Participatory GIS

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Participatory GIS (PGIS) or public participation geographic information system (PPGIS) is a participatory approach to spatial planning and spatial information and communications management. [1] [2]

Contents

PGIS combines Participatory Learning and Action (PLA) methods with geographic information systems (GIS). [3] PGIS combines a range of geo-spatial information management tools and methods such as sketch maps, participatory 3D modelling (P3DM), aerial photography, satellite imagery, and global positioning system (GPS) data to represent peoples' spatial knowledge in the forms of (virtual or physical) two- or three-dimensional maps used as interactive vehicles for spatial learning, discussion, information exchange, analysis, decision making and advocacy. [4] Participatory GIS implies making geographic technologies available to disadvantaged groups in society in order to enhance their capacity in generating, managing, analysing and communicating spatial information.

PGIS practice is geared towards community empowerment through measured, demand-driven, user-friendly and integrated applications of geo-spatial technologies.[ citation needed ] GIS-based maps and spatial analysis become major conduits in the process. A good PGIS practice is embedded into long-lasting spatial decision-making processes, is flexible, adapts to different socio-cultural and bio-physical environments, depends on multidisciplinary facilitation and skills and builds essentially on visual language. The practice integrates several tools and methods whilst often relying on the combination of 'expert' skills with socially differentiated local knowledge. It promotes interactive participation of stakeholders in generating and managing spatial information and it uses information about specific landscapes to facilitate broadly-based decision making processes that support effective communication and community advocacy.

If appropriately utilized, [5] the practice could exert profound impacts on community empowerment, innovation and social change. [6] More importantly, by placing control of access and use of culturally sensitive spatial information in the hands of those who generated them, PGIS practice could protect traditional knowledge and wisdom from external exploitation.

PPGIS is meant to bring the academic practices of GIS and mapping to the local level in order to promote knowledge production by local and non-governmental groups. [7] The idea behind PPGIS is empowerment and inclusion of marginalized populations, who have little voice in the public arena, through geographic technology education and participation. PPGIS uses and produces digital maps, satellite imagery, sketch maps, and many other spatial and visual tools, to change geographic involvement and awareness on a local level. The term was coined in 1996 at the meetings of the National Center for Geographic Information and Analysis (NCGIA). [8] [9] [10]

Debate

Attendees to the Mapping for Change International Conference on Participatory Spatial Information Management and Communication conferred to at least three potential implications of PPGIS; it can: (1) enhance capacity in generating, managing, and communicating spatial information; (2) stimulate innovation; and ultimately; (3) encourage positive social change. [11] [12] This reflects on the rather nebulous definition of PPGIS as referenced in the Encyclopedia of GIS [13] which describes PPGIS as having a definition problem.

There are a range of applications for PPGIS. The potential outcomes can be applied from community and neighborhood planning and development to environmental and natural resource management. Marginalized groups, be they grassroots organizations to indigenous populations could benefit from GIS technology.

Governments, non-government organizations and non-profit groups are a big force behind many programs. The current extent of PPGIS programs in the US has been evaluated by Sawicki and Peterman. [14] They catalog over 60 PPGIS programs who aid in "public participation in community decision making by providing local-area data to community groups," in the United States. [15] :24 The organizations providing these programs are mostly universities, local chambers of commerce, non-profit foundations.

In general, neighborhood empowerment groups can form and gain access to information that is normally very easy for the official government and planning offices to obtain. It is easier for this to happen than for individuals of lower-income neighborhoods just working by themselves. There have been several projects where university students help implement GIS in neighborhoods and communities. It is believed[ by whom? ] that access to information is the doorway to more effective government for everybody and community empowerment. In a case study of a group in Milwaukee, residents of an inner city neighborhood became active participants in building a community information system, learning to access public information and create and analyze new databases derived from their own surveys, all with the purpose of making these residents useful actors in city management and in the formation of public policy. [16] In many cases, there are providers of data for community groups, but the groups may not know that such entities exist. Getting the word out would be beneficial.[ citation needed ]

Some of the spatial data that the neighborhood wanted was information on abandoned or boarded-up buildings and homes, vacant lots, and properties that contained garbage, rubbish and debris that contributed to health and safety issues in the area. They also appreciated being able to find landlords that were not keeping up the properties. The university team and the community were able to build databases and make maps that would help them find these areas and perform the spatial analysis that they needed. Community members learned how to use the computer resources, ArcView 1.0, and build a theme or land use map of the surrounding area. They were able to perform spatial queries and analyze neighborhood problems. Some of these problems included finding absentee landlords and finding code violations for the buildings on the maps. [16]

Approaches

There are two approaches to PPGIS use and application. These two perspectives, top–down and bottom–up, are the currently debated schism in PPGIS.

