Euclidean Allocation (Spatial Analyst)

Available with Spatial Analyst license.

Summary

Calculates, for each cell, the nearest source based on Euclidean distance.

Legacy:

This tool is deprecated and will be removed in a future release.

The Distance Allocation tool provides enhanced functionality or performance.

Learn more about Euclidean distance analysis

Illustration

Euclidean Allocation illustration
Euc_Alloc = EucAllocation(Source_Ras)

Usage

  • The input source data can be a feature class or a raster. The feature class can be point, line or polygon.

  • When the input source data is a raster, the set of source cells consists of all cells in the source raster that have valid values. Cells that have NoData values are not included in the source set. The value 0 is considered a legitimate source. A source raster can be created using the extraction tools.

  • When the input source data is a feature class, the source locations are converted to a raster internally before performing the analysis.

  • When using feature data for the input source data, care must be taken with how the output cell size is handled when it is coarse, relative to the detail present in the input. The internal rasterization process uses the same default Cell assignment type value as the Feature to Raster tool, which is the cell center method. This means that data that is not located at the center of the cell will not be included in the intermediate rasterized source output, so it will not be represented in the distance calculations. For example, if the sources are a series of small polygons (such as building footprints) that are small relative to the output cell size, it is possible that only a few will fall under the centers of the output raster cells, seemingly causing most of the others to be lost in the analysis.

    To avoid this situation, as an intermediate step, you can rasterize the input features directly with the Feature to Raster tool and set the Field parameter. Then use the resulting output as input to the particular distance tool you want to use. Alternatively, you can select a small cell size to capture the appropriate amount of detail from the input features.

  • The Maximum Distance value is specified in the same map units as the input source data.

  • The input value raster is useful if the input raster or feature source data is a raster derived from a function that results in either one or zero. These functions lose their original zone values associated with the source cell locations. The input value raster can either restore these values or allow analysis on additional combinations of zone values within the source cells.

  • If an input value raster is used, it may change the configuration and results of the Euclidean allocation output. It will not affect the optional Euclidean distance or direction results.

  • The Output cell size parameter can be defined by a numeric value or obtained from an existing raster dataset. If the cell size hasn’t been explicitly specified as the parameter value, it is derived from the Cell Size environment if it has been specified. If the parameter cell size or the environment cell size have not been specified, the default output cell size is determined based on the type of input dataset as follows:

    • If the input dataset is a raster, the cell size of the dataset is used.
    • If the input dataset is a feature and the Snap Raster environment has been set, the cell size of the snap raster is used. If no snap raster is set, the cell size is calculated from the shorter of the width or height of the extent divided by 250 in which the extent is in the output coordinate system specified in the environment.
  • If the cell size is specified using a numeric value, the tool will use it directly for the output raster.

    If the cell size is specified using a raster dataset, the parameter will show the path of the raster dataset instead of the cell size value. The cell size of that raster dataset will be used directly in the analysis, provided the spatial reference of the dataset is the same as the output spatial reference. If the spatial reference of the dataset is different than the output spatial reference, it will be projected based on the specified Cell Size Projection Method value.

  • The default processing extent for this tool is the Union of Inputs value. The combined extent of both input datasets will be processed.

  • This tool supports parallel processing. If your computer has multiple processors or processors with multiple cores, better performance may be achieved, particularly on larger datasets. See the Parallel processing with Spatial Analyst help topic for details on this capability and how to configure it.

    When using parallel processing, temporary data will be written to manage the data chunks being processed. The default temp folder location will be on your local C: drive. You can control the location of this folder by setting up a system environment variable named TempFolders and specifying the path to a folder to use (for example, E:\RasterCache). If you have admin privileges on your machine, you can also use a registry key (for example, [HKEY_CURRENT_USER\SOFTWARE\ESRI\ArcGISPro\Raster]).

    By default, this tool will use 50 percent of the available cores. If the input data is smaller than 5,000 by 5,000 cells in size, fewer cores may be used. You can control the number of cores the tool uses with the Parallel processing factor environment.

  • When the output raster format is .crf, this tool supports the Pyramid raster storage environment. Pyramids will be created in the output by default. For any other output format, this environment is not supported, and pyramids will not be created.

