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Engineering Vibration, 5th edition

Published by Pearson (August 4, 2021) © 2022

  • Daniel J. Inman University of Michigan
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Engineering Vibration is a thorough introduction to vibration analysis, design, measurement, and computation. It connects traditional design-oriented topics, an introduction of modal analysis and the use of computational codes with MATLAB®. Special-interest windows summarize essential background information pertinent to the topic discussed so you don't have to search for formulas. Additional design, measurement and computation topics help you develop a dynamic understanding of vibration phenomena and connect theory to practice.

The 5th Edition is updated with new examples, problems, figures, equations, enhanced problem statements and a new units and conversion appendix. All MATLAB code has been updated to 2020 standards.

  1. INTRODUCTION TO VIBRATION AND THE FREE RESPONSE
    • 1.1 Introduction to Free Vibration
    • 1.2 Harmonic Motion
    • 1.3 Viscous Damping
    • 1.4 Modeling and Energy Methods
    • 1.5 Stiffness
    • 1.6 Measurement
    • 1.7 Design Considerations
    • 1.8 Stability
    • 1.9 Numerical Integration of the Time Response
    • 1.10 Coulomb Friction and the Pendulum
    • Problems
  2. RESPONSE TO HARMONIC EXCITATION
    • 2.1 Harmonic Excitation of Undamped Systems
    • 2.2 Harmonic Excitation of Damped Systems
    • 2.3 Alternative Representations
    • 2.4 Base Excitation
    • 2.5 Rotating Unbalance
    • 2.6 Measurement Devices
    • 2.7 Other Forms of Damping
    • 2.8 Numerical Integration and Design
    • 2.9 Nonlinear Response Properties
    • Problems
  3. GENERAL FORCED RESPONSE
    • 3.1 Impulse Response Function
    • 3.2 Response to an Arbitrary Input
    • 3.3 Response to an Arbitrary Periodic Input
    • 3.4 Transform Methods
    • 3.5 Response to Random Inputs
    • 3.6 Shock Spectrum
    • 3.7 Measurement via Transfer Functions
    • 3.8 Stability
    • 3.9 Numerical Integration of the Response
    • 3.10 Nonlinear Response Properties
    • Problems
  4. MULTIPLE-DEGREE-OF-FREEDOM SYSTEMS
    • 4.1 Two-Degree-of-Freedom Model (Undamped)
    • 4.2 Eigenvalues and Natural Frequencies
    • 4.3 Modal Analysis
    • 4.4 More Than Two Degrees of Freedom
    • 4.5 Systems with Viscous Damping
    • 4.6 Modal Analysis of the Forced Response
    • 4.7 Lagrange’s Equations
    • 4.8 Examples
    • 4.9 Computational Eigenvalue Problems for Vibration
    • 4.10 Numerical Integration of the Time Response
    • Problems
  5. DESIGN FOR VIBRATION SUPPRESSION
    • 5.1 Acceptable Levels of Vibration
    • 5.2 Vibration Isolation
    • 5.3 Vibration Absorbers
    • 5.4 Damping in Vibration Absorption
    • 5.5 Optimization
    • 5.6 Viscoelastic Damping Treatments
    • 5.7 Critical Speeds of Rotating Disks
    • 5.8 Approximation and Scaling
    • Problems
  6. DISTRIBUTED-PARAMETER SYSTEMS
    • 6.1 Vibration of a String or Cable
    • 6.2 Modes and Natural Frequencies
    • 6.3 Vibration of Rods and Bars
    • 6.4 Torsional Vibration
    • 6.5 Bending Vibration of a Beam
    • 6.6 Vibration of Membranes and Plates
    • 6.7 Models of Damping
    • 6.8 Modal Analysis of the Forced Response
    • Problems
  7. VIBRATION TESTING AND EXPERIMENTAL MODAL ANALYSIS
    • 7.1 Measurement Hardware
    • 7.2 Digital Signal Processing
    • 7.3 Random Signal Analysis in Testing
    • 7.4 Modal Data Extraction
    • 7.5 Modal Parameters by Circle Fitting
    • 7.6 Mode Shape Measurement
    • 7.7 Vibration Testing for Endurance and Diagnostics
    • 7.8 Operational Deflection Shape Measurement
    • Problems
  8. FINITE ELEMENT METHOD
    • 8.1 Example: The Bar
    • 8.2 Three-Element Bar
    • 8.3 Beam Elements
    • 8.4 Lumped-Mass Matrices
    • 8.5 Trusses
    • 8.6 Model Reduction
    • Problems

APPENDICES

  • A. COMPLEX NUMBERS AND FUNCTIONS
  • B. LAPLACE TRANSFORMS
  • C. MATRIX BASICS
  • D. THE VIBRATION LITERATURE
  • E. LIST OF SYMBOLS
  • F. CODES AND WEB SITES
  • G. UNITS AND CONVERSIONS

REFERENCES

ANSWERS TO SELECTED PROBLEMS

INDEX

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