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E-raamat: Introduction to Earthquake Engineering [Taylor & Francis e-raamat]

(University of the Pacific, Stockton, California, USA), (University of the Pacific, Stockton, California, USA)
  • Formaat: 266 pages, 14 Tables, black and white; 161 Line drawings, color; 57 Halftones, black and white; 218 Illustrations, black and white
  • Ilmumisaeg: 25-May-2017
  • Kirjastus: CRC Press Inc
  • ISBN-13: 9781315171579
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  • Taylor & Francis e-raamat
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Introduction to Earthquake EngineeringSuurem pilt
  • Formaat: 266 pages, 14 Tables, black and white; 161 Line drawings, color; 57 Halftones, black and white; 218 Illustrations, black and white
  • Ilmumisaeg: 25-May-2017
  • Kirjastus: CRC Press Inc
  • ISBN-13: 9781315171579
Teised raamatud teemal:
Taylor & Francis e-raamatudRohkem infot Taylor & Francis e-raamatute kohta
Raamatu kodulehekülg: https://www.taylorfrancis.com/books/9781315171579

This book is intended primarily as a textbook for students studying structural engineering. It covers three main areas in the analysis and design of structural systems subjected to seismic loading: basic seismology, basic structural dynamics, and code-based calculations used to determine seismic loads from an equivalent static method and a dynamics-based method. It provides students with the skills to determine seismic effects on structural systems, and is unique in that it combines the fundamentals of structural dynamics with the latest code specifications. Each chapter contains electronic resources: image galleries, PowerPoint presentations, a solutions manual, etc.

