Explores the plastic hinge method, moment-curvature analysis, and force-displacement response construction in structures.
Covers seismic design fundamentals, including failure modes, capacity design, and displacement-based evaluation of structures.
Explains the plastic hinge method for estimating inelastic deformation capacity in structural elements, focusing on flexural deformations and providing good approximations.
Examines the relationship between different ductilities in seismic engineering, highlighting their significance in structural elements.
Covers the capacity design of reinforced concrete walls in 10 steps, emphasizing overstrength and ductility.
Explores the response and design of inelastic SDOF systems under seismic forces, including force capacity, displacement ductility, and shear strength estimation.
Explores the capacity design of reinforced concrete walls in seismic engineering, emphasizing flexural and shear design principles.
Covers the fundamentals of structural mechanics, focusing on beams, sign conventions, types of beams, and methods to calculate stress resultants.
Covers the Response Spectrum Method and its combination rules, emphasizing effective modal mass and maximum absolute responses.
Discusses stresses in beams under flexure, including shear forces and bending moments.
Covers the capacity design of reinforced concrete walls and structures, emphasizing stability, reinforcement design, and seismic engineering.
