Spatial database explained

A spatial database is a general-purpose database (usually a relational database) that has been enhanced to include spatial data that represents objects defined in a geometric space, along with tools for querying and analyzing such data.

Most spatial databases allow the representation of simple geometric objects such as points, lines and polygons. Some spatial databases handle more complex structures such as 3D objects, topological coverages, linear networks, and triangulated irregular networks (TINs). While typical databases have developed to manage various numeric and character types of data, such databases require additional functionality to process spatial data types efficiently, and developers have often added geometry or feature data types.

Geographic database (or geodatabase) is a georeferenced spatial database, used for storing and manipulating geographic data (or geodata, i.e., data associated with a location on Earth), especially in geographic information systems (GIS). Almost all current relational and object-relational database management systems now have spatial extensions, and some GIS software vendors have developed their own spatial extensions to database management systems.

The Open Geospatial Consortium (OGC) developed the Simple Features specification (first released in 1997)[1] and sets standards for adding spatial functionality to database systems.[2] The SQL/MM Spatial ISO/IEC standard is a part of the structured query language and multimedia standard extending the Simple Features.[3]

Characteristics

The core functionality added by a spatial extension to a database is one or more spatial datatypes, which allow for the storage of spatial data as attribute values in a table.[4] Most commonly, a single spatial value would be a geometric primitive (point, line, polygon, etc.) based on the vector data model. The datatypes in most spatial databases are based on the OGC Simple Features specification for representing geometric primitives. Some spatial databases also support the storage of raster data. Because all geographic locations must be specified according to a spatial reference system, spatial databases must also allow for the tracking and transformation of coordinate systems. In many systems, when a spatial column is defined in a table, it also includes a choice of coordinate system, chosen from a list of available systems that is stored in a lookup table.

The second major functionality extension in a spatial database is the addition of spatial capabilities to the query language (e.g., SQL); these give the spatial database the same query, analysis, and manipulation operations that are available in traditional GIS software. In most relational database management systems, this functionality is implemented as a set of new functions that can be used in SQL SELECT statements. Several types of operations are specified by the Open Geospatial Consortium standard:

Some databases support only simplified or modified sets of these operations, especially in cases of NoSQL systems like MongoDB and CouchDB.

Spatial index

A spatial index is used by a spatial database to optimize spatial queries. Database systems use indices to quickly look up values by sorting data values in a linear (e.g. alphabetical) order; however, this way of indexing data is not optimal for spatial queries in two- or three-dimensional space. Instead, spatial databases use a spatial index designed specifically for multi-dimensional ordering.[5] Common spatial index methods include:

Spatial query

A spatial query is a special type of database query supported by spatial databases, including geodatabases. The queries differ from non-spatial SQL queries in several important ways. Two of the most important are that they allow for the use of geometry data types such as points, lines and polygons and that these queries consider the spatial relationship between these geometries.

The function names for queries differ across geodatabases. The following are a few of the functions built into PostGIS, a free geodatabase which is a PostgreSQL extension (the term 'geometry' refers to a point, line, box or other two or three dimensional shape):[7]

Function prototype: functionName (parameter(s)) : return type

Thus, a spatial join between a points layer of cities and a polygon layer of countries could be performed in a spatially-extended SQL statement as:

SELECT * FROM cities, countries WHERE ST_Contains(countries.shape, cities.shape)

The Intersect vector overlay operation (a core element of GIS software) could be replicated as:

SELECT ST_Intersection(veg.shape, soil.shape) int_poly, veg.*, soil.* FROM veg, soil where ST_Intersects(veg.shape, soil.shape)

Spatial database management systems

See main article: category.

