Abstract
Debates on sustainable technologies for urban management—be they related to energy, water, transport, or any other major sectors—tend to be restricted to issues about how to support a transition to new and more efficient technologies, as part of a linear path of progress proceeding from old, backward technologies to modern ones. Technologies themselves tend to be treated like black-boxes, somehow exogenously defined by engineering R&D efforts, while societies are mainly conceived of as passive agents, which can, at most, accept or reject them on the basis of their preferences. In our paper we adopt a different perspective, i.e., we start from the acknowledgement of the importance of the work of many distributed agents and micro-learning processes in technological evolutions and innovations as well as from the idea that sustainable solutions are by no means restricted to linear progression from past to future, as they can also encompass returns and recombinations of traditional components and practices together with new ones. After grounding our approach in some of the main contributions from innovation studies as well as in the application of cognitive science to evolutionary studies of technologies, we specifically discuss the possibility to use a multi-agent and multi-indexing ontological system as a device to share and learn technological knowledge across a wide community, thus supporting those micro-learning processes of distributed agents, which—in our perspective—can boost innovation and change in practice. In so doing, we will refer to a case study developed within the EU-funded project ANTINOMOS “A knowledge network for solving real-life water problems in developing countries: bridging contrasts”, which has largely dealt with enhancement and management of local/community-based knowledge for water sector management. The major aim is to create an appropriate learning environment for sharing and for actively generating knowledge through multi-actor synergies. In this paper, the above subject is discussed and carried out with a cross-disciplinary, cross-scale, multi-agent approach, considering the different forms of local knowledge and language involved.
The present chapter is the result of a joint research work carried out by the authors. Nevertheless, D. Borri wrote Sect. 3, D. Camarda wrote Sect. 4 and 6, L. Grassini wrote Sect. 1 and 2 and M. Patano wrote Sect. 5.
This is a preview of subscription content, log in via an institution to check access.
Access this chapter
Tax calculation will be finalised at checkout
Purchases are for personal use only
References
Abraham A, Grosan C (2008) Engineering evolutionary intelligent systems: methodologies, architectures and reviews. Stud Computat Intell 82:1–22
Agarwal A, Narain S (1997) Dying wisdom. rise, fall and potential of India’s traditional water harvesting systems. State of India’s Environment: A Citizens’ Report, N. 4, Centre for science and Environment (CSE), New Delhi
Ahmad S (1966) On the theory of induced innovation. Econom J 76:344–357
Ahuja G, Lampert CM (2001) Entrepreneurship in the large corporation: a longitudinal study of how established firms create breakthrough inventions. Strateg Manag J 22:521–543
Archibugi D, Lundvall BA (eds) (2001) The Globalizing Learning Economy. Oxford University Press, Oxford
Barbanente A, Borri D, Grassini L (2012) Evolutionary technologies in knowledge-based management of water resources: perspectives from South Asian case studies. In: Higgitt D (ed) Perspectives on environmental management and technology in Asian River Basins. Springer, Dordrecht, pp 45–67
Bathelt H, Malmberg A, Maskell P (2004) Clusters and knowledge: local buzz, global pipelines and the process of knowledge creation. Prog Hum Geogr 28(1):31–36
Bergek A, Jacobsson S, Carlsson B, Lindmark S, Rickne A (2008) Analyzing the functional dynamics of technological innovation systems: a scheme of analysis. Res Policy 37:407–429
Bijker WE (1995) Of bicycles, bakelites and bulbs: towards a theory of sociotechnical change. The MIT Press, Cambridge/London
Bijker WE, Hughes TP, Pinch TJ (eds) (1987) The social construction of technological systems: new directions in the sociology and history of technology. MIT Press, Cambridge
Binswanger HP, Ruttan VW (1978) Induced innovation: technology, institutions, and development. John Hopkins University Press, Baltimore
Borri D (2011) Technological memories. Plurimondi. Int Forum Res Debate Hum Settl IV(9):81–91
