.com/science/article/pii/S016920461200031X|http://www.sciencedirect.com/science/article/pii/S016920461200031X]])). The spatial analysis is carried out by iterating a moving window of a defined shape on every pixel of the landcover map. The number of landcover types can be counted in the surrounding cells and recorded within each pixel, representing the landcover heterogeneity that can be observed in the neighborhoods. In AlpES project, a moving window of 1 km has been used to calculate landcover diversity (Figure 1).\\ +For the same ES, another example is the diversity of landcover, which is based on the assumption that spatial heterogeneity provides high recreational and visual attractiveness(([[http://www.sciencedirect.com/science/article/pii/S016920461200031X|http://www.sciencedirect.com/science/article/pii/S016920461200031X]])). The spatial analysis is carried out by iterating a moving window of a defined shape on every pixel of the landcover map. The number of landcover types can be counted in the surrounding cells and recorded within each pixel, representing the landcover heterogeneity that can be observed in the neighborhoods. In AlpES project, a moving window of 1 km per side has been used to calculate landcover diversity (Figure 1). 
-\\ + 
-<font 10px/inherit;;inherit;;inherit>Figure 1 Detail of pilot region LAG Alto Bellunese: hemeroby index, where value close to 1 implies a low degree of human influence (top); number of different landcover types per km2 (bottom).</font>+{{:wiki:example_maps.jpeg?500}} 
 + 
 +<font 11px/inherit;;inherit;;inherit>Figure 1Detail of pilot region LAG Alto Bellunese: hemeroby index, where value close to 1 implies a low degree of human influence (top); number of different landcover types per km² (bottom).</font>
  
-Accessibility is the proxy of the degree to which people can actually benefit from high recreation potentials(([[http://www.sciencedirect.com/science/article/pii/S1470160X1400168X|http://www.sciencedirect.com/science/article/pii/S1470160X1400168X]])). In AlpES project, accessibility has been calculated by means of a cost-distance algorithm(([[http://desktop.arcgis.com/en/arcmap/10.4/tools/spatial-analyst-toolbox/cost-distance.htm|http://desktop.arcgis.com/en/arcmap/10.4/tools/spatial-analyst-toolbox/cost-distance.htm]]))(([[https://grass.osgeo.org/grass74/manuals/r.cost.html|https://grass.osgeo.org/grass74/manuals/r.cost.html]])), which determines the cumulative cost of moving to each cell on a cost surface map, from other user-specified geographic coordinates (e.g. the coordinates of the centroids of polygons representing urban areas). Each cell in the input cost map contains a value that represents the cost of moving from that cell to its neighbors. The output map displays the least cost path from each pixel of the cost surface to closest urban areas, extracted from the landcover map (CLC codes 111, 112). To quantify accessibility the cost was expressed in term of travel time.\\+[[wiki:accessibility|Accessibility]] is the proxy of the degree to which people can actually benefit from high recreation potentials(([[http://www.sciencedirect.com/science/article/pii/S1470160X1400168X|http://www.sciencedirect.com/science/article/pii/S1470160X1400168X]])). In AlpES project, accessibility has been calculated by means of a cost-distance algorithm(([[http://desktop.arcgis.com/en/arcmap/10.4/tools/spatial-analyst-toolbox/cost-distance.htm|http://desktop.arcgis.com/en/arcmap/10.4/tools/spatial-analyst-toolbox/cost-distance.htm]]))   (([[https://grass.osgeo.org/grass74/manuals/r.cost.html|https://grass.osgeo.org/grass74/manuals/r.cost.html]])), which determines the cumulative cost of moving to each cell on a cost surface map, from other user-specified geographic coordinates (e.g. the coordinates of the centroids of polygons representing urban areas). Each cell in the input cost map contains a value that represents the cost of moving from that cell to its neighbors. The output map displays the least cost path from each pixel of the cost surface to closest urban areas, extracted from the landcover map (CLC codes 111, 112). To quantify accessibility the cost was expressed in term of travel time.\\
 Whenever an ES is estimated through a portfolio of indicators, a spatial multi-criteria analysis (MCAs) can be applied. For example, this approach has been helpful to display recreation potential hotspots in a relative and easy-to-read manner. In MCA, worth to be mentioned are the steps of normalization and aggregation:\\ Whenever an ES is estimated through a portfolio of indicators, a spatial multi-criteria analysis (MCAs) can be applied. For example, this approach has been helpful to display recreation potential hotspots in a relative and easy-to-read manner. In MCA, worth to be mentioned are the steps of normalization and aggregation:\\
 • normalization(([[https://en.wikipedia.org/wiki/Normalization_(statistics)|https://en.wikipedia.org/wiki/Normalization_(statistics) ]])) is a method used to convert data variability in a common numerical scale (0 to 1 or 0 to 100 %);\\ • normalization(([[https://en.wikipedia.org/wiki/Normalization_(statistics)|https://en.wikipedia.org/wiki/Normalization_(statistics) ]])) is a method used to convert data variability in a common numerical scale (0 to 1 or 0 to 100 %);\\
wiki/mapping_assessment.1521205880.txt.gz · Last modified: 2018/03/16 14:11 by cgiuppo