Top-down

According to Sieber (2006), PPGIS was first envisioned as a means of mapping individuals by many social and economic demographic factors in order to analyze the spatial differences in access to social services. She refers to this kind of PPGIS as top-down, being that it is less hands on for the public, but theoretically serves the public by making adjustments for the deficiencies, and improvements in public management. [17]

Bottom-up

A current trend with academic involvement in PPGIS, is researching existing programs, and or starting programs in order to collect data on the effectiveness of PPGIS. Elwood (2006) in The Professional Geographer, talks in depth about the "everyday inclusions, exclusions, and contradictions of Participatory GIS research." [18] The research is being conducted in order to evaluate if PPGIS is involving the public equally. In reference to Sieber's top-down PPGIS, this is a counter method of PPGIS, rightly referred to as bottom-up PPGIS. Its purpose is to work with the public to let them learn the technologies, then producing their own GIS.

Public participation GIS is defined by Sieber as the use of geographic information systems to broaden public involvement in policymaking as well as to the value of GIS to promote the goals of nongovernmental organizations, grassroots groups and community-based organizations. [17] It would seem on the surface that PPGIS, as it is commonly referred to, in this sense would be of a beneficial nature to those in the community or area that is being represented. But in truth only certain groups or individuals will be able to obtain the technology and use it. Is PPGIS becoming more available to the underprivileged sector of the community? The question of "who benefits?" should always be asked, and does this harm a community or group of individuals.

The local, participatory management of urban neighborhoods usually follows on from 'claiming the territory', and has to be made compatible with national or local authority regulations on administering, managing and planning urban territory. [19] PPGIS applied to participatory community/neighborhood planning has been examined by many others. [20] [21] [22] Specific attention has been given to applications such as housing issues [23] or neighborhood revitalization. [24] Spatial databases along with the P-mapping are used to maintain a public records GIS or community land information systems. [25] These are just a few of the uses of GIS in the community.

Examples

Public Participation in decision making processes works not only to identify areas of common values or variability, but also as an illustrative and instructional tool. One example of effective dialogue and building trust between the community and decision makers comes from pre-planning for development in the United Kingdom. It involves using GIS and multi-criteria decision analysis (MCDA) to make a decision about wind farm siting. This method hinges upon taking all stakeholder perspectives into account to improve chances of reaching consensus . This also creates a more transparent process and adds weight to the final decision by building upon traditional methods such as public meetings and hearings, surveys, focus groups, and deliberative processes enabling participants more insights and more informed opinions on environmental issues. [26]

Collaborative processes that consider objective and subjective inputs have the potential to efficiently address some of the conflict between development and nature as they involve a fuller justification by wind farm developers for location, scale, and design. Spatial tools such as creation of 3D view sheds offer participants new ways of assessing visual intrusion to make a more informed decision. Higgs et al. [26] make a very telling statement when analyzing the success of this project – "the only way of accommodating people's landscape concerns is to site wind farms in places that people find more acceptable". This implies that developers recognize the validity of citizens' concerns and are willing to compromise in identifying sites where wind farms will not only be successful financially, but also successful politically and socially. This creates greater accountability and facilitates the incorporation of stakeholder values to resolve differences and gain public acceptance for vital development projects.

In another planning example, Simao et al. [27] analyzed how to create sustainable development options with widespread community support. They determined that stakeholders need to learn likely outcomes that result from stated preferences, which can be supported through enhanced access to information and incentives to increase public participation. Through a multi-criteria spatial decision support system stakeholders were able to voice concerns and work on a compromise solution to have final outcome accepted by majority when siting wind farms. This differs from the work of Higgs et al. in that the focus was on allowing users to learn from the collaborative process, both interactively and iteratively about the nature of the problem and their own preferences for desirable characteristics of solution.

