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9780824703875

Matrix Analysis of Structural Dynamics: Applications and Earthquake Engineering

by ;
  • ISBN13:

    9780824703875

  • ISBN10:

    0824703871

  • Edition: 1st
  • Format: Hardcover
  • Copyright: 2000-10-19
  • Publisher: CRC Press

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Summary

Uses state-of-the-art computer technology to formulate displacement method with matrix algebra. Facilitates analysis of structural dynamics and applications to earthquke engineering and UBC and IBC seismic building codes.

Author Biography

Franklin Y. Cheng was appointed Curators' Professor of Civil Engineering in 1987, the highest professorial position in Missouri's university system, and is Senior Investigator, Intelligent Systems Center, University of Missouri, Rolla

Table of Contents

Prefacep. iii
Characteristics of Free and Forced Vibrations of Elementary Systemsp. 1
Introductionp. 1
Free Undamped Vibrationp. 1
Motion Equation and Solutionp. 1
Initial Conditions, Phase Angle and Natural Frequencyp. 3
Periodic and Harmonic Motionp. 6
Free Damped Vibrationp. 7
Motion Equation and Viscous Dampingp. 7
Critical Damping, Overdamping and Underdampingp. 9
Logarithmic Decrement and Evaluation of Viscous Damping Coefficientp. 11
Forced Undamped Vibrationp. 14
Harmonic Forcesp. 14
Steady-State Vibration and Resonancep. 15
Impulses and Shock Spectrap. 19
General Loading--Step Forcing Function Method vs. Duhamel's Integralp. 24
Forced Damped Vibrationp. 29
Harmonic Forcesp. 29
Steady-State Vibration for Damped Vibration, Resonant and Peak Amplitudep. 30
General Loading--Step-Forcing Function Method vs. Duhamel's Integralp. 32
Transmissibility and Response to Foundation Motionp. 36
Evaluation of Dampingp. 42
Equivalent Damping Coefficient Methodp. 42
Amplitude Method and Bandwidth Methodp. 43
Overviewp. 45
Bibliographyp. 45
Eigensolution Techniques and Undamped Response Analysis of Multiple-Degree-of-Freedom Systemsp. 47
Fundamentalsp. 47
Introductionp. 47
Characteristics of the Spring-Mass Modelp. 47
Advantages of the Lumped Mass Modelp. 48
Characteristics of Free Vibration of Two-Degree-of-Freedom Systemsp. 49
Motion Equations, Natural and Normal Modesp. 49
Harmonic and Periodic Motionp. 52
Dynamic Matrix Equationp. 54
Orthogonality of Normal Modesp. 55
Modal Matrix for Undamped Vibrationp. 56
Modal Matrices and Characteristicsp. 56
Response to Initial Disturbances, Dynamic Forces and Seismic Excitationp. 58
Effect of Individual Modes on Responsep. 64
Response to Foundation Movementp. 67
Eigensolution for Symmetric Matrixp. 72
Iteration Method for Fundamental and Higher Modesp. 72
Proof of Iterative Solutionp. 77
Extraction Technique for Natural Frequenciesp. 80
Choleski's Decomposition Methodp. 81
Generalized Jacobi Methodp. 87
Sturm Sequence Methodp. 95
Advanced Topicsp. 98
Eigensolution Technique for Unsymmetric Matrixp. 98
Classification of Casesp. 99
Iteration Methodp. 100
Response Analysis for Zero and Repeating Eigenvaluesp. 105
Zero and Repeating Eigenvalue Casesp. 105
Orthogonality Propertiesp. 105
Response Analysisp. 109
Bibliographyp. 114
Eigensolution Methods and Response Analysis for Proportional and Nonproportional Dampingp. 117
Fundamentalsp. 117
Introductionp. 117
Response Analysis for Proportional Dampingp. 117
