Abstract
The design of complex artifacts, for example civil structural and infrastructural systems, is based on the premise that their performance can be predicted and evaluated with sufficient confidence for the engineers, clients and other stakeholders jointly to make intelligent and informed decisions. This requires a shift away from current prescriptive codes, which tend to be implicitly conservative and do not properly account for the consequences of damage or failure of an artifact, and toward a design process and design codes more firmly rooted in the realistic prediction of the probabilities of damage and failure, and the associated consequences. There is also a need for a risk-based design process and code that account in a normative and comprehensive way for the consequences associated to risks. This chapter proposes a capability approach to design, herein called capability-based design. We argue that capabilities provide the requisite framework for conceptualizing consequences in risk assessment, evaluation, and management. Finally, a capability approach to design offers concrete guidance to engineers making design choices and balancing competing design constraints.
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An, D., Gordon, P., Moore, J. E., II, & Richardson, H. W. (2004). Regional economic models for performance based earthquake engineering. Natural Hazards Review, 5(4), 188–195.
Anderson, E. (1988). Values, risks, and market norms. Philosophy and Public Affairs, 17(1), 54–65.
Bates, F., & Peacock, W. G. (1992). Measuring disaster impact on household living conditions. International Journal of Mass Emergencies and Disasters, 10(1), 133–160.
Bedford, T., & Cooke, R. (2001). Probabilistic risk analysis: Foundations and methods. Cambridge: Cambridge University Press.
Crocker, D. (2008). The ethics of global development. New York: Cambridge University Press.
Dahlhamer, J., & D’Souza, M. (1997). Determinants of business disaster preparedness. International Journal of Mass Emergency and Disasters, 15, 265–281.
Dash, N., & Gladwin, H. (2007). Evacuation decision making and behavioral responses: Individual and household. Natural Hazards Review, 8(3), 69–77.
Dash, N., Morrow, B. H., Mainster, J., & Cunningham, L. (2007). Lasting effects of Hurricane Andrew on a working-class community. Natural Hazards Review, 8(1), 13–21.
Ditlevsen, O., & Madsen, H. O. (1996). Structural reliability methods. New York: Wiley.
Fothergill, A., Maestas, E. G. M., & Darlington, J. D. (1999). Race, ethnicity and disasters in the United States: A review of the literature. Disasters, 23(2), 156–173.
Gardoni, P., & Murphy, C. (2008). Recovery from natural and man-made disasters as capabilities restoration and enhancement. International Journal of Sustainable Development and Planning, 3(4), 1–17.
Gardoni, P., & Murphy, C. (2009). A capabilities-based approach to measuring the societal impacts of natural and man-made hazards. Natural Hazard Review, 10(2), 23–37.
Gardoni, P., & Murphy, C. (2010). Gauging the societal impacts of natural disasters using a capabilities-based approach. Disasters: The Journal of Disaster Studies, Policy and Management, 34(3), 619–636.
Gardoni, P., Der Kiureghian, A., & Mosalam, K. M. (2002). Probabilistic capacity models and fragility estimates for RC columns based on experimental observations. ASCE Journal of Engineering Mechanics, 128(10), 1024–1038.
Haimes, Y. Y. (2004). Risk modeling, assessment, and management. Hoboken: Wiley Series in Systems Engineering and Management.
Hansson, S. O. (2007). Philosophical problems in cost-benefit analysis. Economics and Philosophy, 23, 163–183.
Huang, Q., Gardoni, P., & Hurlebaus, S. (2009). Probabilistic capacity models and fragility estimates for reinforced concrete columns incorporating NDT data. ASCE Journal of Engineering Mechanics, 135(12), 1384–1392.
Kajitani, Y., Okada, N., & Tatano, H. (2005). Measuring quality of human community life by spatial-temporal age group distributions: case study of recovery process in a disaster-affected region. Natural Hazards Review, 6(1), 41–47.
Mileti, D. S. (1999). Disasters by design: A reassessment of natural hazards in the United States. Washington, DC: Joseph Henry Press.
Murphy, C., & Gardoni, P. (2006). The role of society in engineering risk analysis: A capabilities-based approach. Risk Analysis, 26(4), 1085–1095.
Murphy, C., & Gardoni, P. (2007). Determining public policy and resource allocation priorities for mitigating natural hazards: A capabilities-based approach. Science and Engineering Ethics, 13(4), 489–504.
Murphy, C., & Gardoni, P. (2008). The acceptability and the tolerability of risks: A capabilities-based approach. Science and Engineering Ethics, 14(1), 77–92.
Murphy, C., & Gardoni, P. (2010). Assessing capability instead of achieved functionings in risk analysis. Journal of Risk Research, 13(2), 137–147.