List

Table of free systems especially for spatial data processing

DBS License Distributed Spatial objects Spatial functions PostgreSQL interface UMN MapServer interface Documentation Modifiable HDFS
Apache DrillApache License 2.0yesyesyes - Drill Geospatial Functions Documentation yesnoOfficial DocumentationANSI SQLyes
ArangoDBApache License 2.0yesyesyes - capabilities overview query language functionsnonoofficial documentationAQLno
GeoMesaApache License 2.0yesyes (Simple Features)yes (JTS)no (manufacturable with GeoTools)noparts of the functions, a few exampleswith Simple Feature Access in Java Virtual Machine and Apache Spark are all kinds of tasks solvableyes
H2 (H2GIS)LGPL 3 (since v1.3), GPL 3 beforenoyes (custom, no raster)Simple Feature Access and custom functions for H2Networkyesnoyes (homepage)SQLno
IngresGPL or proprietaryyes (if extension is installed)yes (custom, no raster)Geometry Engine, Open Source[21] nowith MapScriptjust brieflywith C and OMEno
Neo4J-spatial[22] GNU affero general public licensenoyes (Simple Features)yes (contain, cover, covered by, cross, disjoint, intersect, intersect window, overlap, touch, within and within distance)nonojust brieflyfork of JTSno
PostgreSQL with PostGISGNU General Public Licensenoyes (Simple Features and raster)yes (Simple Feature Access and raster functions)yesyesdetailedSQL, in connection with Rno
Postgres-XL with PostGISMozilla public license and GNU general public licenseyesyes (Simple Features and raster)yes (Simple Feature Access and raster functions)yesyesPostGIS: yes, Postgres-XL: brieflySQL, in connection with R or Tcl or Pythonno
Rasdamanserver GPL, client LGPL, enterprise proprietaryyesjust rasterraster manipulation with rasqlyeswith Web Coverage Service or Web Processing Servicedetailed wikiown defined function in enterprise editionno
RethinkDBAGPLyesyes
  • distance
  • getIntersecting
  • getNearest
  • includes
  • intersects
nonoofficial documentation[23] forkingno

See also

Further reading

External links

Notes and References

  1. Web site: OGC History (detailed) . McKee . Lance . 2016 . OGC . 2016-07-12 . [...] 1997 [...] OGC released the OpenGIS Simple Features Specification, which specifies the interface that enables diverse systems to communicate in terms of 'simple features' which are based on 2D geometry. The supported geometry types include points, lines, linestrings, curves, and polygons. Each geometric object is associated with a Spatial Reference System, which describes the coordinate space in which the geometric object is defined..
  2. http://www.opengeospatial.org OGC Homepage
  3. Book: Springer handbook of geographic information. limited. 2010. Springer. 9783540726807. Kresse. Wolfgang. 1.. Berlin. 82–83. Danko. David M..
  4. Web site: Yue . P. . Tan . Z. . DM-03 - Relational DBMS and their Spatial Extensions . GIS&T Body of Knowledge . UCGIS . 5 January 2023.
  5. Web site: Zhang . X. . Du . Z. . DM-66 Spatial Indexing . GIS&T Body of Knowledge . UCGIS . 5 January 2023.
  6. Book: Güting, Ralf Hartmut . Moving Objects Databases . Schneider . Markus . Morgan Kaufmann . 2005 . 9780120887996 . 262 . en.
  7. Web site: PostGIS Function Reference . PostGIS Manual . OSGeo . 4 January 2023.
  8. https://drill.apache.org/docs/gis-functions/
  9. Web site: Geo queries | Elasticsearch Guide [7.15] | Elastic.
  10. http://www.h2database.com/html/datatypes.html#geometry_type H2 geometry type documentation
  11. http://www.h2database.com/html/grammar.html#create_index H2 create spatial index documentation
  12. Web site: GeoSpatial – MonetDB . 4 March 2014.
  13. Web site: MySQL 5.5 Reference Manual - 12.17.1. Introduction to MySQL Spatial Support. https://web.archive.org/web/20130430004440/http://dev.mysql.com/doc/refman/5.5/en/gis-introduction.html. 2013-04-30. dead. 2013-05-01.
  14. Web site: 9.34. Geometry Data Types and Spatial Index Support . OpenLink Software . October 24, 2018.
  15. Web site: New Releases of Virtuoso Enterprise and Open Source Editions . 2018-10-23 . OpenLink Software . October 24, 2018.
  16. Web site: OGC Certified PostGIS.
  17. Web site: Command reference – Redis.
  18. Web site: SAP Help Portal.
  19. Web site: RTREE . tarantool.org . dead . https://web.archive.org/web/20141213221030/http://tarantool.org/doc/user_guide/RTREE.html . 2014-12-13.
  20. Web site: HP Vertica Place . 2 December 2015.
  21. Web site: GEOS.
  22. Web site: Neo4j Spatial is a library of utilities for Neo4j that facilitates the enabling of spatial operations on data. In particular you can add spatial indexes to already located data, and perform spatial. GitHub. 2019-02-18.
  23. Web site: ReQL command reference - RethinkDB.