Preface ix
Acknowledgements xi
Authors xiii
Chapter 1 Introduction
1(18)
1.1 Structural Effects of Earthquakes
2(6)
1.1.1 Ground Failures
2(3)
1.1.2 Indirect Effects of Earthquakes
5(2)
1.1.3 Ground Shaking
7(1)
1.2 Types of Earthquakes
8(6)
1.2.1 Man-Made Earthquakes
9(2)
1.2.2 Volcanic Earthquakes
11(1)
1.2.3 Tectonic Earthquakes
11(3)
1.3 History of the Development of Mitigation Strategies for the Effects of Seismic Hazards
14(5)
References
17(2)
Chapter 2 Engineering Seismology Overview
19(18)
2.1 Seismology Terminology
19(4)
2.1.1 Elastic Rebound Theory: Tectonic Plate Movement
21(1)
2.1.2 Seismic Waves
21(2)
2.2 Measuring Earthquakes
23(6)
2.2.1 Earthquake Intensity
23(2)
2.2.2 Earthquake Magnitude
25(4)
2.3 Effects of Earthquakes on Structures
29(5)
2.3.1 Earthquake Characteristics
29(2)
2.3.2 Site Characteristics
31(1)
2.3.3 Structural Characteristics
32(2)
2.4 Earthquake Hazard Assessment
34(2)
2.5 Earthquake Prediction
36(1)
Problems
36(1)
References
36(1)
Chapter 3 Single-Degree-of-Freedom Structural Dynamic Analysis
37(54)
3.1 Undamped Single-Degree-of-Freedom System
37(27)
3.1.1 Free Vibration Response of Undamped Systems
38(4)
3.1.2 Structural Weight
42(4)
3.1.3 Structural Stiffness
46(14)
3.1.4 Approximate Structural Period
60(1)
3.1.5 Time-Dependent Forced Undamped Vibration Response
61(3)
3.2 Damped Single-Degree-of-Freedom System
64(19)
3.2.1 Free Vibration Response of Damped Systems
65(6)
3.2.2 Structural Damping
71(2)
3.2.3 Time-Dependent Forced Damped Vibration Response
73(5)
3.2.4 Time-Dependent Support Accelerations
78(5)
3.3 Base Shears and Stresses Caused by Time-Dependent Forces and Support Excitations
83(8)
Problems
86(4)
References
90(1)
Chapter 4 Response to General Loading
91(32)
4.1 Response of an SDOF System to an Impulse
91(3)
4.2 General Forcing Function
94(8)
4.3 Shock Spectra
102(9)
4.4 Response to Ground Motion
111(3)
4.5 Direct Integration Methods
114(9)
4.5.1 Nigam-Jennings Algorithm (Explicit)
114(3)
4.5.2 Central Difference Method (Explicit)
117(3)
4.5.3 Newmark's Beta Method for Linear Systems (Implicit)
120(1)
Problems
121(1)
Reference
122(1)
Chapter 5 Response Spectrum Analysis of SDOF System
123(28)
5.1 Elastic Response Spectrum
123(17)
5.1.1 Elastic Design Response Spectrum
132(8)
5.2 Inelastic Response Spectrum
140(11)
5.2.1 Inelastic Design Response Spectrum
143(3)
Problems
146(3)
References
149(2)
Chapter 6 Generalized SDOF System Analysis
151(18)
6.1 Discrete System (Shear Buildings)
152(10)
6.1.1 Equation of Motion
152(5)
6.1.2 Generalized Participation Factor, Frequency, and Natural Period
157(1)
6.1.3 Deflections, Base Shear, and Moments Using Participation Factors and Response Spectra
157(5)
6.2 Generalized SDOF Continuous System
162(7)
6.2.1 Equation of Motion
162(1)
6.2.2 Generalized Participation Factor, Frequency, and Natural Period
163(1)
6.2.3 Deflections, Base Shear, and Moments Using Participation Factors and Response Spectra
163(4)
Problems
167(1)
References
168(1)
Chapter 7 Multi-Degree-of-Freedom System Analysis
169(34)
7.1 Equations of Motion for an MDOF System
171(17)
7.1.1 Periods and Mode Shapes for an MDOF System
172(8)
7.1.2 Participation Factors for an MDOF System
180(2)
7.1.3 Deflections, Base Shear, and Moments Using Participation Factors and Response Spectra
182(6)
7.2 Response Spectrum Analysis Method Summary
188(15)
Problems
199(2)
References
201(2)
Chapter 8 Seismic Code Provisions
203(44)
8.1 Structural Design Philosophies
203(4)
8.1.1 Allowable Stress Design
204(2)
8.1.2 Load and Resistance Factor Design
206(1)
8.1.3 Allowable Seismic Force-Resisting System
206(1)
8.2 Overview of Seismic Design Codes
207(1)
8.3 Seismic Load Combinations
208(5)
8.3.1 Redundancy Factor, ρ
210(1)
8.3.2 Overstrength Factor Ω0 and other Seismic Force-Resisting System Parameters
211(2)
8.4 Overview of Seismic Load Analysis Procedures
213(7)
8.4.1 Design Response Spectrum
213(6)
8.4.2 Permitted Lateral Analysis Procedures
219(1)
8.5 Earthquake Loads Based on ASCE-7 Equivalent Lateral Force Procedure
220(9)
8.6 Modal Response Spectrum Analysis
229(11)
8.7 Introduction to Seismic Response History Procedures
240(7)
Problems
241(5)
References
246(1)
Index 247
Dr. Hector Estrada, P.E. is currently Professor of Civil Engineering at University of the Pacific (Pacific); where he also served as Chair of the Civil Engineering Department. Prior to joining Pacific, Professor Estrada was chair of the Department of Civil and Architectural Engineering at Texas A&M University-Kingsville. Dr. Estrada has also had visiting research appointments at NASA, Texas Tech University, and the US Army Engineer Research and Development Center Construction Engineering Research Laboratory. His teaching interests include structural engineering and mechanics, the design of concrete, steel, and timber structures, structural dynamics, and earthquake engineering. He has published on structural engineering and engineering education in various peer-reviewed journals, conference proceedings, and presented research work at various technical conferences. He has published a book on drafting and design of structural steel buildings, and several book chapters. He has served as reviewer for a number of journals, conferences, book publishers, and funding agencies. Professor Estrada received his B.S. (with honors), M.S., and Ph.D. all in Civil Engineering from the University of Illinois at Urbana-Champaign.

Dr. Luke Lee, Ph.D., P.E. is currently Associate Professor of Civil Engineering at University of the Pacific where he teaches courses in solid mechanics, structural dynamics and health monitoring, structural design, and engineering risk analysis. He has authored and co-authored numerous journal articles, conference papers, and book chapters in composite materials, structural health monitoring, service life estimation, and engineering pedagogy. Dr. Lee received his B.S. in Civil Engineering from University of California, Los Angeles, M.S. in Civil Engineering from University of California, Berkeley, and Ph.D. in Structural Engineering from University of California, San Diego.
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