- Lecturer
- Kawashima Kazuhiko
- Place
- Fri5-6(M112)
- Credits
- Lecture2 Exercise0 Experiment0
- Code
- 61041
- Syllabus updated
- 2009/5/1
- Lecture notes updated
- 2009/4/28
- Access Index
-
- Semester
- Spring Semester
Outline of lecture
Enhancing seismic performance of urban infrastructures is essential to mitigate loss of function of urban areas during and after a significant earthquake. Seismic design of urban infrastructures is an important part of securing the seismic performance of urban aveas. Emphasis of this lecture will be placed on the seismic design of transportation facilities including bridges and underground structures in soft soil deposits. It has been revealed in the 1994 Northridge, USA earthquake and 1995 Kobe, Japan earthquake that bridges and underground structures are vulnerable to near-field ground motions. The 1999 Bolu, Turkey earthquake and the Chi Chi, Taiwan earthquake resulted in the significant damage of bridges and underground structures by fault-induced displacements. Presented in this lecture are the characterization of ground motions, past damage of transportation facilities, linear and nonlinear dynamic response of bridges and underground structures, effect of poundings, strength and ductility of reinforced concrete piers, columns and walls, performance goals and performance-based seismic design, seismic deformation method, and seismic evaluation and seismic retrofit.
Purpose of lecture
Enhancing seismic performance of urban infrastructures is essential to mitigate loss of
function of urban areas during and after a significant earthquake Seismic design of urban
infrastructures is an important part of securing the seismic performance of urban
infrastructures. Emphasis of this lecture will be placed on the seismic design of transportation
facilities including bridges and underground structures in soft soil deposits
Plan of lecture
1) Damage of urban infrastructures in past earthquakes
2) Engineering characterization of ground motions (1)
3) Engineering characterization of ground motions (2)
4) Dynamic response analysis of bridges
5) Strength and ductility of reinforced concrete members ('l )
6) Strength and ductility of reinforced concrete members (2)
7) Strength and ductility of reinforced concrete members (3)
8) Seismic response of bridges (1)
9) Seismic response of bridges (2)
10) Seismic design (1)
11) Seismic design (2)
12) Performance-based seismic design
13) Evaluation of seismic vulnerability
14) Seismic retrofit
Textbook and reference
Original texts are provided by the lecturer They can be downloaded from HP
Related and/or prerequisite courses
Require basic knowledge on structural analysis and dynamics of structures
Related and/or prerequisite courses
縲
Evaluation
Evaluation depends on tests and reports