Borri D, Camarda D, De Liddo A (2004) Envisioning environmental futures: Multi-agent knowledge generation, frame problem, cognitive mapping. Lecture Notes in Computer Science, vol 3190, pp 230–237
Borri D, Camarda D, Grassini L (2005) Complex knowledge in the environmental domain: Building intelligent architectures for water management. Lecture Notes in Computer Science, vol 3533, pp 762–772
Borri D, Camarda D, Grassini L (2006) Distributed knowledge in environmental planning: hybrid IT-based approaches in scenario-building contexts. Group Decis Negot 6:557–580
Borri D, Grassini L, Starkl M (2009) Technological innovations and decision making changes in the water sector: Experiences from India. In: Messerschmid C, El-Jazairi L, Khatib I, Al Haj Daoud A (eds) Water: values & rights. Palestine Academy for Science and Technology, Palestine, pp 577–590
Breschi S, Malerba F (1997) Sectoral innovation systems: technological regimes, Schumpeterian dynamics, and spatial boundaries. In: Edquist C (ed) Systems of innovation: technologies, institutions and organizations. Pinter, London/Washington, pp 130–156
Brodt SB (2001) A system perspective on the conservation and erosion of indigenous agricultural knowledge in central India. Human Ecol 29(1):99–120
Brown S, Kozinets RV, Sherry JF (2003) Sell me the old, old story: retromarketing marketing and the art of brand revival. J Customer Behavior 2:85–98
Buchanan B, Shortliffe E (1977) Production rules as a representation for a knowledge-based consultation prigram. Artif Intell 8(1):15–45
Carlsson B, Stankiewicz R (1991) On the nature, function and composition of technological systems. J Evol Econ 1(2):93–118
Cohen W, Levinthal D (1990) Absorptive capacity: a new perspective on learning and innovation. Adm Sci Q 35:128–152
Collins HM (1990) Artificial experts. social knowledge and intelligent machines. The MIT Press, Cambridge
Comelli E (2016) Tecnologie più veloci della società (Technologies faster than society). Il Sole 24 Ore 512:10
Dosi G (1988) Sources, procedures and microeconomic effects of innovation. J Econom Literature 26(2):1120–1171
Ebersbach A, Glaser M, Heigl R, Warta A (2008) Wiki: web collaboration. Springer, Berlin
Elzen B, Geels FW, Green K (eds) (2004) System innovation and the transition to sustainability: theory, evidence and policy. Edward Elgar, Cheltenham
Escobar A (1996) Constructing nature: elements for a post-structural political ecology. In: Peet R, Watts M (eds) Liberation ecologies. Environment, development, social movements. Routledge, London, pp 46–68
Farla J, Markard J, Raven R, Coenen L (2012) Sustainability transitions in the making: a closer look at actors, strategies and resources. Technol Forecast Soc Chang 79:991–998
Ferber J (1999) Multi-agent system: an introduction tio distributed artificial intelligence. Addison Wesley Longman, Harlow
Fleming L (2001) Recombinant uncertainty in technological search. Manage Sci 47(1):117–132
Fleming L (2007) Brekthroughs and the ‘long tail’ of innovation. MIT Sloan Manage Rev 49:68–74
Forester J (1988) Planning in the face of power. University of California Press, Berkeley
Forester J (1999) The deliberative practitioner: encouraging participatory planning processes. MIT Press, Cambridge
Gartner WB (1988) “Who is an entrepreneur” is the wrong question. American J Small Business 12(4):11–32
Garud R, Karnøe P (2003) Bricolage versus breakthrough: distributed and embedded agency in technology entrepreneurship. Res Policy 32:277–300
Geels FW (2002) Technological transitions as evolutionary reconfiguration processes: a multi level perspective and a case study. Res Policy 31:1257–1274
Geels FW (2004) From sectoral systems of innovation to socio-technical systems. insights about dynamics and change from sociology and institutional theory. Res Policy 33(6/7):897–920
Geels FW, Schot J (2010) The dynamics of socio-technical transitions—a socio-technical perspective. In: Grin J, Rotmans J, Schot J (eds) Transitions to sustainable development. Routledge, London, pp 9–101
Geels FW, Hekkert MP, Jacobsson S (2008) The dynamics of sustainable innovation journeys. Technol Anal Strateg Manag 20(5):521–536
Gerner J, Naramore E, Owens M (2006) Professional LAMP: Linux, Apache, MySQL, and PHP web development. Wiley & Sons, New Jersey
Giovannini E (2016) Innovazione per la sostenibilità (Innovation for sustainability). Il Sole 24 Ore 512:9
Grassini L (2011) Buone prassi per chi? Politiche di sviluppo e pratiche interpretative in India. Alinea, Firenze
