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More About This Title Hilbert Transform Applications in MechanicalVibration
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This book will appeal to both professionals and students working in mechanical, aerospace, and civil engineering, as well as naval architecture, biomechanics, robotics, and mechatronics.
Hilbert Transform Applications in Mechanical Vibration employs modern applications of the Hilbert transform time domain methods including:
- The Hilbert Vibration Decomposition method for adaptive separation of a multi-component non-stationary vibration signal into simple quasi-harmonic components; this method is characterized by high frequency resolution, which provides a comprehensive account of the case of amplitude and frequency modulated vibration analysis.
- The FREEVIB and FORCEVIB main applications, covering dynamic testing and extraction of the modal parameters of nonlinear vibration systems including the initial elastic and damping force characteristics under free and forced vibration regimes. Identification methods contribute to efficient and accurate testing of vibration systems, avoiding effort-consuming measurement and analysis.
- Precise identification of nonlinear and asymmetric systems considering high frequency harmonics on the base of the congruent envelope and congruent frequency.
- Accompanied by a website at www.wiley.com/go/feldman, housing MATLAB®/ SIMULINK codes.
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Michael Feldman is Computer System Engineer and Adjunct Senior Lecturer in the Faculty of Mechanical Engineering, Technion. His research focuses on signal processing, vibration engineering; analysis of dynamic signals and mechanical systems, modal testing and monitoring and diagnostics of machines. He is a past editor of the Journal Mechanical Systems and Signal Processing and has authored two books in Russian as well as contributions to the Encyclopedia of Structural Health Monitoring (Wiley, 2009) and Encyclopedia of Vibration (Academic Press, 2001).
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List of Tables.
Preface.
1 INTRODUCTION.
1.1 Brief History of the Hilbert Transform.
1.2 Hilbert Transform in Vibration Analysis.
1.3 Organization of the Book.
PART I. HILBERT TRANSFORM AND ANALYTIC SIGNAL.
2 ANALYTIC SIGNAL REPRESENTATION.
2.1 Local Versus Global Estimations.
2.2 The Hilbert Transform Notation.
2.3 Main Properties of the Hilbert Transform.
2.4 The Hilbert Transform of Multiplication.
2.5 Analytic Signal Representation.
2.6 Polar Notation.
2.7 Angular Position and Speed.
2.8 Signal Waveform and Envelope.
2.9 Instantaneous Phase.
2.10 Instantaneous Frequency.
2.11 Envelope vs. Instantaneous Frequency Plot.
2.12 Distribution Functions of the Instantaneous Characteristics.
2.13 Signal Bandwidth.
2.14 Instantaneous Frequency Distribution and Negative Values.
2.15 Conclusions.
3 SIGNAL DEMODULATION.
3.1 Envelope and Instantaneous Frequency Extraction.
3.2 Hilbert Transform and Synchronous Detection.
3.3 Digital Hilbert Transformers.
3.4 Instantaneous Characteristics Distortions.
3.5 Conclusions.
Part II. HILBERT TRANSFORM AND VIBRATION SIGNALS.
