Geomatics

Geomatics is defined in the ISO/TC 211 series of standards as the "discipline concerned with the collection, distribution, storage, analysis, processing, presentation of geographic data or geographic information".[1] Under another definition, it consists of products, services and tools involved in the collection, integration and management of geographic (geospatial) data.[2] It is also known as geomatic(s) engineering (geodesy and geoinformatics engineering or geospatial engineering). Surveying engineering was the widely used name for geomatic(s) engineering in the past.

Not to be confused with Geoinformatics.
Geodesy
Fundamentals
Concepts
Technologies
Standards (history)
NGVD 29 Sea Level Datum 1929
OSGB36 Ordnance Survey Great Britain 1936
SK-42 Systema Koordinat 1942 goda
ED50 European Datum 1950
SAD69 South American Datum 1969
GRS 80 Geodetic Reference System 1980
ISO 6709 Geographic point coord. 1983
NAD 83 North American Datum 1983
WGS 84 World Geodetic System 1984
NAVD 88 N. American Vertical Datum 1988
ETRS89 European Terrestrial Ref. Sys. 1989
GCJ-02 Chinese obfuscated datum 2002
Geo URI Internet link to a point 2010
A surveyor's shed showing equipment used for geomatics

History and etymology

The term was proposed in French ("géomatique") at the end of the 1960s by scientist Bernard Dubuisson to reflect at the time recent changes in the jobs of surveyor and photogrammetrist.[3] The term was first employed in a French Ministry of Public Works memorandum dated 1 June 1971 instituting a "standing committee of geomatics" in the government.[4]

The term was popularised in English by French-Canadian surveyor Michel Paradis in his The little Geodesist that could article, in 1981 and in a keynote address at the centennial congress of the Canadian Institute of Surveying (now known as the Canadian Institute of Geomatics) in April 1982. He claimed that at the end of the 20th century the needs for geographical information would reach a scope without precedent in history and that, in order to address these needs, it was necessary to integrate in a new discipline both the traditional disciplines of land surveying and the new tools and techniques of data capture, manipulation, storage and diffusion.[5]

Geomatics includes the tools and techniques used in land surveying, remote sensing, cartography, geographic information systems (GIS), global-navigation satellite systems (GPS, GLONASS, Galileo, Compass), photogrammetry, geophysics, geography, and related forms of earth mapping. The term was originally used in Canada but has since been adopted by the International Organization for Standardization, the Royal Institution of Chartered Surveyors, and many other international authorities, although some (especially in the United States) have shown a preference for the term geospatial technology,[6] which may be defined as synonym of "geospatial information and communications technology".[7]

Although many definitions of geomatics, such as the above, appear to encompass the entire discipline relating to geographic information – including geodesy, geographic information systems, remote sensing, satellite navigation, and cartography –, the term is almost exclusively restricted to the perspective of surveying and engineering toward geographic information. Geoinformatics has been proposed as an alternative comprehensive term, but its use is only common in some parts of the world, especially Europe.

The related field of hydrogeomatics covers the area associated with surveying work carried out on, above or below the surface of the sea or other areas of water. The older term of hydrographics was considered too specific to the preparation of marine charts, and failed to include the broader concept of positioning or measurements in all marine environments.

A growing number of university departments which were once titled "surveying", "survey engineering" or "topographic science" have re-titled themselves using the terms "geomatics" or "geomatics engineering", while others have switched to program titles such as "spatial information technology", and similar names.[8][9]

The rapid progress and increased visibility of geomatics since the 1990s has been made possible by advances in computer hardware, computer science, and software engineering, as well as by airborne and space observation remote-sensing technologies.