Grassini L (2012) Water resources management and territorial development: technological changes in the Apulia region in the post-Unitary period. Plurimondi. Int Forum Res Debate Hum Settl 11:89–123
Grassini L (2013) Gestione delle risorse idriche e sviluppo territoriale. Percorsi di innovazione tra modernità e tradizione. Planum. J Urbanism 27(2)
Greenwald BC, Stiglitz JE (1986) Externalities in economies with imperfect information and incomplete markets. Q J Econ 101(2):229–264
Greenwald BC, Stiglitz JE (1990) Asymmetric information and the new theory of the firm: Financial constraints and risk behavior. Am Econ Rev 80(2):160–165
Griffith M (ed) (1983) Aeschylus’ Prometheus Bound. Cambridge University Press, Cambridge
Griliches Z (1984) R&D, Patents and Productivity. University of Chicago Press, Chicago
Hekkert MP, Suurs RAA, Negro SO, Kuhlmann S, Smits REHM (2007) Functions of innovation systems: a new approach for analyzing technological change. Technol Forecast Soc Chang 74:413–432
Hendry C, Harborne P (2011) Changing the view of wind power development: more than “bricolage”. Res Policy 40(5):778–789
Hicks J (1932) The theory of wages. Macmillan & Co, London
Howells JRL (2002) Tacit knowledge, innovation and economic geography. Urban Stud 39(5–5):871–884
Hughes TP (1987) The evolution of large technological systems. In: Bijker W, Hughes TP, Pinch T (eds) The social construction of technological systems. MIT Press, Cambridge, pp 51–82
Johnson-Laird P (1988) The computer and the mind. An introduction to cognitive science. Collins, London
Kamp LM, Smits REHM, Andriesse CD (2004) Notions on learning applied to wind turbine development in the Netherlands and Denmark. Energy Policy 32:1625–1637
Katila R (2002) New product search over time: past ideas in their prime? Acad Manag J 45(5):995–1010
Katila R, Ahuja G (2002) Something old, something new: a longitudinal study of search behavior and new product introduction. Acad Manag J 45:1183–1194
Keeney J, Lewis D, O’Sullivan D (2007) Ontological semantics for fistributing contextual knowledge in highly distributed autonomic systems. J Netw Syst Manage 15(1):75–86
Khakee A, Barbanente A, Camarda D, Puglisi M (2002) With or without? Comparative study of preparing participatory scenarios using computer-aided and traditional brainstorming. J Future Res 6:45–64
Khaled MH, Mohamed SK (2004) Efficient phrase-based document indexing for web document clustering. IEEE Trans Knowl Data Eng 16:1279–1296
King P, Munson EV (eds) (2004) Digital documents: systems and principles. Springer Verlag, Berlin
Kubursi A, Borri D, Grassini L (2011) In praise of traditional technologies. Plurimondi. Int forum Res Debate Human Settl. Special issue on Antinomos: Dilemmas in water supply and sanitation technologies IV(8):21–50
Latour B (1987) Science in action: how to follow scientists and engineers through society. Open University Press, Milton Keynes
Mansfield E (1968) Industrial research and technological innovation. Norton, New York
March J (1991) Exploration and exploitation in organizational learning. Organ Sci 2:71–87
McCully P (1996) Silenced rivers: the ecology and politics of large dams. Zed Books, London
Messeni Petruzzelli A, Albino V (2012) When tradition turns into innovation. How firms can create and appropriate value through tradition. Woodhead Publishing Limited, Cambridge
Messeni Petruzzelli A, Rotolo D, Albino V (2012) The impact of old technologies on innovation: the case of US biotechnology industry. Technol Anal Strateg Manag 24:453–466
Mignolo W (2000) Local histories/global designs: coloniality, subaltern knowledges, and border thinking. Princeton University Press, Princeton
Minsky ML (1987) The Society of Mind. Simon & Schuster, New York
Minsky M (1988) The emotion machine: common sense thinking, artificial intelligence, and the future of human mind. Simon and Schuster, New York
Negro S, Hekkert MP (2008) Explaining the success of emerging technologies by innovation system functioning: the case of biomass digestion in Germany. Technol Anal Strateg Manag 20(4):465–482
Nelson RR, Winter SG (1973) Towards an evolutionary theory of economic capabilities. Am Econ Rev 63:440–449
Nelson RR, Winter SG (1977) In search of useful theory of innovation. Res Policy 6(1):36–76
Nelson RR, Winter SG (1982) An evolutionary theory of economic change. Cambridge University Press, Cambridge
Nerkar A (2003) Old is gold? The value of temporal exploration in the creation of new knowledge. Manage Sci 49:211–229