Based on a Modal Matrixp. 117
Proportional Dampingp. 120
Evaluation of Damping Coefficients and Factorsp. 121
Two Modes Requiredp. 121
All Modes Requiredp. 125
Damping Factors from Damping Coefficientsp. 125
Determination of Proportional and Nonproportional Dampingp. 126
Advanced Topicsp. 128
Characteristics of Complex Eigenvalues for Nonproportional Dampingp. 128
Iteration Method for Fundamental and Higher Modes of Complex Eigenvaluesp. 137
Fundamental Modep. 137
Orthogonality Condition and Iteration for Higher Modesp. 139
Step-by-Step Proceduresp. 139
Response Analysis with Complex Eigenvaluesp. 149
Relationship Between Undamped, Proportional Damping, and Nonproportional Dampingp. 156
Bibliographyp. 159
Dynamic Stiffness and Energy Methods for Distributed Mass Systemsp. 161
Introductionp. 161
Derivation of Bernoulli-Euler Equationp. 161
Derivation of Dynamic Stiffness Coefficientsp. 166
Characteristics of Dynamic Stiffness Coefficientsp. 168
Numerals and Curves for Coefficientsp. 168
Rayleigh's Dynamic Reciprocal Principlep. 171
Muller-Breslau's Principlep. 173
Dynamic Stiffness, Load, and Mass Matricesp. 175
Degree-of-Freedom of Plane Structural Systemsp. 175
Equilibrium Matricesp. 176
Compatibility Matricesp. 177
Dynamic Stiffness Matrixp. 178
Dynamic Load Matrixp. 179
System Matrix Equationp. 180
Derivation of Dynamic Fixed-end Moments and Fixed-end Shearsp. 180
Differential Equationsp. 181
Uniform Loadp. 182
Triangular Loadp. 183
Concentrated Load between Nodesp. 185
Foundation Movementp. 186
Numerical Technique for Eigensolutionsp. 186
Steady-State Response Analysisp. 198
Response for General Forcing Functions with and without Dampingp. 203
Kinetic and Strain Energyp. 203
Orthogonality Conditionp. 204
Dissipated Energy and Workp. 205
Response Equationsp. 206
Bibliographyp. 212
Dynamic Stiffness Method for Coupling Vibration, Elastic Media and P-[Delta] Effectp. 213
Fundamentalsp. 213
Introductionp. 213
Longitudinal Vibration and Stiffness Coefficientsp. 213
Longitudinal Vibration and Stiffness Coefficients with Elastic Mediap. 214
Dynamic Analysis of Trusses and Elastic Framesp. 216
Dynamic Stiffness Coefficients of Pin-connected Memberp. 216
Dynamic Stiffness Matrix of Trussesp. 218
Dynamic Stiffness Matrix of Elastic Framesp. 221
Coupling of Longitudinal and Flexural Vibrationp. 224
Torsional Vibration and Stiffness Coefficientsp. 229
Dynamic Stiffness Matrix of Grid Systemsp. 230
Coupling of Torsional and Flexural Vibrationp. 233
Advanced Topicsp. 237
Bernoulli-Euler Equation with Elastic Mediap. 237
Bernoulli-Euler Equation with Elastic Media and P-[Delta] Effectp. 238
Timoshenko Equation (Bending and Shear Deformation and Rotatory Inertia)p. 240
Differential Equationsp. 240
Stiffness Coefficientsp. 243
Fixed-end Forces for Steady-State Vibrationp. 246
Response Analysis for General Forcing Functionsp. 247
Effect of Various Parameters on Frequenciesp. 252
Timoshenko Equation with Elastic Media and P-[Delta] Effectp. 252
Differential Equationsp. 253
Stiffness Coefficientsp. 255
Fixed-end Forcesp. 256
Case Studies of the Effect of Various Parameters on Frequenciesp. 257
Bibliographyp. 258
Consistent Mass Method for Frames and Finite Elementsp. 261
Fundamentalsp. 261
Introductionp. 261
Energy Method for Motion Equationp. 262
Rigid Framesp. 263
Elastic Framesp. 265
Stiffness, Mass and Generalized Force Matrices for Frame Membersp. 265