Science
See also: Geographic information science

Geospatial science or spatial information science is an academic discipline incorporating fields such as surveying, geographic information systems, hydrography and cartography. Spatial science is typically concerned with the measurement, management, analysis and display of spatial information describing the Earth, its physical features and the built environment.[10]

The term spatial science or spatial sciences is primarily used in Australia. Australian universities which offer degrees in spatial science include Curtin University,[11] the University of Tasmania,[12] the University of Adelaide,[13]Melbourne University[14] and RMIT University.[15]

In the U.S., Texas A&M University offers a bachelor's degree in Spatial Sciences and is home to its own Spatial Sciences Laboratory.[16] Beginning in 2012, the University of Southern California started to place more emphasis on the spatial science branch of its geography department, with traditional human and physical geography courses and concentrations either not being offered on a regular basis or phased out. In place, the university now offers graduate programs strictly related to spatial science and its geography department offers a spatial science minor rather than the original geography major.[17]

Spatial information practitioners within the Asia-Pacific region are represented by the professional body called the Surveying and Spatial Sciences Institute (SSSI).[18]

Engineering

Geomatic(s) Engineering, Geodesy and Geoinformatics Engineering or Geospatial Engineering is a rapidly developing engineering discipline that focuses on spatial information (i.e. information that has a location). The location is the primary factor used to integrate a very wide range of data for spatial analysis and visualization. Geomatics engineers apply engineering principles to spatial information and implement relational data structures involving measurement sciences, thus using geomatics and acting as spatial information engineers. Geomatics engineers manage local, regional, national and global spatial data infrastructures. Geomatics Engineering also involves aspects of Computer Engineering, Software Engineering and Civil Engineering.

Geomatics is a field that incorporates several others such as the older field of land surveying engineering along with many other aspects of spatial data management ranging from data science and cartography to geography. Following the advanced developments in digital data processing, the nature of the tasks required of the professional land surveyor has evolved significantly in recent years, and for more and more people the term "surveying" no longer accurately covers the whole range of tasks that the profession deals with. As our societies become more complex, information with a spatial position associated with it becomes more critical to decision-making, both from a personal and a business perspective, and also from a community and a large-scale governmental viewpoint.

Therefore, the geomatics engineer can be involved in an extremely wide variety of information gathering activities and applications. Geomatics engineers design, develop, and operate systems for collecting and analyzing spatial information about the land, the oceans, natural resources, and manmade features.

The more traditional land surveying strand of geomatics engineering is concerned with the determination and recording of boundaries and areas of real property parcels, and the preparation and interpretation of legal land descriptions. The tasks more closely related to civil engineering include the design and layout of public infrastructure and urban subdivisions, and mapping and control surveys for construction projects.

Geomatics engineers serve society by collecting, monitoring, archiving, and maintaining diverse spatial data infrastructures. Geomatics engineers utilize a wide range of technologically advanced tools such as digital theodolite/distance meter total stations, Global Positioning System (GPS) equipment, digital aerial imagery (both satellite and air-borne), and computer-based geographic information systems (GIS). These tools enable the geomatics engineer to gather, process, analyze, visualize and manage spatially related information to solve a wide range of technical and societal problems.

Geomatics engineering is the field of activity that integrates the acquisition, processing, analysis, display and management of spatial information. It is an exciting and new grouping of subjects in the spatial and environmental information sciences with a broad range of employment opportunities as well as offering challenging pure and applied research problems in a vast range of interdisciplinary fields.

In different schools and in different countries the same education curriculum is administered with the name surveying in some, and in others with the names geomatics, civil engineering surveying, geomatics engineering, geospatial (information) engineering, surveying engineering, or geodesy and geoinformatics. While these occupations were at one time often taught in civil engineering education programs, more and more universities include the departments relevant for geo-data sciences under informatics, computer science or applied mathematics. These facts demonstrate the breadth, depth and scope of the highly interdisciplinary nature of geomatics engineering. The job of geospatial engineer is well established in the U.S. military.[19][20]

Applications

Application areas include:

Areas of knowledge

Geomatics integrates science and technology from both new and traditional disciplines:

