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CAD To Geodatabase (Conversion)

In this topic

  1. Summary
  2. Usage
  3. Parameters
  4. Environments
  5. Licensing information

Summary

Reads a CAD dataset and creates feature classes of the drawing. The feature classes are written to a geodatabase feature dataset.

Usage

  • This tool creates a new feature dataset in an existing geodatabase, which is added as a group layer in the map.

  • The input features must be a CAD file. The CAD file will contain all the available homogenous geometries.

  • The input parameter will accept CAD data from multiple formats (DWG, DXF, and DGN) in one operation.

  • If a DWG is used as input it may contain additional CAD-defined feature classes that conform to the Esri specification document Mapping Specification for CAD. These are subsets of the original homogenous geometries with entity-linked attributes that also import to the geodatabase as feature attributes.

  • Feature class names must be unique for the entire geodatabase or the tool will fail.

  • All inputs are combined into a single output CAD dataset, which will contain the standard point, line, and polygon feature classes, in addition to any CAD-defined feature classes that may exist.

  • If a projection file exists for the input CAD file, it will automatically populate the spatial_reference parameter with the projection information. If multiple CAD files are used as inputs, the spatial_reference will be taken from the first CAD file with valid projection information.

  • If a universal projection (esri_cad.prj) file exists in the directory, the projection information will be taken from the universal projection file if a coordinate system is not defined for the first CAD file.

  • If a world file exists for the input CAD file, it will automatically perform the transformation.

  • If a universal world (esri_cad.wld) file exists in the directory, the transformation will be applied to each CAD dataset in the list that does not have a companion world file.

  • If a DGN file has multiple models, be sure the first model has the largest domain. This tool calculates the domain for the entire DGN file from the first model. If this is not the case, be sure to expand the domain in your first model to be large enough so all will fit.

  • Should you only require a single feature class from the CAD feature classes, use a geoprocessing tool such as Feature Class To Feature Class.

Parameters

DialogPython

LabelExplanationData Type
Input CAD Datasets

The collection of CAD files to convert to geodatabase features.

CAD Drawing Dataset
Output Geodatabase

The geodatabase where the output feature dataset will be created. This geodatabase must already exist.

Workspace
Dataset

The name of the feature dataset to be created.

String
Reference scale

This parameter is not needed for this tool as CAD annotation is treated as points in ArcGIS Pro.

Double
Spatial Reference
(Optional)

The spatial reference of the output feature dataset. If you wish to control other aspects of the spatial reference, such as the xy, z, m domains, resolutions, and tolerances, set the appropriate geoprocessing environments.

Spatial Reference

Derived Output

LabelExplanationData Type
Output Feature Dataset

The output geodatabase feature dataset containing the new feature classes.

Feature Dataset

arcpy.conversion.CADToGeodatabase(input_cad_datasets, out_gdb_path, out_dataset_name, reference_scale, {spatial_reference})
NameExplanationData Type
input_cad_datasets
[CAD drawing dataset,...]

The collection of CAD files to convert to geodatabase features.

CAD Drawing Dataset
out_gdb_path

The geodatabase where the output feature dataset will be created. This geodatabase must already exist.

Workspace
out_dataset_name

The name of the feature dataset to be created.

String
reference_scale

This parameter is not needed for this tool as CAD annotation is treated as points in ArcGIS Pro.

Double
spatial_reference
(Optional)

The spatial reference of the output feature dataset. If you wish to control other aspects of the spatial reference, such as the xy, z, m domains, resolutions, and tolerances, set the appropriate geoprocessing environments.

Spatial Reference

Derived Output

NameExplanationData Type
out_dataset

The output geodatabase feature dataset containing the new feature classes.

Feature Dataset

Code sample

CADToGeodatabase example (stand-alone script)

The following Python script demonstrates how to use the CADToGeodatabase function in a stand-alone script. 

# Name: CADtoGeodatabase.py
# Description: Create a feature dataset

# Import system modules
import arcpy

# Set workspace
arcpy.env.workspace = "C:/data"

# Set local variables
input_cad_dataset = "C:/data/City.DWG"
out_gdb_path = "C:/data/HabitatAnalysis.gdb" 
out_dataset_name = "analysisresults"
reference_scale = "1000"
spatial_reference = "NAD_1983_StatePlane_California_VI_FIPS_0406_Feet"

# Create a file geodatabase for the feature dataset
arcpy.CreateFileGDB_management("C:/data", "HabitatAnalysis.gdb")

# Execute CreateFeaturedataset 
arcpy.CADToGeodatabase_conversion(input_cad_dataset, out_gdb_path, 
                                  out_dataset_name, reference_scale)

Environments

Default Output Z Value, M Resolution, M Tolerance, Output XY Domain, Output Coordinate System, Extent, Current Workspace, Geographic Transformations, Scratch Workspace, Output has M values, Output has Z values, XY Resolution, XY Tolerance, Z Resolution, Z Tolerance

Licensing information

  • Basic: Yes
  • Standard: Yes
  • Advanced: Yes

Related topics

  • An overview of the To Geodatabase toolset
  • Find a geoprocessing tool

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In this topic
  1. Summary
  2. Usage
  3. Parameters
  4. Environments
  5. Licensing information