  • See Analysis environments and Spatial Analyst for additional details on the geoprocessing environments that apply to this tool.

Parameters

LabelExplanationData Type
Input raster or feature source data

The input source locations.

This is a raster or feature identifying the cells or locations that will be used to calculate the Euclidean distance for each output cell location.

For rasters, the input type can be integer or floating point.

If the input source raster is floating point, the Input value raster parameter must be set, and it must be integer. The value raster will take precedence over the Source field parameter setting.

Raster Layer; Feature Layer
Maximum distance
(Optional)

The threshold that the accumulative distance values cannot exceed.

If an accumulative Euclidean distance value exceeds this value, the output value for the cell location will be NoData.

The default distance is to the edge of the output raster.

Double
Input value raster
(Optional)

The input integer raster that identifies the zone values that will be used for each input source location.

For each source location (cell or feature), the Input value raster value will be assigned to all cells allocated to the source location for the computation. The value raster will take precedence over the Source field parameter setting.

Raster Layer
Output cell size
(Optional)

The cell size of the output raster that will be created.

This parameter can be defined by a numeric value or obtained from an existing raster dataset. If the cell size hasn't been explicitly specified as the parameter value, the environment cell size value will be used if specified; otherwise, additional rules will be used to calculate it from the other inputs. See the usage section for more detail.

Analysis Cell Size
Source field
(Optional)

The field used to assign values to the source locations. It must be of integer type.

If the Input value raster parameter has been set, the values in that input will have precedence over the Source field parameter setting.

Field
Output distance raster
(Optional)

The output Euclidean distance raster.

The distance raster identifies, for each cell, the Euclidean distance to the closest source cell, set of source cells, or source location.

The output raster is of floating-point type.

Raster Dataset
Output direction raster
(Optional)

The output Euclidean direction raster.

The direction raster contains the calculated direction, in degrees, that each cell center is from the closest source cell center.

The range of values is from 0 degrees to 360 degrees, with 0 reserved for the source cells. Due east (right) is 90, and the values increase clockwise (180 is south, 270 is west, and 360 is north).

The output raster is of integer type.

Raster Dataset
Distance Method
(Optional)

Specifies whether the distance will be calculated using a planar (flat earth) or a geodesic (ellipsoid) method.

  • PlanarThe distance calculation will be performed on a projected flat plane using a 2D Cartesian coordinate system. This is the default.
  • GeodesicThe distance calculation will be performed on the ellipsoid. Regardless of input or output projection, the results will not change.
String
Input raster or feature barrier data
(Optional)

The dataset that defines the barriers.

The barriers can be defined by an integer or a floating-point raster, or by a point, line, or polygon feature.

Raster Layer; Feature Layer
Out back direction raster
(Optional)

The output Euclidean back direction raster.

The back direction raster contains the calculated direction in degrees. The direction identifies the next cell along the shortest path back to the closest source while avoiding barriers.

The range of values is from 0 degrees to 360 degrees, with 0 reserved for the source cells. Due east (right) is 90, and the values increase clockwise (180 is south, 270 is west, and 360 is north).

The output raster is of type float.

Raster Dataset

Return Value

LabelExplanationData Type
Output allocation raster

The output Euclidean allocation raster.

The cell values (zones) identify the nearest source location.

The output raster is of integer type.

Raster

EucAllocation(in_source_data, {maximum_distance}, {in_value_raster}, {cell_size}, {source_field}, {out_distance_raster}, {out_direction_raster}, {distance_method}, {in_barrier_data}, {out_back_direction_raster})
NameExplanationData Type
in_source_data

The input source locations.

This is a raster or feature identifying the cells or locations that will be used to calculate the Euclidean distance for each output cell location.

For rasters, the input type can be integer or floating point.

If the input source raster is floating point, the in_value_raster parameter must be set, and it must integer. The value raster will take precedence over the source_field parameter setting.

Raster Layer; Feature Layer
maximum_distance
(Optional)

The threshold that the accumulative distance values cannot exceed.

If an accumulative Euclidean distance value exceeds this value, the output value for the cell location will be NoData.

The default distance is to the edge of the output raster.

Double
in_value_raster
(Optional)

The input integer raster that identifies the zone values that will be used for each input source location.