This stimulated sharing of opinions and discussion of interests behind preferences. After understanding the problem more fully, participants could discuss alternative solutions and interact with other participants to come to a compromise solution. [27] Similar work has been done to incorporate public participation in spatial planning for transportation system development, [28] and this method of two-way benefits is even beginning to move towards web-based mapping services to further simplify and extend the process into the community. [29]

See also

Related Research Articles

<span class="mw-page-title-main">Geographic information system</span> System to capture, manage and present geographic data

A geographic information system (GIS) consists of integrated computer hardware and software that store, manage, analyze, edit, output, and visualize geographic data. Much of this often happens within a spatial database, however, this is not essential to meet the definition of a GIS. In a broader sense, one may consider such a system also to include human users and support staff, procedures and workflows, the body of knowledge of relevant concepts and methods, and institutional organizations.

<span class="mw-page-title-main">Public participation (decision making)</span> Extent to which societies encourage the people to share in organizational decision-making

Citizen participation or public participation in social science refers to different mechanisms for the public to express opinions—and ideally exert influence—regarding political, economic, management or other social decisions. Participatory decision-making can take place along any realm of human social activity, including economic, political, management, cultural or familial.

<span class="mw-page-title-main">Crime mapping</span> Diagram showing crime incident patterns

Crime mapping is used by analysts in law enforcement agencies to map, visualize, and analyze crime incident patterns. It is a key component of crime analysis and the CompStat policing strategy. Mapping crime, using Geographic Information Systems (GIS), allows crime analysts to identify crime hot spots, along with other trends and patterns.

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.

Public participation, also known as citizen participation or patient and public involvement, is the inclusion of the public in the activities of any organization or project. Public participation is similar to but more inclusive than stakeholder engagement.

<span class="mw-page-title-main">Participatory rural appraisal</span> Process in international development

Participatory rural appraisal (PRA) is an approach used by non-governmental organizations (NGOs) and other agencies involved in international development. The approach aims to incorporate the knowledge and opinions of rural people in the planning and management of development projects and programmes.

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

Web mapping or an online mapping is the process of using, creating, and distributing maps on the World Wide Web, usually through the use of Web geographic information systems. A web map or an online map is both served and consumed, thus, web mapping is more than just web cartography, it is a service where consumers may choose what the map will show.

<span class="mw-page-title-main">Participatory planning</span> Decentralized, whole community-based urban design process

Participatory planning is an urban planning paradigm that emphasizes involving the entire community in the community planning process. Participatory planning emerged in response to the centralized and rationalistic approaches that defined early urban planning work.

Collaborative mapping, also known as citizen mapping, is the aggregation of Web mapping and user-generated content, from a group of individuals or entities, and can take several distinct forms. With the growth of technology for storing and sharing maps, collaborative maps have become competitors to commercial services, in the case of OpenStreetMap, or components of them, as in Google Map Maker Waze and Yandex Map Editor.

Traditional knowledge geographic information systems (GIS) are the data, techniques, and technologies designed to document and utilize local knowledges in communities around the world. Traditional knowledge is information that encompasses the experiences of a particular culture or society. Traditional knowledge GIS differ from ordinary cognitive maps in that they express environmental and spiritual relationships among real and conceptual entities. This toolset focuses on cultural preservation, land rights disputes, natural resource management, and economic development.

Volunteered geographic information (VGI) is the harnessing of tools to create, assemble, and disseminate geographic data provided voluntarily by individuals. VGI is a special case of the larger phenomenon known as user-generated content, and allows people to have a more active role in activities such as urban planning and mapping.

<span class="mw-page-title-main">Participatory 3D modelling</span> Community-based mapping method

Participatory 3D modelling (P3DM) is a community-based mapping method which integrates local spatial knowledge with data on elevation of the land and depth of the sea to produce stand-alone, scaled and geo-referenced relief models. Essentially based on local spatial knowledge, land use and cover, and other features are depicted by informants on the model by the use of pushpins (points), yarns (lines) and paints (polygons). On completion, a scaled and geo-referenced grid is applied to facilitate data extraction or importation. Data depicted on the model are extracted, digitised and plotted. On completion of the exercise the model remains with the community.

