geo_line_densify()
Applies to: ✅ Microsoft Fabric ✅ Azure Data Explorer ✅ Azure Monitor ✅ Microsoft Sentinel
Converts planar lines or multiline edges to geodesics by adding intermediate points.
Syntax
geo_line_densify(lineString, tolerance, [ preserve_crossing ])
Learn more about syntax conventions.
Parameters
| Name | Type | Required | Description |
|---|---|---|---|
| lineString | dynamic |
✔️ | A LineString or MultiLineString in the GeoJSON format. |
| tolerance | int, long, or real | Defines maximum distance in meters between the original planar edge and the converted geodesic edge chain. Supported values are in the range [0.1, 10000]. If unspecified, the default value 10 is used. |
|
| preserve_crossing | bool |
If true, preserves edge crossing over antimeridian. If unspecified, the default value false is used. |
Returns
Densified line in the GeoJSON format and of a dynamic data type. If either the line or tolerance is invalid, the query will produce a null result.
Note
The geospatial coordinates are interpreted as represented by the WGS-84 coordinate reference system.
LineString definition
dynamic({"type": "LineString","coordinates": [[lng_1,lat_1], [lng_2,lat_2], ..., [lng_N,lat_N]]})
dynamic({"type": "MultiLineString","coordinates": [[line_1, line_2, ..., line_N]]})
- LineString coordinates array must contain at least two entries.
- The coordinates [longitude, latitude] must be valid. The longitude must be a real number in the range [-180, +180] and the latitude must be a real number in the range [-90, +90].
- The edge length must be less than 180 degrees. The shortest edge between the two vertices will be chosen.
Constraints
- The maximum number of points in the densified line is limited to 10485760.
- Storing lines in dynamic format has size limits.
Motivation
- GeoJSON format defines an edge between two points as a straight cartesian line while
geo_line_densify()uses geodesic. - The decision to use geodesic or planar edges might depend on the dataset and is especially relevant in long edges.
Examples
The following example densifies a road in Manhattan island. The edge is short and the distance between the planar edge and its geodesic counterpart is less than the distance specified by tolerance. As such, the result remains unchanged.
print densified_line = tostring(geo_line_densify(dynamic({"type":"LineString","coordinates":[[-73.949247, 40.796860],[-73.973017, 40.764323]]})))
Output
| densified_line |
|---|
| {"type":"LineString","coordinates":[[-73.949247, 40.796860], [-73.973017, 40.764323]]} |
The following example densifies an edge of ~130-km length
print densified_line = tostring(geo_line_densify(dynamic({"type":"LineString","coordinates":[[50, 50], [51, 51]]})))
Output
| densified_line |
|---|
| {"type":"LineString","coordinates":[[50,50],[50.125,50.125],[50.25,50.25],[50.375,50.375],[50.5,50.5],[50.625,50.625],[50.75,50.75],[50.875,50.875],[51,51]]} |
The following example returns a null result because of the invalid coordinate input.
print densified_line = geo_line_densify(dynamic({"type":"LineString","coordinates":[[300,1],[1,1]]}))
Output
| densified_line |
|---|
The following example returns a null result because of the invalid tolerance input.
print densified_line = geo_line_densify(dynamic({"type":"LineString","coordinates":[[1,1],[2,2]]}), 0)
Output
| densified_line |
|---|