Disponible con licencia de Image Analyst.
Disponible con una licencia de Spatial Analyst.
Resumen
Provides access to all existing math functions and returns a raster object with the mathematical operation applied.
Debate
For more information about how this function works, see the Raster Calculator raster function.
The referenced raster dataset for the raster object is temporary. To make it permanent, you can call the raster object's save method.
Sintaxis
RasterCalculator (rasters, input_names, expression, {extent_type}, {cellsize_type})| Parámetro | Explicación | Tipo de datos |
rasters [rasters,...] | The list of input rasters. | Raster |
input_names [input_names,...] | The user-defined variable names. | String |
expression | Build an algebraic expression to perform spatial analysis on the input raster. | String |
extent_type | The spatial extent used to create the output raster.
(El valor predeterminado es FirstOf) | String |
cellsize_type | The cell size used to create the output raster.
(El valor predeterminado es FirstOf) | String |
| Tipo de datos | Explicación |
| Raster | The output raster. |
Muestra de código
Example of a map algebraic expression using a raster calculator.
from arcpy.sa import *
out_rc_multi_raster = RasterCalculator(["raster1.tif", "raster2.tif"],
["x", "y"], "x*y")
out_rc_multi_raster.save("C:/arcpyExamples/raster_rc_multi.tif")Example of a map algebraic expression using a raster calculator.
# Import system modules
import arcpy
from arcpy.sa import *
# Check out the ArcGIS Spatial Analyst extension license
arcpy.CheckOutExtension("Spatial")
# Set the analysis environments
arcpy.env.workspace = "C:/arcpyExamples/data"
# Set local variables
in_raster1 = "raster1.tif"
in_raster2 = "raster2.tif"
# Excuate RasterCalculator(Minus) function
out_rc_minus_raster = RasterCalculator([in_raster1, in_raster2], ["x", "y"],
"x-y", "", "FirstOf")
# Save the output
out_rc_minus_raster.save("C:/arcpyExamples/raster_rc_minus.tif")