Web mapping

Types

Analytical web maps

Animated and realtime

Collaborative web maps

• Google Map Maker
• Here Map Creator
• OpenStreetMap
• WikiMapia
• - a survey of Wikimedia movement web mapping proposals

  Online atlases

Static web maps

Web GIS in the cloud

Evolving paper cartography

• Web maps can easily deliver up to date information. If maps are generated automatically from databases, they can display information in almost realtime. They don't need to be printed, mastered and distributed. Examples:
• * A map displaying election results, as soon as the election results become available.
• * A traffic congestion map using traffic data collected by sensor networks.
• * A map showing the current locations of mass transit vehicles such as buses or trains, allowing patrons to minimize their waiting time at stops or stations, or be aware of delays in service.
• * Weather maps, such as NEXRAD.
• Software and hardware infrastructure for web maps is cheap. Web server hardware is cheaply available and many open source tools exist for producing web maps. Geodata, on the other hand, is not; satellites and fleets of automobiles use expensive equipment to collect the information on an ongoing basis. Perhaps owing to this, many people are still reluctant to publish geodata, especially in places where geodata are expensive. They fear copyright infringements by other people using their data without proper requests for permission.
• Product updates can easily be distributed. Because web maps distribute both logic and data with each request or loading, product updates can happen every time the web user reloads the application. In traditional cartography, when dealing with printed maps or interactive maps distributed on offline media, a map update takes serious efforts, triggering a reprint or remastering as well as a redistribution of the media. With web maps, data and product updates are easier, cheaper, and faster, and occur more often. Perhaps owing to this, many web maps are of poor quality, both in symbolization, content and data accuracy.
• Web maps can combine distributed data sources. Using open standards and documented APIs one can integrate different data sources, if the projection system, map scale and data quality match. The use of centralized data sources removes the burden for individual organizations to maintain copies of the same data sets. The downside is that one has to rely on and trust the external data sources. In addition, with detailed information available and the combination of distributed data sources, it is possible to find out and combine a lot of private and personal information of individual persons. Properties and estates of individuals are now accessible through high resolution aerial and satellite images throughout the world to anyone.
• Web maps allow for personalization. By using user profiles, personal filters and personal styling and symbolization, users can configure and design their own maps, if the web mapping systems supports personalization. Accessibility issues can be treated in the same way. If users can store their favourite colors and patterns they can avoid color combinations they can't easily distinguish. Despite this, as with paper, web maps have the problem of limited screen space, but more so. This is in particular a problem for mobile web maps; the equipment carried usually has a very small screen, making it less likely that there is room for personalisation.
• Web maps enable collaborative mapping similar to web mapping technologies such as DHTML/Ajax, SVG, Java, Adobe Flash, etc. enable distributed data acquisition and collaborative efforts. Examples for such projects are the OpenStreetMap project or the Google Earth community. As with other open projects, quality assurance is very important, however, and the reliability of the internet and web server infrastructure is not yet good enough. Especially if a web map relies on external, distributed data sources, the original author often cannot guarantee the availability of the information.
• Web maps support hyperlinking to other information on the web. Just like any other web page or a wiki, web maps can act like an index to other information on the web. Any sensitive area in a map, a label text, etc. can provide hyperlinks to additional information. As an example a map showing public transport options can directly link to the corresponding section in the online train time table. However, development of web maps is complicated enough as it is: Despite the increasing availability of free and commercial tools to create web mapping and web GIS applications, it is still a more complex task to create interactive web maps than to typeset and print images. Many technologies, modules, services and data sources have to be mastered and integrated The development and debugging environments of a conglomerate of different web technologies is still awkward and uncomfortable.