Nonaka I (1999) The dynamics of knowledge creation. In: Ruggles R, Holtshouse D (eds) The knowledge advantage. Ernst and Young, Dover
Postel SL (2000) Entering an era of water scarcity: the challenges ahead. Ecol Appl 10(4):941–948
Raven RPJM, Geels FW (2010) Socio-cognitive evolution in niche development: Comparative analysis of biogas development in Denmark and the Netherlands (1973–2004). Technovation 30(2):87–99
Rinkus S, Walji M, Johnson-Troop KA, Malin JT, Turley JP, Smith JW, Zhang J (2005) Human-centered design of a distributed knowledge management system. J Biomed Inform 38(1):4–17
Rip A, Kemp R (1998) Technological change. In: Rayner S, Malone EL (eds) Human choice and climate change—resources and technology. Battelle Press, Columbus, pp 327–399
Rosenberg N (1982) Inside the black box: technology and economics. Cambridge University Press
Rostow WW (1960) The stages of economic growth: a non-communist manifesto. Cambridge University Press, Cambridge
Scherer F (1986) Innovation and growth, schumpeterian perspectives. The MIT Press, Cambridge
Schmookler J (1966) Invention and economic growth. Harvard University Press, Cambridge
Schumpeter JA (1934) The theory of economic development: an inquiry into profits, capital, credit, interest and the business cycle (trans from the German by Opie R). Transaction Publishers, New Brunswick and London
Schumpeter JA (1942) Capitalism, socialism and democracy. Harper, New York
Severino E (1979) Legge e Caso (Law and chance). Milano, Adelphi
Severino E (1998) Il Destino della Tecnica (The destiny of the technique). Milano, Rizzoli
Shanahan M (1997) Solving the frame problem. MIT Press, Cambridge
Shiva V (2001) Water wars. privatisation, pollution and profit. Pluto Press, London
Silver D et al (2016) Mastering the game of Go with deep neural networks and tree search. Nature 529:484–489
Smith A, Jan-Peter Voβ J-P, Grin J (2010) Innovation studies and sustainability transitions: the allure of a multi-level perspective and its challenges. Res Policy 39(4):435–448
Solow RM (1957) Technical change and the aggregate production function. Rev Econ Stat 39:312–320
Sørensen J, Stuart T (2000) Aging, obsolescence, and organizational innovation. Adm Sci Q 45(1):81–112
Stuart TE, Podolny JM (1996) Local search and the evolution of technological capabilities. Strateg Manag J 17:21–38
Torregrosa Armentia ML, Castro JE, Allen A, Gómez González Cosío R, Vera J, Kloster K (2006) Institutional development and political processes, baseline document for the cross-cutting perspective 2. National Water Commission, Mexico City
Unver OIH (1997) South-eastern Anatolian Project (GAP). Water Resour Dev 13(4):453–483
van de Kerkhof M, Wieczorek A (2005) Learning and stakeholder participation in transition processes towards sustainability: methodological considerations. Technol Forecast Soc Chang 72:733–747
van den Bergh JCJM, Gowdy JM (2000) Evolutionary theories in environmental and resource economics: approaches and applications. Environ Resour Econ 17(1):37–57
Voβ J-P, Smith A, Grin J (2009) Designing long-term policy: rethinking transition management. Policy Sci 42(4):275–302
Winograd T, Flores F (1987) Understanding computers and cognition. A new foundation for design. Ablex, Norwood, New Jersey
Zeleny M (2005) Human systems management: integrating knowledge, management and systems. World Scientific, New York
Zhang J (1998) A distributed representation approach to group problem solving. J Am Soc Inform Sci 801–809
Acknowledgements
The research on which the paper is based is part of the project ANTINOMOS, “A knowledge network for solving real life water problems in developing countries”, funded by the European Commission under the Sixth Framework Programme.
Author information
Authors and Affiliations
Corresponding author
Editor information
Editors and Affiliations
Rights and permissions
Copyright information
© 2016 Springer International Publishing Switzerland
About this chapter
Cite this chapter
Borri, D., Camarda, D., Grassini, L., Patano, M. (2016). Technological Change and Innovation for Sustainable Cities: A Multiagent-Based Ontological Approach. In: Papa, R., Fistola, R. (eds) Smart Energy in the Smart City. Green Energy and Technology. Springer, Cham. https://doi.org/10.1007/978-3-319-31157-9_4
Download citation
DOI: https://doi.org/10.1007/978-3-319-31157-9_4
Published:
Publisher Name: Springer, Cham
Print ISBN: 978-3-319-31155-5
Online ISBN: 978-3-319-31157-9
eBook Packages: EnergyEnergy (R0)