4 TYPICAL EXAMPLES AND DESCRIPTION OF VIBRATION DATA.
4.1 Random Signal.
4.2 Decay Vibration Waveform.
4.3 Slow Linear Sweeping Frequency Signal.
4.4 Harmonic Frequency Modulation.
4.5 Harmonic Amplitude Modulation.
4.6 Product of Two Harmonics.
4.7 Single Harmonic with DC Offset.
4.8 Composition of Two Harmonics.
4.9 Derivative and Integral of the Analytic Signal.
4.10 Signal Level.
4.11 Frequency Contents.
4.12 Narrowband and Wideband Signal.
4.13 Conclusions.
5 ACTUAL SIGNAL CONTENTS.
5.1 Monocomponent Signal.
5.2 Multicomponent Signal.
5.3 Types of multicomponent signals.
5.4 Averaging Envelope and Instantaneous Frequency.
5.5 Smoothing and Approximation of the Instantaneous Frequency.
5.6 Congruent Envelope.
5.7 Congruent Instantaneous Frequency.
5.8 Conclusions.
6 LOCAL AND GLOBAL VIBRATION DECOMPOSITIONS.
6.1 Empirical Mode Decomposition.
6.2 Analytical Basics of the EMD.
6.3 Global Hilbert Vibration Decomposition.
6.4 Instantaneous Frequency of the Largest Energy Component.
6.5 Envelope of the Largest Energy Component.
6.6 Subtraction of the Synchronous Largest Component.
6.7 Hilbert Vibration Decomposition Scheme.
6.8 Examples of Hilbert Vibration Decomposition.
6.9 Comparison of the Hilbert Transform Decomposition Methods.
6.10 Common Properties of the Hilbert Transform Decompositions.
6.11 The Differences between the Hilbert Transform Decompositions.
6.12 Amplitude-Frequency Resolution of HT Decompositions.
6.13 Limiting Number of Valued Oscillating Components.
6.14 Decompositions of Typical Non-stationary Vibration Signals.
6.15 Main Results and Recommendations.
6.16 Conclusions.
7 SIGNAL ANALYSIS PRACTICE EXPERIENCE AND INDUSTRIAL APPLICATION.
7.1 Structural Health Monitoring.
7.2 Standing and Traveling Wave Separation.
7.3 Echo Signal Estimation.
7.4 Synchronization Description.
7.5 Fatigue Estimation.
7.6 Multichannel Vibration Generation.
7.7 Conclusions.
Part III. HILBERT TRANSFORM AND VIBRATION SYSTEMS
8 VIBRATION SYSTEM CHARACTERISTICS.
8.1 Kramers-Kronig Relations.
8.2 Detection of Nonlinearities in Frequency Domain.
8.3 Typical Nonlinear Elasticity Characteristics.
8.4 Phase Plane Representation of Elastic Nonlinearities in Vibration Systems.
8.5 Complex Plane Representation.
8.6 Approximate Primary Solution of a Conservative Nonlinear System.
8.7 Hilbert Transform and Hysteretic Damping.
8.8 Nonlinear Damping Characteristics in SDOF Vibration System.
8.9 Typical Nonlinear Damping in Vibration System.
8.10 Velocity-Dependent Nonlinear Damping.
8.11 Velocity-Independent Damping.
8.12 Combination of Different Damping Elements.
8.13 Conclusions.
9 IDENTIFICATION OF THE PRIMARY SOLUTION.
9.1 Theoretical Bases of the Hilbert Transform System Identification.
9.2 Free Vibration Modal Characteristics.
9.3 Forced Vibration Modal Characteristics.
9.4 BackBone (Skeleton Curve).
9.5 Damping Curve.
9.6 Frequency Response.
9.7 Force Static Characteristics.
9.8 Conclusions.
10 THE FREEVIB and FORCEVIB METHODS.
10.1 FREEVIB Identification Examples.
10.2 FORCEVIB Identification Examples.
10.3 System Identification with Biharmonic Excitation.
10.4 Identification of Nonlinear Time-Varying System.
10.5 Experimental Identification of Nonlinear Vibration System.
10.6 Conclusions.
11 CONSIDERING HIGH ORDER SUPERHARMONICS. IDENTIFICATION OF ASYMMETRIC AND MDOF SYSTEMS.
11.1 Description of the Precise Method Scheme.
11.2 Identification of the Instantaneous Modal Parameters.
11.3 Congruent Modal Parameters.
11.4 Congruent Nonlinear Elastic and Damping Forces.
11.5 Examples of Precise Free Vibration Identification.
11.6 Forced Vibration Identification Considering High-Order Superharmonics.
11.7 Identification of Asymmetric Nonlinear System.
11.8 Experimental Identification of a Crack.
11.9 Identification of MDOF Vibration System.
11.10 Identification of Weakly Nonlinear Coupled Oscillators.
11.11 Conclusions.
12 SYSTEM ANALYSIS PRACTICE EXPERIENCE AND INDUSTRIAL APPLICATION.
12.1 Non-parametric Identification of Nonlinear Mechanical Vibration Systems.
12.2 Parametric Identification of Nonlinear Mechanical Vibrating Systems.
12.3 Structural Health Monitoring and Damage Detection.
12.4 Conclusions.
References.
Index.