  History

• 1989: Birth of the WWW, WWW invented at CERN for the exchange of research documents.
• 1993: Xerox PARC Map Viewer, The first mapserver based on CGI/Perl, allowed reprojection styling and definition of map extent.
• 1994: , the first interactive web mapping mashup was released, based on the Xerox PARC map view.
• 1994: , The first version of the National Atlas of Canada was released. Can be regarded as the first online atlas.
• 1995: , The prototype version of the Gazetteer for Scotland was released. The first geographical database with interactive mapping.
• 1995: Tiger Mapping Service, from the U.S. Census Bureau, the first national street-level web map, and the first major web map from the U.S. government.
• 1995: MapGuide, First introduced as Argus MapGuide.
• 1996: Center for Advanced Spatial Technologies Interactive Mapper, Based on CGI/C shell/GRASS would allow the user to select a geographic extent, a raster base layer, and number of vector layers to create personalized map.
• 1996: Mapquest, The first popular online Address Matching and Routing Service with mapping output.
• 1996: MultiMap, The UK-based MultiMap website launched offering online mapping, routing and location based services. Grew into one of the most popular UK web sites.
• 1996: Geomedia WebMap 1.0, First version of , already supports vector graphics through the use of ActiveCGM.
• 1996: MapGuide, Autodesk acquired Argus Technologies.and introduced Autodesk MapGuide 2.0.
• 1997: US Online National Atlas Initiative, The USGS received the mandate to coordinate and create the online National Atlas of the United States of America .
• 1997: UMN MapServer 1.0, Developed at the University of Minnesota as Part of the NASA ForNet Project. Grew out of the need to deliver remote sensing data across the web for foresters.
• 1997: ' - GeoInfo Solutions developed the first Java GIS Applet called 'JavaMap'. The application supported the export and conversion of MapInfo data for display in the thematic mapping tool for the web. GeoinfoMapper was demonstrated at the Victoria Computer Show in 1997 and referenced in the Universal Locator project at UC Berkeley School of Information.
• 1998: Terraserver USA, A Web Map Service serving aerial images and USGS DRGs was released. One of the first popular WMS. This service is a joint effort of USGS, Microsoft and HP.
• 1998: UMN MapServer 2.0, Added reprojection support.
• 1998: ', ESRI's entry into the web mapping business.
• 1999: National Atlas of Canada, 6th edition, This new version was launched at the ICA 1999 conference in Ottawa. Introduced many new features and topics. Is being improved gradually, since then, and kept up-to-date with technical advancements.
• 2000: ArcIMS 3.0, The first public release of ESRI's ArcIMS.
• 2000: ESRI Geography Network, ESRI founded Geography Network to distribute data and web map services.
• 2000: UMN MapServer 3.0, Developed as part of the NASA Project. This is also the first public, open source release of UMN Mapserver. Added raster support and support for TrueType fonts.
• 2001: GeoServer, starts of the GeoServer project
• 2001: MapScript 1.0 for UMN MapServer, Adds a lot of flexibility to UMN MapServer solutions.
• 2001: , A highly interactive online atlas, the first to be based on the SVG standard.
• 2002: UMN MapServer 3.5, Added support for PostGIS and ArcSDE. Version 3.6 adds initial OGC WMS support.
• 2002: ArcIMS 4.0, Version 4 of the ArcIMS web map server.
• 2003: NASA World Wind, NASA World Wind Released. An open virtual globe that loads data from distributed resources across the internet. Terrain and buildings can be viewed 3 dimensionally. The markup language allows users to integrate their own personal content. This virtual globe needs special software and doesn't run in a web browser.
• 2003: UMN MapServer 4.0, Adds 24bit raster output support and support for PDF and SWF.
• 2004: OpenStreetMap, an open source, open content world map founded by Steve Coast.
• 2004: Yandex Maps is founded.
• 2005: Google Maps, The first version of Google Maps. Based on raster tiles organized in a quad tree scheme, data loading done with XMLHttpRequests. This mapping application became highly popular on the web, also because it allowed other people to integrate google map services into their own website.
• 2005: UMN MapServer introduced as open source by the Open Source Geospatial Foundation. UMN MapServer 4.6, Adds support for SVG.
• 2005: MapGuide Open Source introduced as open source by Autodesk
• 2005: Google Earth, The first version of Google Earth was released building on the virtual globe metaphor. Terrain and buildings can be viewed 3 dimensionally. The KML markup language allows users to integrate their own personal content. This virtual globe needs special software and doesn't run in a web browser.
• 2005: OpenLayers, the first version of the open source Javascript library OpenLayers.
• 2006: WikiMapia Launched
• 2009: Nokia made Ovi Maps free on its smartphones.
• 2010: MapBox was founded
• 2012: Apple removed Google Maps as the default mapping app and replaces it with its own mapping app.
• 2013: MapBox announced Vector Tiles for MapBox Streets

  Technologies

• Spatial databases are usually object relational databases enhanced with geographic data types, methods and properties. They are necessary whenever a web mapping application has to deal with dynamic data or with huge amount of geographic data. Spatial databases allow spatial queries, sub selects, reprojections, and geometry manipulations and offer various import and export formats. PostGIS is a prominent example; it is open source. MySQL also implements some spatial features. Oracle Spatial, Microsoft SQL Server, and IBM DB2 are the commercial alternatives. The Open Geospacial Consortium's specification "Simple Features" is a standard geometry data model and operator set for spatial databases. Part 2 of the specification defines an implementation using SQL.
• Tiled web maps display rendered maps made up of raster image "tiles".
• Vector tiles are also becoming more popular—Google and Apple have both transitioned to vector tiles. Mapbox.com also offers vector tiles. This new style of web mapping is resolution independent, and also has the advantage of dynamically showing and hiding features depending on the interaction.
• WMS servers generate maps using parameters for user options such as the order of the layers, the styling and symbolization, the extent of the data, the data format, the projection, etc. The OGC standardized these options. Another WMS server standard is the Tile Map Service. Standard image formats include PNG, JPEG, GIF and SVG.

  Courses

• Open Web Mapping, offered by Pennsylvania State University, "https://www.e-education.psu.edu/geog585/"
• Web Mapping, offered by Oregon State University, "https://github.com/jakobzhao/geog371"
• Programming for Web Mapping, offered by University of Kentucky, "http://newmapsplus.uky.edu/new-maps-plus-programs-and-online-courses#map672"
• Web Mapping, offered by University of Oregon