Two-Force Memberp. 265
Torsional Memberp. 268
Flexural Memberp. 270
Eigenvalue Comparisons Among Lumped Mass, Dynamic Stiffness and Consistent Mass Methodsp. 283
Advanced Topicsp. 285
Stiffness, Mass and Generalized Force Matrices for Finite Elementsp. 285
Finite Element Formulation--Generalized Coordinatesp. 286
Finite Element Formulation--Natural Coordinatesp. 291
Motion Equation with P-[Delta] Effectp. 303
Potential Energy and Motion Equationp. 303
Geometric Matrix with Rotation and Deflectionp. 305
Geometric Matrix (String Stiffness) with Deflectionp. 305
Timoshenko Prismatic Member with P-[Delta] Effectp. 306
Displacement and Shape Functionsp. 306
Stiffness Matrixp. 308
Mass Matrixp. 309
Generalized Force Matrixp. 312
Geometric Matrixp. 312
Timoshenko Tapered Member with P-[Delta] Effectp. 314
Stiffness Matrixp. 314
Mass Matrixp. 315
Generalized Force Matrixp. 317
Geometric Matrixp. 317
Comments on Lumped Mass, Consistent Mass, and Dynamic Stiffness Modelsp. 318
Bibliographyp. 319
Numerical Integration Methods and Seismic Response Spectra for Single-and Multi-Component Seismic Inputp. 321
Fundamentalsp. 321
Introductionp. 321
Earthquakes and Their Effects on Structuresp. 321
Earthquake Characteristicsp. 321
Intensity, Magnitude, and Acceleration of Earthquakesp. 322
Relationship Between Seismic Zone, Acceleration, Magnitude, and Intensityp. 326
Earthquake Principal Componentsp. 327
Numerical Integration and Stabilityp. 329
Newmark Integration Methodp. 329
Wilson-[Theta] Methodp. 332
General Numerical Integration Related to Newmark and Wilson-[Theta] Methodsp. 334
Runge-Kutta Fourth-Order Methodp. 338
Numerical Stability and Error of Newmark and Wilson-[Theta] Methodsp. 350
Numerical Stability of Runge-Kutta Fourth-Order Methodp. 358
Seismic Response Spectra for Analysis and Designp. 361
Response Spectra, Pseudo-Spectra and Principal-Component Spectrap. 362
Housner's Average Design Spectrap. 369
Newmark Elastic Design Spectrap. 371
Newmark Inelastic Design Spectrap. 372
Site-Dependent Spectra and UBC-94 Design Spectrap. 378
Various Definitions of Ductilityp. 380
Advanced Topicsp. 383
Torisonal Response Spectrap. 383
Ground Rotational Records Generationp. 383
Construction of Torsional Response Spectrap. 389
Response Spectra Analysis of a Multiple d.o.f. Systemsp. 390
SRSS Modal Combination Methodp. 393
CQC Modal Combination Methodp. 394
Structural Response Due to Multiple-Component Seismic Inputp. 397
Maximum (Worst-Case) Response Analysis for Six Seismic Componentsp. 399
Based on SRSS Methodp. 400
Based on CQC Methodp. 404
Composite Translational Spectrum and Torsional Spectrump. 410
Construction of the Composite Response Spectrump. 411
Composite Spectral Modal Analysisp. 412
Overviewp. 414
Bibliographyp. 414
Formulation and Response Analysis of Three-Dimensional Building Systems with Walls and Bracingsp. 417
Fundamentalsp. 417
Introductionp. 417
Joints, Members, Coordinate Systems, and Degree of Freedom (d.o.f.)p. 417
Coordinate Transformation Between JCS and GCS: Methods 1 and 2p. 418
Force Transformation Between Slave Joint and Master Jointp. 424
System d.o.f. as Related to Coordinate and Force Transformationp. 426
Beam-Columnsp. 429
Coordinate Transformation Between ECS and JCS or GCS: Methods 1 and 2p. 429
Beam-Column Stiffness in the ECSp. 431
