Digital Information Tools for Urban Regeneration: Capital’s Approach in Theory and Practice
Abstract
:1. Introduction
2. Methodological Approach: Interacting Capitals
- “Spatial capital is a representation of spatial form that can be linked to social, economic and ecological processes in cities, thereby allowing them to be consciously directed by urban design” [7]. Based on Space Syntax approach the spatial urban configurations could be analysed in the terms of co-presence or symmetry, closeness, multifunctionality, etc.
- The idea of social capital, according to Marcus, is grounded on the studies of collective human activities where concepts of trust, cooperation and both formal and informal institutions are essential [8]. It is based on works of Robert Putnam, who defines social capital as the “Collective value of all social networks and the inclinations that arise from these networks to do things for each other” [9].
- Economic capital: “It is easy to see how the notion of cities as a landscape of co-presences of varying size and differentiation, in economic terms can be translated into a landscape of markets; what are economic markets but co-presences of people and things… We see the importance of transport costs in these models, something that may vary for many reasons, energy costs, degree of congestion and infrastructural standard. However, underpinning any such cost is physical distance, which is what routinely is structured and shaped by way of spatial form in urban design.” [7].
- According to Marcus “humans... are understood as an intrinsic part of nature and ecological process... We may illustrate (it) through the ecosystem service pollination. To facilitate such services in an urban area, we need to create support for both essential agents … functioning ecosystems are in spatial terms a set of locations linked together in a configuration that allow movement between them.” [7].
- Degree centrality as a number of edges of each node. Higher degree centrality might mean bigger number of social contacts of a person or bigger number of visual connections with neighbouring spaces in an urban square
- Closeness centrality as a sum of distances from selected node to all the other nodes of a network. The lowest value of closeness centrality means that the precise node is in the most reachable position in a network
- Betweenness centrality as a number of the hypothetical shortest journeys between all possible pairs of nodes which cross a node for which calculation is made. A higher number might mean bigger flows of information, materials, or energy in a network. This type of centrality is the most often used for transport flow modelling in a city while street crossroads are seen as network nodes
- Humans are territorial beings, so a node of the graph could be seen as a territorially integrated, homogenous group of people
- Similar social status, education level, age, etc. might increase probability of social connections
- Physical neighbouring of human groups and territories increase probability of social contacts
- One 100 × 100 m cell represents one node of the graph while number of inhabitants represent a weight of a node
- Node-sell is connected with the neighbouring nodes-cells if they have a common border—the same principle is earlier mentioned convex graphs offered by Space Syntax theory
- Node is connected with distant nodes if both represent the same dominant social groups
- All elements or species and services of ecosystem could be associated with certain territory
- Higher diversity of elements/services and interactions between them could be seen as indicator of higher ecological potential or capital. It could be grounded by general statement that more diverse system has more possibilities to adapt to changing conditions
- Closeness of elements make the interaction more probable
- Territory could be divided into equal cells (e.g., 100 × 100 m)
- Neighbouring cells/nodes are connected with each other in two cases depending on selected ecological services: if they have a common border; if a distance between them fall within certain actual range, e.g., daily travel distance of an actual specie or size of its biotope
- Distant nodes/cells could be connected on the base of existing ecological corridors. In a case of recreational services, it would be green connections, pedestrian alleys, bicycle routs; in a case of biotopes—corridors of journeys of various species
- Various commercial activities might support each other and benefit from closeness to each other
- Commercial activities benefit from closeness to public functions and infrastructural services which attract more people
- Each commercial activity has its service area
- Commercial and public services might catalyse each other in both positive and negative ways
- Territory could be divided into equal cells as it was offered for social and ecological graph. Each territorial cell becomes a node which might be weighted according available data on economic activities which could be related directly or indirectly to the number of customers, e.g.,: size of commercial area, generated income, number of employees, type of activities, etc. Such data, in a case of Lithuania, is available for 100 × 100 m territorial cells
- Neighbouring cells could be connected depending on positive catalysation and service area distance. Both aspects could be evaluated on the base of sociological survey
- Distant cells could be connected on the base of infrastructural connections as the main routes and public transport lines classified according to a journey speed including waiting time as stops
3. Results: Classification of DT/IT for Urban Regeneration
4. Case Study: A Digital Tool in Riga
- to promote exchange of experience and ideas for the re-arrangement of degraded territories and degraded structures
- to share experience on the temporary use of empty buildings as an effective tool to prevent the emergence of slums and revitalize the degraded urban areas
- to create a sustainable platform of collaboration between Riga and other European cities [28].
