FeatureClassToNumPyArray

Résumé

Convertit une classe d'entités en tableau structuré NumPy.

Discussion

NumPy is a fundamental package for scientific computing in Python, including support for a powerful N-dimensional array object. For more information, see Working with NumPy in ArcGIS.

Pour convertir des tables en tableau NumPy, utilisez plutôt la fonction TableToNumPyArray.

Syntaxe

FeatureClassToNumPyArray (in_table, field_names, {where_clause}, {spatial_reference}, {explode_to_points}, {skip_nulls}, {null_value})
ParamètreExplicationType de données
in_table

The feature class, layer, table, or table view.

String
field_names
[field_names,...]

A list (or tuple) of field names. For a single field, you can use a string instead of a list of strings.

Use an asterisk (*) instead of a list of fields to access all fields from the input table (raster and BLOB fields are excluded). However, for faster performance and reliable field order, it is recommended that the list of fields be narrowed to only those that are actually needed.

Raster and BLOB fields are not supported. Geometry objects are not supported using the SHAPE@ token, but geometry information can be included using other tokens such as SHAPE@XY (a tuple of the feature's centroid coordinates), SHAPE@AREA, and SHAPE@LENGTH.

Additional information can be accessed using tokens (such as OID@) in place of field names:

  • SHAPE@XYTuple des coordonnées x,y du centroïde de l’entité.
  • SHAPE@XYZTuple des coordonnées x,y,z du centroïde de l’entité.
  • SHAPE@TRUECENTROIDTuple des coordonnées x,y du centroïde de l’entité. La valeur renvoyée est la même que SHAPE@XY.
  • SHAPE@XDouble de la coordonnée x de l'entité.
  • SHAPE@YDouble de la coordonnée y de l'entité.
  • SHAPE@ZDouble de la coordonnée z de l'entité.
  • SHAPE@MDouble de la valeur m de l'entité.
  • SHAPE@JSONChaîne JSON Esri représentant la géométrie.
  • SHAPE@WKBReprésentation binaire connue (WKB) de la géométrie de l'OGC. Cette représentation constitue une représentation portable d'une valeur de géométrie sous la forme d'un flux contigu d'octets.
  • SHAPE@WKTReprésentation textuelle connue (WKT) de la géométrie de l'OGC. Cette représentation constitue une représentation portable d'une valeur de géométrie sous la forme d'une chaîne de texte.
  • SHAPE@AREADouble de la surface de l'entité.
  • SHAPE@LENGTHDouble de la longueur de l'entité.
  • OID@Valeur du champ ID d’objet.

Export a feature class to a NumPy array. The output array will include a field for the Object ID and a field containing a tuple of the feature's centroid's x,y coordinates.

import arcpy
array = arcpy.da.FeatureClassToNumPyArray(fc, ["OID@", "SHAPE@XY"])

# The first row would look similar to the following:
#  (1, [-147.82339477539062, 64.86953735351562])
print(array[0])

SHAPE@M and SHAPE@Z tokens will only return values if the in_table contains point features and is m-aware (or z-aware). If the in_table contains polygon, polyline, or multipart features, SHAPE@M and SHAPE@Z will return a nan. Any feature class that is not m-aware or z-aware will not support SHAPE@M and SHAPE@Z tokens.

(La valeur par défaut est *)

String
where_clause

An optional expression that limits the records returned. For more information on where clauses and SQL statements, see SQL reference for query expressions used in ArcGIS.

(La valeur par défaut est "")

String
spatial_reference

The spatial reference of the feature class. When this argument is specified, the feature will be projected (or transformed) from the input's spatial reference. If unspecified, the input feature classes' spatial reference will be used. Valid values for this argument are a SpatialReference object or string equivalent.

Use the spatial_reference argument to return coordinates in a different spatial reference. Here, a second feature class is described to access a spatial reference object.

import arcpy
SR = arcpy.Describe(fc2).spatialReference
arcpy.da.FeatureClassToNumPyArray(fc,
                                  ["OID@", "SHAPE@XY", "EDUCATION"], 
                                  spatial_reference=SR)

(La valeur par défaut est None)

SpatialReference
explode_to_points

Deconstruct a feature into its individual points or vertices. If explode_to_points is set to True, a multipoint feature with five points, for example, is represented by five rows.

(La valeur par défaut est False)

Boolean
skip_nulls

Control whether records using nulls are skipped. It can be either a Boolean True or False, or a Python function or lambda expression.

When set to True, if any of the record's attributes is null (including geometry), the record is skipped. With a False setting, skip_nulls attempts to use all records regardless of nulls. In a NumPy array, a null is represented as a nan (not a number) for floating-point numeric values but not for integers.

Skip all records that include a null.

import arcpy
array = arcpy.da.FeatureClassToNumPyArray(fc, fields, skip_nulls=True)

A Python function or lambda expression can be used to allow finer control, including logging the OID values of all records that include a null value. In both examples below, the lambda expression or function is used to identify OIDs that include null records.

Use a function to capture all records that are skipped because of nulls.

import arcpy
def getnull(oid):
    nullRows.append(oid)
    return True
nullRows = list()
array = arcpy.da.FeatureClassToNumPyArray(table, fields, skip_nulls=getnull)
print(nullRows)

Use a lambda expression to capture all records that are skipped because of nulls.

import arcpy
nullRows = list()
array = arcpy.da.FeatureClassToNumPyArray(fc, fields, 
                                    skip_nulls=lambda oid: nullRows.append(oid))
print(nullRows)
Remarque :

In NumPy arrays, nulls are represented in float types such as nan and in text types such as None. Integer types do not support the concept of null values.

(La valeur par défaut est False)

Variant
null_value

Replaces null values from the input with a new value.

null_value is replaced before skip_nulls is evaluated.

Mask all None's in integer fields with a -9999.

import arcpy
fields = ['field1', 'field2']
arcpy.da.FeatureClassToNumPyArray(fc, fields, null_value=-9999)

Mask None's in integer fields with different values using a dictionary.

import arcpy
fields = ['field1', 'field2']
nullDict = {'field1':-999999, 'field2':-9999}
arcpy.da.FeatureClassToNumPyArray(fc, fields, null_value=nullDict)
Attention :

Providing a mask such as -9999 allows integer fields containing nulls to be exported to a NumPy array, but be cautious when using these values in any analysis. The results may be inadvertently skewed by the introduced value.

(La valeur par défaut est None)

Integer
Valeur renvoyée
Type de donnéesExplication
NumPyArray

A NumPy structured array.

Exemple de code

Convertir une table en tableau NumPy et effectuer certains calculs statistiques de base avec NumPy.

import arcpy
import numpy

input = "c:/data/usa.gdb/USA/counties"
arr = arcpy.da.FeatureClassToNumPyArray(input, ('STATE_NAME', 'POP1990', 'POP2000'))

# Sum the total population for 1990 and 2000
#
print(arr["POP1990"].sum())
print(arr["POP2000"].sum())

# Sum the population for the state of Minnesota
#
print(arr[arr['STATE_NAME'] == "Minnesota"]['POP2000'].sum())

Utilisez la fonction TableToNumPyArray pour déterminer les coefficients de corrélation pour deux champs.

import arcpy
import numpy

input = "c:/data/usa.gdb/USA/counties"
field1 = "INCOME"
field2 = "EDUCATION"

arr = arcpy.da.FeatureClassToNumPyArray(input, (field1, field2))

# Print correlation coefficients for comparison of 2 field values
#               
print(numpy.corrcoef((arr[field1], arr[field2])))

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