References

Behnam B., Ronagh H.R. (2013). Performance of reinforced concrete structures subjected to Fire following earthquake. European Journal of Environmental and Civil Engineering 17(4):270-292.DOI10.1080/19648189.2013.783882]).

Bier VM (1997), An Overview of Probabilistic Risk Analysis for Complex Engineered Systems”, Chapter I.5 in Fundamentals of Risk Analysis and Risk Management, V. Molak (Ed.), CRC Press, 1997.

Buchanan (2017). Structural Design for Fire Safety, John Wiley & Sons.

Crosti C, Bontempi F, (2008). Performance assessment of steel structure subject to fire action, Proceedings of the CST2008 & ECT2008 Conferences (in press), Athens, September 2-5, 2008.

Ellingwood, B. (2009). Assessment and Mitigation of Risk from Low-probability, High-consequence Hazards, Australian Journal of Structural Engineering, 9 (1): 1-7.

EN 1990:2002. Eurocode - Basis of structural design.

Grosshandler W. (2007). A Research Agenda for the Next Generation of Performance-Based Design Tools, 11th International Conference on Fire Science and Engineering, London, UK, September 3-5, 2007.

Haines Y.Y. (1998), Risk Modeling, Assessment, and Management, John Wiley & Sons.

ISO (1998). International Standards Organization, General Principles on Reliability for Structures, ISO 2394.

ISO (1999a). International Standards Organization, ISO/TR 13387-1:1999. Fire safety engineering. 

ISO (1999b). International Standards Organization, ISO TR 13387-1. “Technical report on Fire Safety Engineering”, 1999

ISO (2004). International Standards Organization, ISO TC 92/SC 4/WG TG 1, “Fire Safety Engineering — General Principles”, Document Draft, 18-11-2004

Lange D., Devaney S., Usmani A. (2014). An application of the PEER performance based earthquake engineering framework to structures in fire. Engineering Structures 66: 100–115

Lougheed G.D., Hadjisophocleous G.V. (2001). The Smoke hazard from a fire in high spaces, National Research Council Canada (NRC), ASHRAE Transactions, v. 107, pt. 1, pp. 720-729, 2001.

NIST (2018). National Institute of Standard and Technologies website page: Engineering Laboratory / Fire Research Division. https://www.nist.gov/%3Cfront%3E/fire-dynamics 

NIST (National Institute of Standards and Technology), www.nist.gov

NFPA (2017). National Fire Protection Association, NFPA 550: Guide to the Fire Safety Concepts Tree. https://www.nfpa.org/codes-and-standards/all-codes-and-standards/list-of-codes-and-standards/detail?code=550 

Perrow C., 1984. Normal Accidents: Living with High-Risk Technologies., New York, Basic Books.

Randall A (2011). Risk and Precaution. Cambridge University Press. ISBN 9781139494793.

Reason J. (1990), Human Error, Cambridge University Press.

SFPE (2005). Society of Fire Protection Engineers, “Engineering Guide to Application of Risk Assessment in Fire Protection Design”, Review Draft, October 2005.

Starossek, U., (2009) Progressive collapse of structures, Thomas Telford.

Stewart M.G., Melchers R.E. (1997). “Probabilistic Risk Assessment of Engineering Systems”, London: Chapman & Hall,1997.