5. Discussion
6. Conclusions
Author Contributions
Funding
Acknowledgments
Conflicts of Interest
References
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Economic Capital (EcC): Assets That Can Enhance One’s Power to Perform Economically Useful Work | ||
• | Interaction with a city in general terms: | market relations act as a background for economic functioning of a city; could be seen as force utilizing all other capitals in economic processes (including ScC) |
• | Relations to Spatial Capital (SpC): | SpC creates added value by offering spatial conditions which allow successful economic functioning |
• | Possible modelling approach: | a monetary or exchange-value |
• | Indicators: | monetary value or costs |
Social Capital (ScC): Collective Value of Social Networks. Two Types of ScC: Bridging and Bonding | ||
• | Interaction with a city in general terms: | creates in general direct background of society; might be increased by an attachment to a specific place/location |
• | Relations to Spatial Capital (SpC): | SpC catalyses co-presence |
• | Possible modelling approach: | social network description, socio-top map [13], etc. |
• | Indicators: | number of social connections |
Ecological (Natural) Capital (EnC): Environmental Resources; Value of Relations with Environment Created by Functioning of Ecosystems | ||
• | Interaction with a city in general terms: | movement of energy, materials and information is conducted on the base of physical infrastructure (including spatial configuration) |
• | Relations to Spatial Capital (SpC): | SpC creates conditions for ecosystem services in terms of various flows (materials, energy, information) |
• | Possible modelling approach: | functional potential of ecosystems |
• | Indicators: | diversity and connections (openness) of eco-subsystems or biotopes |
Cultural Capital (CltC): “CltC Comprises the Social Assets of a Person (or Social Group) that Promote Social Mobility in a Stratified Society” [11] | ||
• | Interaction with a city in general terms: | it could be seen as closely related to ScC and EcC as an additional attribute layer; it might be utilizing certain spatial locations for its demonstration |
• | Relations to Spatial Capital (SpC): | SpC affects CltC by using spatial configuration as a tool to reflect and create CltC through reflecting some cultural space usage scenarios |
• | Possible modelling approach: | modified socio-top mapping [13]; semantic structure |
• | Indicators: | patterns of CltC features (might be spatially mapped) |
Symbolic capital (SyC): “Resources Available to an Individual (or Society) on the Basis of Honour, Prestige or Recognition, and Serves as Value That One Holds within a Culture”—Semantic Cultural Symbols | ||
• | Interaction with a city in general terms: | it could be seen as closely related to ScC and EcC as an additional attribute layer; it might be utilizing certain spatial locations for its demonstration |
• | Relations to Spatial Capital (SpC): | SpC could be affected by the objects related to or holding SyC as catalysers of SpC; SpC, on its turn, can make the objects of SyC more or less intelligible in a city |
• | Possible modelling approach: | semantic structure |
• | Indicators: | pairs of oppositions describing semantic structure |
Spatial capital (SpC): Value Created by Spatial Configurations for Both Functional Needs and Urban Resilience | ||
• | Interaction with a city in general terms: | provides/creates conditions for functioning of all other capitals by creating conditions for spatial movement of people |
• | Possible modelling approach: | quantitative models of spatial configurations which might be related to qualitative aspects; it is important to say that so called bottom up or complex models are essential here as they have a power of predictability and imitate real processes if comparing to descriptive, top-down models |
• | Indicators: | mathematical graph based model and calculated centralities; agent-based model, Cellular Automata model, Fractal index |
No | DT/IT | Types of Capitals | |||||
---|---|---|---|---|---|---|---|
Economic | Social | Ecologic | Cultural | Symbolic | Spatial | ||
Urban and Regional Information Infrastructure (Data about All Social, Economic and Environmental Issues) | |||||||
1. | GIS | + | + | + | + | + | + |
2. | RS | + | + | + | + | ||
3. | Google maps | + | + | + | + | ||
4. | OpenStreetMap | + | + | + | + | ||
5. | Maps.lt | + | + | + | + | ||
6. | Geoportal.lt | + | + | + | + | ||
7. | Regia.lt | + | + | + | |||
8. | Kvr.kpd.lt | + | + | ||||
9. | Tpdr.lt | + | + | + | |||
10. | Tpdris.lt | + | + | + | |||
11. | Zeldynai.mapika.lt | + | + | ||||
Digital Environmental Models (Information Organization and Analysis) | |||||||
12. | DEM, DSM, DTM | + | + | + | |||
13. | Digital Twin | + | + | + | + | ||
14. | CIM | + | + | + | + | + | + |
15. | City Engine | + | + | + | + | ||
16. | ArchiCad | + | + | ||||
17. | Traffic flow analysis application sisp.maps.arcgis.com | + | + | ||||
18. | Revit | + | + | ||||
19. | SketchUp | + | + | ||||
20. | Graphics editor (for ex., Illustrator, Photoshop, etc.) | + | |||||
Communication Platforms | |||||||
21. | Online participatory mapping (for ex., Maptionnaire, Carticipe, MinStad, etc.) | + | + | + | + | + | + |
22. | Mind mapping software (for ex., Ayoa, etc.) | + | + | ||||
23. | Online sociological surveys (for ex., Survio, google forms, etc.) | + | + | + | + | + | + |
24. | Collective design and planning (for ex., Betaville, etc.) | + | + | + | |||
25. | Augmented reality | + | + | + | + | + | + |
26. | Tangible table | + | + | + | |||
27. | Multi-screen system | + | + | + | |||
28. | Social networks (for ex., Facebook, Instagram, etc.) | + | + | + | + |
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Bratuškins, U.; Zaleckis, K.; Treija, S.; Koroļova, A.; Kamičaitytė, J. Digital Information Tools for Urban Regeneration: Capital’s Approach in Theory and Practice. Sustainability 2020, 12, 8082. https://doi.org/10.3390/su12198082
Bratuškins U, Zaleckis K, Treija S, Koroļova A, Kamičaitytė J. Digital Information Tools for Urban Regeneration: Capital’s Approach in Theory and Practice. Sustainability. 2020; 12(19):8082. https://doi.org/10.3390/su12198082
Chicago/Turabian StyleBratuškins, Uģis, Kęstutis Zaleckis, Sandra Treija, Alisa Koroļova, and Jūratė Kamičaitytė. 2020. "Digital Information Tools for Urban Regeneration: Capital’s Approach in Theory and Practice" Sustainability 12, no. 19: 8082. https://doi.org/10.3390/su12198082
APA StyleBratuškins, U., Zaleckis, K., Treija, S., Koroļova, A., & Kamičaitytė, J. (2020). Digital Information Tools for Urban Regeneration: Capital’s Approach in Theory and Practice. Sustainability, 12(19), 8082. https://doi.org/10.3390/su12198082