Neogeography

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Neogeography (literally "new geography") is the use of geographical techniques and tools for personal and community activities or by a non-expert group of users. [1] Application domains of neogeography are typically not formal or analytical. [2]

Contents

From the point of view of human geography, neogeography could be also defined as the use of new specific information society tools, especially the Internet, to the aims and purposes of geography as an academic discipline; in all branches of geographical thought and incorporating contributions from outside of geography performed by non-specialist users in this discipline through the use of specific geographic ICT tools. This new definition, complementing previous ones, restores to academic geography the leading role proponents claim it should play when considering a renewal of the discipline with the rigor and right granted by its centuries-existence, but also includes the interesting social phenomenon of citizen participation in the geographical knowledge from its dual role: as undoubted possibility of enrichment for geography and as social phenomenon with geographic interest.[ citation needed ]

History

The term neogeography has been used since at least 1922. In the early 1950s in the U.S. it was a term used in the sociology of production & work. The French philosopher François Dagognet used it in the title of his 1977 book Une Epistemologie de l'espace concret: Neo-geographie. The word was first used in relation to the study of online communities in the 1990s by Kenneth Dowling, the Librarian of the City and County of San Francisco. [3] Immediate precursor terms in the industry press were: "the geospatial Web" and "the geoaware Web" (both 2005); "Where 2.0" (2005); "a dissident cartographic aesthetic" and "mapping and counter-mapping" (2006). [3] These terms arose with the concept of Web 2.0, around the increased public appeal of mapping and geospatial technologies that occurred with the release of such tools as "slippy maps" such as Google Maps, Google Earth, and also with the decreased cost of geolocated mobile devices such as GPS units. Subsequently, the use of geospatial technologies began to see increased integration with non-geographically focused applications.

The term neogeography was first defined in its contemporary sense by Randall Szott in 2006. He argued for a broad scope, to include artists, psychogeography, and more. The technically oriented aspects of the field, far more tightly defined than in Scott's definition, were outlined by Andrew Turner in his Introduction to Neogeography (O'Reilly, 2006). The contemporary use of the term, and the field in general, owes much of its inspiration to the locative media movement that sought to expand the use of location-based technologies to encompass personal expression and society. [3]

Traditional Geographic Information Systems historically have developed tools and techniques targeted towards formal applications that require precision and accuracy. By contrast, neogeography tends to apply to the areas of approachable, colloquial applications. The two realms can have overlap as the same problems are presented to different sets of users: experts and non-experts.[ citation needed ]

User-generated geographic content

Neogeography has also been connected [4] with the increase in user-generated geographic content, closely related to Volunteered Geographic Information. [5] This can be an active collection of data such as OpenStreetMap or passive collection of user-data such as Flickr tags for folksonomic toponyms. While involving non-trained volunteers in the data creation process, research proves users perceive volunteered geographic information as highly valuable and trustworthy. [6] [7] [8]

Discussion about the definition

There is currently much debate about the scope and application of neogeography in the web mapping, geography, and GIS fields. Some of this discussion considers neogeography to be the ease of use of geographic tools and interfaces while other points focus on the domains of application.

Neogeography is not limited to a specific technology and is not strictly web-based, so is not synonymous with web mapping though it is commonly conceived as such.

A number of geographers and geoinformatics scientists (such as Mike Goodchild [9] ) have expressed strong reservations about the term "neogeography". They say that geography is an established scientific discipline; uses such as mashups and tags in Google Earth are not scientific works, but are better described as Volunteered Geographic Information.

There are also a great many artists and inter-disciplinary practitioners involved in an engagement with new forms of mapping and locative art. [10] It is thus far wider than simply web mapping.

See also

Related Research Articles

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<span class="mw-page-title-main">Geomatics</span> Geographic data discipline

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". Under another definition, it consists of products, services and tools involved in the collection, integration and management of geographic (geospatial) data. It is also known as geomatic(s) engineering. Surveying engineering was the widely used name for geomatic(s) engineering in the past.

In computing, GeoServer is an open-source server written in Java that allows users to share, process and edit geospatial data. Designed for interoperability, it publishes data from any major spatial data source using open standards. GeoServer has evolved to become an easy method of connecting existing information to virtual globes such as Google Earth and NASA World Wind as well as to web-based maps such as OpenLayers, Leaflet, Google Maps and Bing Maps. GeoServer functions as the reference implementation of the Open Geospatial Consortium Web Feature Service standard, and also implements the Web Map Service, Web Coverage Service and Web Processing Service specifications.

A GIS software program is a computer program to support the use of a geographic information system, providing the ability to create, store, manage, query, analyze, and visualize geographic data, that is, data representing phenomena for which location is important. The GIS software industry encompasses a broad range of commercial and open-source products that provide some or all of these capabilities within various information technology architectures.

Geographic information science or geographical information science is the scientific discipline that studies geographic information, including how it represents phenomena in the real world, how it represents the way humans understand the world, and how it can be captured, organized, and analyzed. It can be contrasted with geographic information systems (GIS), which are the actual repositories of such data, the software tools for carrying out relevant tasks, and the profession of GIS users. That said, one of the major goals of GIScience is to find practical ways to improve GIS data, software, and professional practice. it is more focused on how gis is applied in real life

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<span class="mw-page-title-main">Web mapping</span> Process of using the maps delivered by geographic information systems (GIS) in World Wide Web

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<span class="mw-page-title-main">Ed Parsons</span>

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References

  1. Flanagin, A. J.; Metzger, M. J. (2008). "The credibility of volunteered geographic information". GeoJournal. 72 (3–4): 137–148. doi:10.1007/s10708-008-9188-y. S2CID   15975229.
  2. Turner, Andrew (2006). Introduction to Neogeography. Short Cuts. O'Reilly Media. p. 2. ISBN   978-0-596-52995-6.
  3. 1 2 3 "A short enquiry into the origins and uses of the term “neogeography”", D'log
  4. "Haklay, M., Singleton, A. and Parker, C., 2008. Web mapping 2.0: The neogeography of the GeoWeb. Geography Compass, 2(6), pp.2011-2039". CiteSeerX   10.1.1.456.5267 .{{cite journal}}: Cite journal requires |journal= (help)
  5. "Neogeography and the Palimpsests of Place: Web 2.0 and the Construction of a Virtual Earth ", M. Graham (2010). Journal of Economic And Social Geography (TESG)
  6. Parker, Christopher J.; May, Andrew; Mitchell, Val (2014-07-03). "User-centred design of neogeography: the impact of volunteered geographic information on users' perceptions of online map 'mashups'". Ergonomics. 57 (7): 987–997. doi:10.1080/00140139.2014.909950. ISSN   0014-0139. PMID   24827070. S2CID   13458260.
  7. May, Andrew; Parker, Christopher J.; Taylor, Neil; Ross, Tracy (December 2014). "Evaluating a concept design of a crowd-sourced 'mashup' providing ease-of-access information for people with limited mobility". Transportation Research Part C: Emerging Technologies. 49: 103–113. doi: 10.1016/j.trc.2014.10.007 .
  8. Parker, Christopher J.; May, Andrew; Mitchell, Val (August 2012). "Understanding Design with VGI using an Information Relevance Framework: Understanding VGI". Transactions in GIS. 16 (4): 545–560. doi:10.1111/j.1467-9671.2012.01302.x. S2CID   20100267.
  9. Goodchild (2009). "NeoGeography and the nature of geographic expertise".{{cite journal}}: Cite journal requires |journal= (help)
  10. "Search results - neogeography"
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