For each source location (cell or feature), the in_value_raster value will be assigned to all cells allocated to the source location for the computation. The value raster will take precedence over the source_field parameter setting.

Raster Layer
cell_size
(Optional)

The cell size of the output raster that will be created.

This parameter can be defined by a numeric value or obtained from an existing raster dataset. If the cell size hasn't been explicitly specified as the parameter value, the environment cell size value will be used if specified; otherwise, additional rules will be used to calculate it from the other inputs. See the usage section for more detail.

Analysis Cell Size
source_field
(Optional)

The field used to assign values to the source locations. It must be of integer type.

If the in_value_raster parameter has been set, the values in that input will have precedence over the source_field parameter setting.

Field
out_distance_raster
(Optional)

The output Euclidean distance raster.

The distance raster identifies, for each cell, the Euclidean distance to the closest source cell, set of source cells, or source location.

The output raster is of floating-point type.

Raster Dataset
out_direction_raster
(Optional)

The output Euclidean direction raster.

The direction raster contains the calculated direction, in degrees, that each cell center is from the closest source cell center.

The range of values is from 0 degrees to 360 degrees, with 0 reserved for the source cells. Due east (right) is 90, and the values increase clockwise (180 is south, 270 is west, and 360 is north).

The output raster is of integer type.

Raster Dataset
distance_method
(Optional)

Specifies whether the distance will be calculated using a planar (flat earth) or a geodesic (ellipsoid) method.

  • PLANARThe distance calculation will be performed on a projected flat plane using a 2D Cartesian coordinate system. This is the default.
  • GEODESICThe distance calculation will be performed on the ellipsoid. Regardless of input or output projection, the results will not change.
String
in_barrier_data
(Optional)

The dataset that defines the barriers.

The barriers can be defined by an integer or a floating-point raster, or by a point, line, or polygon feature.

Raster Layer; Feature Layer
out_back_direction_raster
(Optional)

The output Euclidean back direction raster.

The back direction raster contains the calculated direction in degrees. The direction identifies the next cell along the shortest path back to the closest source while avoiding barriers.

The range of values is from 0 degrees to 360 degrees, with 0 reserved for the source cells. Due east (right) is 90, and the values increase clockwise (180 is south, 270 is west, and 360 is north).

The output raster is of type float.

Raster Dataset

Return Value

NameExplanationData Type
out_allocation_raster

The output Euclidean allocation raster.

The cell values (zones) identify the nearest source location.

The output raster is of integer type.

Raster

Code sample

EucAllocation example 1 (Python window)

The following Python Window script demonstrates how to use the EuclideanAllocation tool.

import arcpy
from arcpy import env
from arcpy.sa import *
env.workspace = "C:/sapyexamples/data"
eucAllocate = EucAllocation("observers", 50000, "elevation", 25, "FID", 
                            "c:/sapyexamples/output/outeucdist", 
                            "c:/sapyexamples/output/outeucdir")
eucAllocate.save("c:/sapyexamples/output/eucalloc")
EucAllocation example 2 (stand-alone script)

Calculates, for each cell, the zone of the closest source location in Euclidean distance.

# Name: EucAllocation_Ex_02.py
# Description: Calculates, for each cell, the zone of the closest 
#              source location in Euclidean distance.
# Requirements: Spatial Analyst Extension

# Import system modules
import arcpy
from arcpy import env
from arcpy.sa import *

# Set environment settings
env.workspace = "C:/sapyexamples/data"

# Set local variables
inSource = "observers.shp"
maxDist = 50000
valRaster = "elevation"
cellSize = 25
sourceField = "FID"
optOutDist = "c:/sapyexamples/output/outeucdist02"
optOutDir = "c:/sapyexamples/output/outeucdir02"

# Execute EucAllocation
eucAllocate = EucAllocation(inSource, maxDist, valRaster, cellSize,
                             sourceField, optOutDist, optOutDir)

# Save the output 
eucAllocate.save("c:/sapyexamples/output/eucalloc02")

Licensing information

  • Basic: Requires Spatial Analyst
  • Standard: Requires Spatial Analyst
  • Advanced: Requires Spatial Analyst

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