Murphy, C., & Gardoni, P. (2011). The capability approach in risk analysis. In S. Roeser (Ed.), Handbook on risk theory (pp. 979–997). Dordrecht: Springer.
Murphy, C., Gardoni, P., & Harris, C. E. (2011). Classification and moral evaluation of uncertainties in engineering modeling. Science and Engineering Ethics , 17(3), 553–570.
Nigg, J. (1996). Anticipated business disruption effects due to earthquake-induced lifeline interruption. In F. Cheng & Y. Wang (Eds.), Post-earthquake rehabilitation and reconstruction (pp. 47–57). St. Louis: Pergamon.
Nussbaum, M. (2000a). Aristotle, politics, and human capabilities: A response to Antony, Arneson, Charlesworth, and Mulgan. Ethics, 111(1), 102–140.
Nussbaum, M. (2000b). Woman and human development: The capabilities approach. Cambridge: Cambridge University Press.
Nussbaum, M. (2001). Adaptive preferences and women’s options. Economics and Philosophy, 17, 67–88.
Peacock, W. G., & Girard, C. (1997). Ethnic and racial inequalities in hurricane damage and insurance settlements. In W. G. Peacock, B. H. Morrow, & H. Gladwin (Eds.), Hurricane Andrew: Ethnicity, gender and the sociology of disasters. London: Routledge.
Petterson, J. (1999). A review of the literature and programs on local recovery from disaster (Working Paper #102). Natural Hazards Research and Applications Information Center, Institute of Behavioral Science, University of Colorado. Published by Public Entity Risk Institute. www.riskinstitute.org. Accessed 3 Dec 2007.
Robeyns, I. (2006). The capability approach in practice. Journal of Political Philosophy, 14(3), 351–376.
Rowe, W. D. (1980). Risk assessment: Theoretical approaches and methodological problems. In J. Conrad (Ed.), Society, technology, and risk assessment (pp. 3–29). New York: Academic Press.
Sen, A. (1989). Development as capabilities expansion. Journal of Development Planning, 19, 41–58.
Sen, A. (1992). Inequality reexamined. Cambridge: Harvard University Press.
Sen, A. (1993). Capability and well-being. In M. Nussbaum & A. Sen (Eds.), The quality of life (pp. 30–53). Oxford: Clarendon.
Sen, A. (1999a). Commodities and capabilities. Oxford: Oxford University Press.
Sen, A. (1999b). Development as freedom. New York: Anchor Books.
Sen, A. (2009). The idea of justice. Cambridge: Belknap Press of Harvard University Press.
Slovic, P. (1987). Perception of risk. Science, 236, 280–285.
Sunstein, C. (2005). Cost-benefit analysis and the environment. Ethics, 115, 251–285.
Tierney, K. (1992). What are the likely categories of loss and damage? In The economic consequences of a catastrophic earthquake: Proceedings of a forum (pp. 77–82). Washington, DC: National Academy Press.
Tierney, K. (1994). Societal impacts. In J. Goltz (Ed.), The Northridge, California earthquake of January 17, 1994: General reconnaissance report (pp. 7:1–7:10). Buffalo: National Center for Earthquake Engineering Research.
van de Poel, I. (2001). Investigating ethical issues in engineering design. Science and Engineering Ethics, 7, 429–446.
van de Poel, I., & van Gorp, A. C. (2006). The need for ethical reflection in engineering design: The relevance of type of design and design hierarchy. Science, Technology & Human Values, 31(3), 333–360.
Van Willigen, M., Edwards, E., Lormand, S., & Wilson, K. (2005). Comparative assessment of impacts and recovery from Hurricane Floyd among student and community households. Natural Hazards Review, 6(4), 180–190.
Vose, D. (2000). Risk analysis: A quantitative guide. New York: Wiley.
Wetmore, J. M. (2008). Engineering with uncertainty: Monitoring air bag performance. Science and Engineering Ethics, 14, 201–218.
Wolff, J., & de-Shalit, A. (2007). Disadvantage. Oxford: Oxford University Press.
Acknowledgements
This research was supported primarily by the Science, Technology, and Society Program of the National Science Foundation Grant (STS 0926025). Opinions and findings presented are those of the authors and do not necessarily reflect the views of the sponsor.
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Murphy, C., Gardoni, P. (2012). Design, Risk and Capabilities. In: Oosterlaken, I., van den Hoven, J. (eds) The Capability Approach, Technology and Design. Philosophy of Engineering and Technology, vol 5. Springer, Dordrecht. https://doi.org/10.1007/978-94-007-3879-9_10
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