NEHRP Clearinghouse
displaying 11 - 20 results in
total 43
Pate, M. E.
Risk and Public Policy.
National Science Foundation, Washington, DC. Engineering and Applied Science., July 1979, 60 p.
Identifying Number(s): 37
Keywords: Hazards; Buildings; Risk; Earthquake engineering; Economic analysis; Earthquakes; Probability theory; Seismic riskYao, J. T. P.; Schiff, A. J.
System Identification in Earthquake Engineering.
National Science Foundation, Washington, DC. Engineering and Applied Science., May 1980, 16 p.
Identifying Number(s): ['CE-STR-80-7', 'EC-80-2']
Keywords: Dynamic response; Hazards; Damage assessment; Earthquake engineering; Earthquake resistant structures; Earthquakes; Probability theory; Structures; Dynamic structural analysisYegian, M. K.; Vitelli, B. M.
Probabilistic Analysis for Liquefaction.
National Science Foundation, Washington, DC., March 1981, 109 p.
Keywords: Saturated soils; Earthquake engineering; Sands; Risk analysis; Earthquakes; Sand boils; Probability theory; Soil dynamics; Soil properties; Liquefaction (Soils); Seismic riskIshizuka, M.; Fu, K. S.; Yao, J. T. P.
SPERIL I - Computer Based Structural Damage Assessment System.
National Science Foundation, Washington, DC., November 1981, 44 p.
Identifying Number(s): CE-STR-81-36
Keywords: SPERIL computer program; Ground motion; Fuzzy sets; Damage assessment; Computer programs; Earthquakes; Probability theory; Decision making; Structures; Structural analysisA-Grivas, D.; Howland, J.; Tolcser, P.
A Probabilistic Model for Seismic Slope Stability Analysis.
National Science Foundation, Washington, DC. Engineering and Applied Science., June 1979, 95 p.
Identifying Number(s): CE-78-5
Keywords: Earthquake engineering; Probability density functions; Earthquakes; Earthwork; Probability theory; Soil properties; Random variables; Slopes; Mathematical models; Seismic riskWhitman, R. V.
Contribution to State-of-the-Art Report of the Earthquake Committee of the IABSE-ASCE Tall Buildings Committee 'Economic and Social Aspects'. Optimum Seismic Protection for New Building Construction in Eastern Metropolitan Areas.
National Science Foundation, Washington, DC. Engineering and Applied Science., March 1972, 16 p.
Identifying Number(s): INTERNAL STUDY-5
Keywords: Damage; Buildings; Earthquake engineering; Earthquake resistant structures; Risk analysis; Seismic design; Probability theory; Design standards; Tall buildings; Cost analysisTaleb-Agha, G.; Hein, K.
Multiple Failure Risk of Spatially Distributed Structures. Seismic Design Decision Analysis.
National Science Foundation, Washington, DC. Applied Science and Research Applications., February 1975, 17 p.
Identifying Number(s): INTERNAL STUDY-53
Keywords: Failure; Ground motion; Earthquake engineering; Earthquake resistant structures; New Hampshire; Maine; Earthquakes; Probability theory; Rhode Island; Vermont; Nuclear power plants; Massachusetts; New England; Seismic riskBalopoulou, S.; Grigoriu, M.
Seismic Response of Nominally Symmetric Systems with Strength Uncertainty.
National Science Foundation, Arlington, VA., December 23, 1997, 216 p.
Identifying Number(s): NCEER-97-0015
Keywords: Acceleration (Physics); Buildings; Building codes; El Centro earthquake; Earthquake engineering; Lateral pressure; Seismic design; Probability theory; Torsion; Mathematical models; Eccentricity; MotionA-Grivas, D.; Howland, J. D.
Probabilistic Seismic Stability Analysis of Earth Slopes.
National Science Foundation, Washington, DC. Engineering and Applied Science., December 1980, 131 p.
Identifying Number(s): CE-80-2
Keywords: Earthquake engineering; Probability density functions; Earthquakes; Probability theory; Soil dynamics; Soil properties; Slopes; Mathematical modelsShah, H. C.; McCann, M. W.
Bayesian Geophysical Model for Seismic Hazard.
National Science Foundation, Washington, DC., May 1981, 193 p.
Identifying Number(s): 47
Keywords: Seismic hazards; Seismic waves; Ground motion; Fourier transformation; Earthquake engineering; Monte Carlo method; Earthquakes; Probability theory; Earth movements; Seismic risk