References
  1. ISO/TR 19122:2004(en) Geographic information/Geomatics — Qualification and certification of personnel
  2. "About Us". Applied Geomatics Research Laboratory. Retrieved 2 April 2018.
  3. "ACSG - Association canadienne des sciences géomatiques (Section Champlain) /// Des références utiles en géomatique". acsg-champlain.scg.ulaval.ca. Retrieved 2019-11-04.
  4. Arrêté du 27 décembre 1994 relatif à la terminologie de la télédétection aérospatiale, retrieved 2019-11-04
  5. Paradis, Michel (September 1981). "De l'arpentage à la géomatique". Le Géomètre Canadien (in French). 35 (3): 262.
  6. Boehm, Richard G.; Mohan, Audrey (2010). "Geospatial Technology: Curricular Keystone of Applied Geography". International Journal of Applied Geospatial Research. 1 (1): 26–39. doi:10.4018/jagr.2010071602. ISSN 1947-9654.
  7. Scholten, H.J.; Velde, R.; van Manen, N. (2009). Geospatial Technology and the Role of Location in Science. GeoJournal Library. Springer Netherlands. p. 1. ISBN 978-90-481-2620-0. Retrieved 2022-01-28.
  8. "Geomatics engineering & geographic information systems (GIS)". University of Colorado Denver- College of Engineering. University of Colorado Denver. Retrieved October 3, 2021.
  9. "White Mountains Community College- Spatial Information Technology Transcript Checklist". PDFFiller. PDFFiller. Retrieved October 3, 2021.
  10. "Queensland University of Technology, Undergratuate Program - Spatial Science (Surveying)". Archived from the original on 2008-07-19. Retrieved 2008-06-14.
  11. "Curtin University - Spatial science courses". Archived from the original on 2015-09-10. Retrieved 2016-07-31.
  12. University of Tasmania, Centre for Spatial Information Science, Courses Archived 2008-07-25 at the Wayback Machine
  13. "University of Adelaide, Major in Ecology and Spatial Science" (PDF). adelaide.edu.au. Archived from the original (PDF) on 21 August 2014. Retrieved 2 April 2018.
  14. Melbourne University - Spatial Information Science
  15. "Surveying and geospatial sciences - RMIT University".
  16. Texas A&M University, Spatial Sciences Laboratory Archived 2008-09-05 at archive.today
  17. "Archived copy". Archived from the original on 2012-11-24. Retrieved 2012-10-20.{{cite web}}: CS1 maint: archived copy as title (link)
  18. Surveying and Spatial Sciences Institute (SSSI)
  19. "Geospatial Engineer Jobs (12Y)". goarmy.com. Retrieved 2 April 2018.
  20. "12Y Geospatial Engineer - National Guard". www.nationalguard.com. Retrieved 2 April 2018.

Further reading
  • Geomatics Canada Ottawa: Natural Resources Canada ISSN 1491-5480
  • Dermanis, Athanasios; Grün, Armin; Sansò, Fernando (2000). Geomatic Methods for the Analysis of Data in the Earth Sciences. New York: Springer. ISBN 978-3-540-67476-4.
  • Kavanagh, Barry F. (2003). Geomatics. Prentice Hall. ISBN 978-0-130-32289-0.
  • Yvan Bédard, "Geomatics" in Karen Kemp (2008), Encyclopedia of Geographic Information Science, Sage.
  • Yvan Bédard (2007),“Geomatics”: 26 years of history already!, Geomatica, 61(3):269-272.
  • Gomarasca, Mario A. (2009). Basics of Geomatics. Springer. ISBN 978-1-402-09014-1.
    • "Geomatics", Chap. 1 in Mario A. Gomarasca (2009) Basics of Geomatics, Springer.
  • "Geomatics", sec. 1.3 in Mathias Lemmens (2011), Geo-information: Technologies, Applications and the Environment, Springer.
  • Ogaja, Clement (2016). Geomatics Engineering: A Practical Guide to Project Design. CRC Press. ISBN 978-1-439-89511-5.
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