acoustic performance modeling
advanced vibration simulation case study
Aliasing Distortion
analysis
Category=UY
Centered Difference Approximation
Daubechies Wavelets
Digital Fourier
Digital Fourier Analysis
Direct Integration Approach
Dunkerley's Formula
Effective Noise Bandwidth
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FE Program
FEA Model
Finite Difference Methods
fourier
Fourier Spectrum
Fourth Order Runge Kutta Method
frequencies
Fundamental Frequency
Gabor Transform
MATLAB simulation techniques
mechanical system dynamics
Modal Superposition
Modal Superposition Approach
mode
Mode Shapes
Morlet Wavelet
multibody system analysis
natural
Natural Frequencies
Ordinary Differential Equations
response
Rotational DoF
Runge Kutta Method
shapes
signal processing methods
spectrum
transform
Transient Dynamic Analysis
vibration control engineering
wavelet
Wavelet Transform
Product details
- ISBN 9781420053173
- Weight: 521g
- Dimensions: 178 x 254mm
- Publication Date: 27 Mar 2007
- Publisher: Taylor & Francis Inc
- Publication City/Country: US
- Product Form: Hardback
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Understanding and controlling vibration is critical for reducing noise, improving work environments and product quality, and increasing the useful life of industrial machinery and other mechanical systems. Computer-based modeling and analytical tools provide fast, accurate, and efficient means of designing and controlling a system for improved vibratory and, subsequently, acoustic performance. Computer Techniques in Vibration provides an overview as well as a detailed account and application of the various tools and techniques available for modeling and simulating vibrations.
Drawn from the immensely popular Vibration and Shock Handbook, each expertly crafted chapter of this book includes convenient summary windows, tables, graphs, and lists to provide ready access to the important concepts and results. Working systematically from general principles to specific applications, the coverage spans from numerical techniques, modeling, and software tools to analysis of flexibly supported multibody systems, finite element applications, vibration signal analysis, fast Fourier transform (FFT), and wavelet techniques and applications. MATLAB® toolboxes and other widely available software packages feature prominently in the discussion, accompanied by numerous examples, sample outputs, and a case study.
Instead of wading through heavy volumes or software manuals for the techniques you need, find a ready collection of eminently practical tools in Computer Techniques in Vibration.
Clarence W. de Silva