Beam-Column Stiffness in the JCS or GCS Based on Method 1p. 434
Beam-Column Geometric Matrix (String Stiffness) in ECS and JCS or GCS Based on Method 1p. 438
Shear Wallsp. 439
Shear-Wall ECS and GCS Relationship Based on Method 1p. 439
Shear-Wall Stiffness in the ECSp. 441
Shear-Wall Stiffness in the JCS or GCS Based on Method 1p. 447
Shear-Wall Geometric Matrix (String Stiffness) in the JCS or GCS Based on Method 1p. 455
Bracing Elementsp. 455
Bracing-Element ECS and GCS Relationship Based on Method 1p. 455
Bracing-Element Stiffness in ECSp. 457
Bracing-Element Stiffness in the JCS or GCS Based on Method 1p. 457
Structural Characteristics of 3-D Building Systemsp. 462
Rigid Zone Between Member End and Joint Centerp. 462
Building-Structure-Element Stiffness with Rigid Zonep. 464
Beam-Column Stiffness in ECS Based on Method 2p. 464
Beam-Column Stiffness in GCS Based on Method 2p. 466
Beam-Column Geometric Matrix (String Stiffness) in JCS or GCS Based on Method 2p. 473
Beam Stiffness in the GCS Based on Method 2p. 475
Bracing-Element Stiffness in the JCS or GCS Based on Method 2p. 479
Shear-Wall Stiffness in the JCS or GCS Based on Method 2p. 482
Shear-Wall Geometric Matrix (String Stiffness) in the JCS or GCS Based on Method 2p. 487
Advanced Topicsp. 490
Assembly of Structural Global Stiffness Matrixp. 490
General System Assembly (GSA)p. 490
Floor-by-Floor Assembly (FFA)p. 498
Mass Matrix Assemblyp. 504
Loading Matrix Assemblyp. 508
Vertical Static or Harmonic Forcesp. 509
Lateral Wind Forcesp. 511
Lateral Dynamic Loadsp. 513
Seismic Excitationsp. 514
Analysis and Response Behavior of Sample Structural Systemsp. 516
Overviewp. 523
Bibliographyp. 525
Various Hysteresis Models and Nonlinear Response Analysisp. 527
Fundamentalsp. 527
Introductionp. 527
Material Nonlinearity and Stress-Strain Modelsp. 528
Bauschinger Effect on Moment-Curvature Relationshipp. 528
Elasto-Plastic Hysteresis Modelp. 529
Stiffness Matrix Formulationp. 532
Bilinear Hysteresis Modelp. 534
Stiffness Matrix Formulationp. 535
Convergence Techniques at Overshooting Regionsp. 538
State of Yield and Time-Increment Techniquep. 538
Unbalanced Force Techniquep. 539
Equilibrium and Compatibility Checks for Numerical Solutionsp. 552
Curvilinear Hysteresis Modelp. 555
Stiffness Matrix Formulationp. 556
Stiffness Comparison Between Bilinear and Curvilinear Modelsp. 560
Ramberg-Osgood Hysteresis Modelp. 562
Parameter Evaluations of Ramberg-Osgood Stress-Strain Curvep. 562
Ramberg-Osgood Moment-Curvature Curvesp. 563
Stiffness Matrix Formulation for Skeleton Curvep. 565
Stiffness Matrix Formulation for Branch Curvep. 570
Advanced Topicsp. 579
Geometric Nonlinearityp. 579
Interaction Effect on Beam Columnsp. 589
Elasto-Plastic Analysis of Consistent Mass Systemsp. 591
Stiffness Matrix Formulationp. 591
Moments, Shears and Plastic Hinge Rotationsp. 595
Hysteresis Models of Steel Bracing, RC Beams, Columns and Shear Wallsp. 604
Overviewp. 604
Bibliographyp. 605
Static and Dynamic Lateral-Force Procedures and Related Effects in Building Codes of UBC-94, UBC-97 and IBC-2000p. 607
Fundamentalsp. 607
Introductionp. 607
Background of Lateral Force Procedures in Building Codesp. 608
Effective Earthquake Force and Effective Massp. 608
Base Shear and Overturning Momentp. 610
UBC-94 and Design Parametersp. 612
Criteria for Appropriate Lateral-Force Procedurep. 612