Online land planning is a collaborative process in which sustainable development practices and design professionals from across the world are networked to provide advice and solutions on urban design and land planning issues. The target audience includes property owners, communities, businesses and government agencies that have limited access, time, finances or personnel to make informed decisions about land use. In many cases, this approach provides electronic documents that become the catalyst to rebuild after natural or man-made spur rural community development and stimulate or create a new microeconomy.

Geographic information systems (GISs) and geographic information science (GIScience) combine computer-mapping capabilities with additional database management and data analysis tools. Commercial GIS systems are very powerful and have touched many applications and industries, including environmental science, urban planning, agricultural applications, and others.

Geodesign is a set of concepts and methods used to involve all stakeholders and various professions in collaboratively designing and realizing the optimal solution for spatial challenges in the built and natural environments, utilizing all available techniques and data in an integrated process. Originally, geodesign was mainly applied during the design and planning phase. "Geodesign is a design and planning method which tightly couples the creation of design proposals with impact simulations informed by geographic contexts." Now, it is also used during realization and maintenance phases and to facilitate re-use of for example buildings or industrial areas. Geodesign includes project conceptualization, analysis, design specification, stakeholder participation and collaboration, design creation, simulation, and evaluation.

<span class="mw-page-title-main">GIS and environmental governance</span> Tool for environmental management

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Counter-mapping is creating maps that challenge "dominant power structures, to further seemingly progressive goals". Counter-mapping is used in multiple disciplines to reclaim colonized territory. Counter-maps are prolific in indigenous cultures, "counter-mapping may reify, reinforce, and extend settler boundaries even as it seeks to challenge dominant mapping practices; and still, counter-mapping may simultaneously create conditions of possibility for decolonial ways of representing space and place." The term came into use in the United States when Nancy Peluso used it in 1995 to describe the commissioning of maps by forest users in Kalimantan, Indonesia, to contest government maps of forest areas that undermined indigenous interests. The resultant counter-hegemonic maps strengthen forest users' resource claims. There are numerous expressions closely related to counter-mapping: ethnocartography, alternative cartography, mapping-back, counter-hegemonic mapping, deep mapping and public participatory mapping. Moreover, the terms: critical cartography, subversive cartography, bio-regional mapping, and remapping are sometimes used interchangeably with counter-mapping, but in practice encompass much more.

Spatial citizenship describes the ability of individuals and groups to interact and participate in societal spatial decision making through the reflexive production and use of geo-media. Spatial citizens are lay users who are able to use geo-media to question existing perspectives on action in space and to produce, communicate, and negotiate alternative spatial visions.

<span class="mw-page-title-main">Internet GIS</span> Internet technologies regarding spatial data

Internet GIS, or Internet geographic information system (GIS), is a term that refers to a broad set of technologies and applications that employ the Internet to access, analyze, visualize, and distribute spatial data. Internet GIS is an outgrowth of traditional GIS, and represents a shift from conducting GIS on an individual computer to working with remotely distributed data and functions. Two major issues in GIS are accessing and distributing spatial data and GIS outputs. Internet GIS helps to solve that problem by allowing users to access vast databases impossible to store on a single desktop computer, and by allowing rapid dissemination of both maps and raw data to others. These methods include both file sharing and email. This has enabled the general public to participate in map creation and make use of GIS technology.

<span class="mw-page-title-main">Web GIS</span> Technologies employing the World Wide Web to manage spatial data

Web GIS, or Web Geographic Information Systems, are GIS that employ the World Wide Web to facilitate the storage, visualization, analysis, and distribution of spatial information over the Internet. The World Wide Web, or the Web, is an information system that uses the internet to host, share, and distribute documents, images, and other data. Web GIS involves using the World Wide Web to facilitate GIS tasks traditionally done on a desktop computer, as well as enabling the sharing of maps and spatial data. While Web GIS and Internet GIS are sometimes used interchangeably, they are different concepts. Web GIS is a subset of Internet GIS, which is itself a subset of distributed GIS, which itself is a subset of broader Geographic information system. The most common application of Web GIS is Web mapping, so much so that the two terms are often used interchangeably in much the same way as Digital mapping and GIS. However, Web GIS and web mapping are distinct concepts, with web mapping not necessarily requiring a Web GIS.

References

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  15. Craig02
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