Geospatial Parquet format


The Apache Parquet provides a standardized open-source columnar storage format. This specification defines how geospatial data should be stored in parquet format, including the representation of geometries and the required additional metadata.


This is version 0.2.0 of the geoparquet specification.

Geometry columns

Geometry columns are stored using the BYTE_ARRAY parquet type. They are encoded as WKB. See the encoding section below for more details.


geoparquet files include additional metadata at two levels:

  1. File metadata indicating things like the version of this specification used
  2. Column metadata with additional metadata for each geometry column

These are both stored under a "geo" key in the parquet metadata (the FileMetaData::key_value_metadata) as a JSON-encoded UTF-8 string.

File metadata

All file-level metadata should be included under the "geo" key in the parquet metadata.

Field Name Type Description
version string REQUIRED The version of the geoparquet metadata standard used when writing.
primary_column string REQUIRED The name of the "primary" geometry column.
columns Map<key, Colum Metadata> REQUIRED Metadata about geometry columns, with each key is the name of a geometry column in the table.

At this level, additional implementation-specific fields (e.g. library name) are allowed, and thus readers should be robust in ignoring those.

Additional file metadata information


This indicates the "primary" or "active" geometry for systems that can store multiple geometries, but have a default geometry used for geospatial operations.


Version of the geoparquet spec used, currently 0.2.0

Column metadata

Each geometry column in the dataset must be included in the columns field above with the following content, keyed by the column name:

Field Name Type Description
encoding string REQUIRED Name of the geometry encoding format. Currently only 'WKB' is supported.
geometry_type string or [string] REQUIRED The geometry type(s) of all geometries, or 'Unknown' if they are not known.
crs string OPTIONAL WKT2 string representing the Coordinate Reference System (CRS) of the geometry. If the crs field is not included then the data in this column must be stored in longitude, latitude. In the case where a crs is not provided, CRS-aware implementations should assume a default value of OGC:CRS84 (longitude-latitude coordinates)
edges string OPTIONAL Name of the coordinate system for the edges. Must be one of 'planar' or 'spherical'. The default value is 'planar'.
bbox [number] OPTIONAL Bounding Box of the geometries in the file, formatted according to RFC 7946, section 5
epoch double OPTIONAL Coordinate epoch in case of a dynamic CRS, expressed as a decimal year.


The Coordinate Reference System (CRS) is an optional parameter for each geometry column defined in geoparquet format.

The CRS must be provided in WKT version 2, also known as WKT2. WKT2 has several revisions, this specification only supports WKT2_2019.

If CRS is not provided, then all coordinates in the geometry must use longitude, latitude to store their data. If an implementation is CRS-aware and needs a CRS representation of the data it should assume a default value is OGC:CRS84. It's equivalent to the well-known EPSG:4326 but changes the axis from latitude-longitude to longitude-latitude. The WKT2:2019 string for OGC:CRS84 is:

    ENSEMBLE["World Geodetic System 1984 ensemble",
        MEMBER["World Geodetic System 1984 (Transit)"],
        MEMBER["World Geodetic System 1984 (G730)"],
        MEMBER["World Geodetic System 1984 (G873)"],
        MEMBER["World Geodetic System 1984 (G1150)"],
        MEMBER["World Geodetic System 1984 (G1674)"],
        MEMBER["World Geodetic System 1984 (G1762)"],
        MEMBER["World Geodetic System 1984 (G2139)"],
        ELLIPSOID["WGS 84",6378137,298.257223563,
        AXIS["geodetic longitude (Lon)",east,
        AXIS["geodetic latitude (Lat)",north,
        SCOPE["Not known."],

Due to the large number of CRSes available and the difficulty of implementing all of them, we expect that a number of implementations will start without support for the optional crs field. Users are recommended to store their data in longitude, latitude (OGC:CRS84 or not including the crs field) for it to work with the widest number of tools. But data that is better served in particular projections can choose to use an alternate coordinate reference system. We expect many tools will support alternate CRSes, but encourage users to check to ensure their chosen tool supports their chosen crs.


In a dynamic CRS, coordinates of a point on the surface of the Earth may change with time. To be unambiguous, the coordinates must always be qualified with the epoch at which they are valid.

The optional "epoch" field allows to specify this in case the "crs" field defines a a dynamic CRS. The coordinate epoch is expressed as a decimal year (e.g. 2021.47). Currently, this specification only supports an epoch per column (and not per geometry).


This is the binary format that the geometry is encoded in. The string 'WKB', signifying Well Known Binary is the only current option, but future versions of the spec may support alternative encodings. This should be the "OpenGISĀ® Implementation Specification for Geographic information - Simple feature access - Part 1: Common architecture" WKB representation (using codes for 3D geometry types in the [1001,1007] range). This encoding is also consistent with the one defined in the "ISO/IEC 13249-3:2016 (Information technology - Database languages - SQL multimedia and application packages - Part 3: Spatial)" standard.

Note that the current version of the spec only allows for a subset of WKB: 2D or 3D geometries of the standard geometry types (the Point, LineString, Polygon, MultiPoint, MultiLineString, MultiPolygon, and GeometryCollection geometry types). This means that M values or non-linear geometry types are not yet supported.

Coordinate axis order

The axis order of the coordinates in WKB stored in a geoparquet follows the de facto standard for axis order in WKB and is therefore always (x, y) where x is easting or longitude and y is northing or latitude. This ordering explicitly overrides the axis order as specified in the CRS. This follows the precedent of GeoPackage, see the note in their spec.


This field captures the geometry type(s) of the geometries in the column, when known. Accepted geometry types are: "Point", "LineString", "Polygon", "MultiPoint", "MultiLineString", "MultiPolygon", "GeometryCollection".

In addition, the following rules are used:

It is expected that this field is strictly correct. For example, if having both polygons and multipolygons, it is not sufficient to specify "MultiPolygon", but it is expected to specify ["Polygon", "MultiPolygon"]. Or if having 3D points, it is not sufficient to specify "Point", but it is expected to list "Point Z".

Polygon winding

The winding order of polygons follows the GeoJSON spec. Polygon rings MUST follow the right-hand rule for orientation (counterclockwise external rings, clockwise internal rings). Traversing vertices of rings in order, the interior of the polygon is on the left.


This attribute indicates how to interpret the edges of the geometries: whether the line between two points is a straight cartesian line or the shortest line on the sphere (geodesic line). Available values are:

If no value is set, the default value to assume is 'planar'.


Bounding boxes are used to help define the spatial extent of each geometry column. Implementations of this schema may choose to use those bounding boxes to filter partitions (files) of a partitioned dataset.

The bbox, if specified, must be encoded with an array containing the minimum and maximum values of each dimension: [<xmin>, <ymin>, <xmax>, <ymax>]. This follows the GeoJSON specification (RFC 7946, section 5).

Additional information

You can find an example in the examples folder.