Base Shear of Static Lateral-Force Procedure and Related Parametersp. 612
Vertical Distribution of Lateral Forcep. 620
Story Shear and Overturning Momentp. 620
Torsion and P-[Delta] Effectp. 621
Story Drift Limitationsp. 623
3R[subscript w]/8 Factorp. 623
UBC-97 and Design Parametersp. 624
Criteria for Appropriate Lateral-Force Procedurep. 624
Base Shear of Static Lateral-Force Procedure and Related Parametersp. 624
R[subscript w] and R Relationship vs Load Combinationp. 626
Load Combination for Strength Design and Allowable Stress Designp. 627
Story Shear, Overturning Moment and Restoring Momentp. 631
Story Drift, P-[Delta] Effect and Torsionp. 632
Relationships Among 3R[subscript w]/8, [Omega subscript 0] and 0.7R[Delta subscript s]p. 632
IBC-2000 and Design Parametersp. 633
Criteria for Appropriate Lateral-Force Procedurep. 633
Base Shear of Equivalent Lateral-Force Procedure and Related Parametersp. 633
Vertical Distribution of Lateral Forcep. 638
Horizontal Shear Distribution and Overturning Momentp. 639
Deflection and Story Driftp. 639
P-[Delta] Effectp. 640
Summary Comparison of UBC-94, UBC-97 and IBC-2000 Lateral-Force Proceduresp. 641
Numerical Illustrations of Lateral-Force Procedure for UBC-94, UBC-97 and IBC-2000p. 648
Techniques for Calculating Rigidity Centerp. 672
Method A--Using Individual Member Stiffness for Rigid-floor Shear Buildingsp. 672
Method B--Using Relative Rigidity of Individual Bays for General Buildingsp. 673
Advanced Topicsp. 675
Dynamic Analysis Procedures of UBC-94, UBC-97 and IBC-2000p. 675
UBC-94 Dynamic Analysis Procedurep. 675
UBC-97 Dynamic Analysis Procedurep. 676
IBC-2000 Dynamic Analysis Procedurep. 678
Regionalized Seismic Zone Maps and Design Response Spectra in UBC-97 and IBC-2000p. 682
Summary Comparison of UBC-94, UBC-97 and IBC-2000 Dynamic Analysis Proceduresp. 684
Numerical Illustrations of Dynamic Analysis Procedures for UBC-94, UBC-97 and IBC-2000p. 688
Overviewp. 705
Bibliographyp. 705
Problemsp. 707
Problemsp. 715
Problemsp. 721
Problemsp. 723
Problemsp. 727
Problemsp. 733
Problemsp. 741
Problemsp. 745
Problemsp. 753
Problemsp. 757
Solutionsp. 763
Solutionsp. 767
Solutionsp. 773
Solutionsp. 777
Solutionsp. 783
Solutionsp. 791
Solutionsp. 797
Solutionsp. 799
Solutionsp. 807
Solutionsp. 811
Lagrange's Equationp. 817
Derivation of Ground Rotational Recordsp. 823
Vector Analysis Fundamentalsp. 827
Transformation Matrix Between JCS and GCSp. 831
Transformation Matrix Between ECS and GCS for Beam Columnp. 843
Transformation Matrix [A'] and Stiffness Matrix [K superscript i subscript eg] of Beam Column with Rigid Zonep. 851
Computer Program for Newmark Methodp. 855
Computer Program for Wilson-[Theta] Methodp. 863
Computer Program for CQC Methodp. 865
Jain-Goel-Hanson Steel-Bracing Hysteresis Model and Computer Programp. 875
Takeda Model for RC Columns and Beams and Computer Programp. 895
Cheng-Mertz Model for Bending Coupling with Shear and Axial Deformations of Low-Rise Shear Walls and Computer Programp. 913
Bending: Low-Rise Shear Wall Cheng-Mertz Hysteresis Modelp. 913
Shear: Low-Rise Shear Wall Cheng-Mertz Hysteresis Modelp. 932
Axial: Low-Rise Shear Wall Cheng-Mertz Hysteresis Modelp. 952
Cheng-Lou Axial Hysteresis Model for RC Columns and Walls and Computer Programp. 967
Notationp. 979
Indexp. 989
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