NEHRP Clearinghouse
displaying 111 - 120 results in total 298
Roufaiel, M. S. L.; Meyer, C.
Analysis of Damaged Concrete Frame Buildings.
May 1983, 163 p.
Keywords: Damage assessment; Reinforced concrete; Mathematical models; Computer applications; Buildings; Earthquake engineering; Dynamic response; Mechanical hystereis; Concrete construction; Earthquakes; Dynamic structural analysisYim, C. S.; Chopra, A. K.
Effects of Transient Foundation Uplift on Earthquake Response of Structures.
National Science Foundation, Washington, DC., June 1983, 137 p.
Identifying Number(s): UCB/EERC-83/09
Keywords: Earthquake resistant structures; Mathematical models; Dynamic response; Buildings; Earthquake engineering; Uplift pressure; Soil properties; Soil structure interactions; Foundations; EarthquakesHeins, C. P.; Lin, I. C.
Equivalent Seismic Design of Curved Box Girder Bridges.
National Science Foundation, Washington, DC., February 1982, 179 p.
Keywords: Seismic design; Earthquake resistant structures; Mathematical models; Computer applications; Dynamic response; Earthquake engineering; Resonant frequency; Girder bridges; Design criteriaRubin, L. I.; Abdel-Ghaffar, A. M.; Scanlan, R. H.
Earthquake Response of Long-Span Suspension Bridges.
National Science Foundation, Washington, DC., May 1983, 576 p.
Identifying Number(s): R-83-SM-13
Keywords: Golden Gate Bridge; Tacoma Narrows Bridge; California; Mathematical models; Computer applications; Ground motion; Earthquake engineering; Vincent Thomas Bridge; Suspension bridges; Bridge foundations; Dynamic response; Soil dynamics; Random vibration; Soil structure interactions; Finite element analysis; Washington (State); Earthquakes; Forced vibrationShing, P. B.; Mahin, S. A.
Experimental Error Propagation in Pseudodynamic Testing.
National Science Foundation, Washington, DC., June 1983, 187 p.
Identifying Number(s): UCB/EERC-83/12
Keywords: Earthquake resistant structures; Mechanical hysteresis; Mathematical models; Computer applications; Buildings; Earthquake engineering; Dynamic response; Pseudodynamic method; Degrees of freedom; Error analysis; EarthquakesDravinski, M.
Strong Motion Effects Due to Seismic Waves in Dipping Layers.
National Science Foundation, Washington DC., September 1983, 216 p.
Keywords: Seismic waves; Mathematical models; Ground motion; Earthquake engineering; Harmonic analysis; Boundary value problems; Plane waves; Earthquakes; Boundary layerJain, S. K.
Analytical Models for the Dynamics of Buildings.
National Science Foundation, Washington, DC., January 1983, 215 p.
Identifying Number(s): EERL-83-02
Keywords: Deformation; Equations of motion; Flexibility; Bending; Boundaries; Multistory buildings; Mathematical models; Acceleration; Earthquake resistant structures; Beams (Structural); Shear properties; Buildings; Floors; Vibration; Seismology; Walls; Theses; Diaphragms (Mechanics); Dynamic structural analysisHuang, M.
Investigation of Local Geology Effects on Strong Earthquake Ground Motions.
National Science Foundation, Washington, DC., January 1984, 256 p.
Identifying Number(s): EERL-83-03
Keywords: Orientation; Geology; Depth; California; Sites; Seismic waves; Mathematical models; Secondary waves; Pasadena (California); Seismological stations; Primary waves; Stresses; Theses; Motion; Rocks; Earthquakes; Geological faultsMcVerry, G. H.; Beck, J. L.
Structural Identification of JPL Building 180 Using Optimally Synchronized Earthquake Records.
National Science Foundation, Washington, DC., August 1983, 92 p.
Identifying Number(s): ERRL-83-01
Keywords: Dynamic loads; Earthquake accelerograms; Seismic waves; Mathematical models; Dynamic response; Buildings; Earthquake engineering; Dynamic structural analysis; Synchronism; Earthquakes; Structural analysisVaidya, N. R.; Eggenberger, A. J.
Feasibility Evaluation of Base Isolation for the Aseismic Design of Structures.
National Science Foundation, Washington, DC., January 1984, 130 p.
Keywords: Elastomers; Seismic design; Earthquake resistant structures; Seismic waves; Mathematical models; Dynamic response; Buildings; Earthquake engineering; Ground motion; Base isolation; Bearings; Design criteria