Autore	Dilworth Brandon J
Edizione	[1st ed. 2024.]
Pubbl/distr/stampa	Cham : , : Springer Nature Switzerland : , : Imprint : Springer, , 2024
Descrizione fisica	1 online resource (212 pages)
Disciplina	624.171
Altri autori (Persone)	MarinoneTimothy MainsMichael
Collana	Conference Proceedings of the Society for Experimental Mechanics Series
Soggetto topico	Multibody systems Vibration Mechanics, Applied Statics Buildings - Design and construction Civil engineering Building materials Multibody Systems and Mechanical Vibrations Mechanical Statics and Structures Building Construction and Design Civil Engineering Structural Materials
ISBN	3-031-34942-3
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Automated Operational Modal Analysis on a Full-Scale Wind Turbine Tower -- , Combining Non Traditional Response Variables with Acceleration Data for Experimental Modal Analysis -- , A Somewhat Comprehensive Critique of Experimental Modal Analysis -- ,OMA of a High-rise TV Tower Using the Novel Poly-reference Complex Frequency Modal Identification Technique Formulated in Modal Model -- , The New Poly-reference Complex Frequency Formulated In Modal Model (pCF-MM): A New Trend In Experimental Modal Analysis? -- ,Mode Shape Identification using Drive-by Monitoring: A Comparative Study -- ,Tips, Tricks, and Obscure Features for Modal Parameter Estimation -- ,Modal Analysis using a UAV-deployable Wireless Sensor Network -- ,Vibration-based Approach for Identifying Closely Spaced Modes in Space Frame Structures and Derivation of Member Axial Forces -- ,A Technique for Minimizing Robot-Induced Modal Excitations for On-Orbit Servicing, Assembly, and Manufacturing Structures -- ,Design Optimization of 3D Printed Chiral Metamaterials with Simultaneous High Stiffness and High Damping -- ,Modal Analysis of a Coilable Composite Tape Spring Boom with Parabolic Cross Section -- ,On the Behavior of Superimposed Orthogonal Structure-Borne Traveling Waves in Two-Dimensional Finite surfaces -- ,Comparative Assessment of Force Estimation in MIMO Tests -- , Online Implementation of the Local Eigenvalue Modification Procedure for High-rate Model Assimilation -- , Modal Correlation is required to Reduce Uncertainty in Shock Analysis and Testing -- , Modal Analysis of a Time-Variable Ropeway System: Model Reduction and Vibration Instability Detection -- , Investigation of Rotating Structures' Modal Response by using DIC -- ,Increasing Multi-Axis Testing Confidence through Finite Element and Input Control Modeling -- ,Vibration-based Damage Detection of a Monopile Specimen Using Output-only Environmental Models -- , Analysis of Traveling Wave Properties of Mechanical Metamaterial Structures: Simulation and Experiment -- ,Data Sampling Frequency Impact on Automatic Operational Modal Analysis – Application on Long-Span Bridges -- ,Comparison of two Possible Dynamic Models for Gear Dynamic Analysis. - , Influence of Gearbox Flexibilities on Dynamic Overloads. - , Experimental Modal Analysis and Operational Deflection Shape Analysis of a Cantilever Plate in a Wind Tunnel with Finite Element Model Verification.
Record Nr.	UNINA-9910770270903321

Autore	Rui Xiaoting
Edizione	[1st edition]
Pubbl/distr/stampa	Hoboken, NJ : , : Wiley, , 2019
Descrizione fisica	1 online resource (150 pages)
Disciplina	531/.16
Soggetto topico	Mechanics, Analytic Matrices Multibody systems
ISBN	1-118-72482-8 1-118-72483-6 1-118-72481-X
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Intro -- Title Page -- Copyright Page -- Contents -- Introduction -- About the Author -- Foreword One for the Chinese Edition -- Foreword Two for the Chinese Edition -- Foreword Three for the Chinese Edition -- Foreword Four for the Chinese Edition -- Professor Rui's Method-Discrete Time Transfer Matrix Method for Multibody System Dynamics -- Preface -- Chapter 1 Introduction -- 1.1 The Status of the Multibody System Dynamics Method -- 1.2 The Transfer Matrix Method and the Finite Element Method -- 1.3 The Status of the Transfer Matrix Method for a Multibody System -- 1.4 Features of the Transfer Matrix Method for Multibody Systems -- 1.5 Launch Dynamics -- 1.6 Features of this Book -- 1.7 Sign Conventions -- Part I Transfer Matrix Method for Linear Multibody Systems -- Chapter 2 Transfer Matrix Method for Linear Multibody Systems -- 2.1 Introduction -- 2.2 State Vector, Transfer Equation and Transfer Matrix -- 2.3 Overall Transfer Equation, Overall Transfer Matrix and Boundary Conditions -- 2.4 Characteristic Equation -- 2.5 Computation for State Vector and Vibration Characteristics -- 2.6 Vibration Characteristics of Multibody Systems -- 2.7 Eigenvalues of Damped Vibration -- 2.8 Steady-state Response to Forced Vibration -- 2.9 Steady-state Response of Forced Damped Vibration -- Chapter 3 Augmented Eigenvector and System Response -- 3.1 Introduction -- 3.2 Body Dynamics Equation and Parameter Matrices -- 3.3 Basic Theory of the Orthogonality of Eigenvectors -- 3.4 Augmented Eigenvectors and their Orthogonality -- 3.5 Examples of the Orthogonality of Augmented Eigenvectors -- 3.6 Transient Response of a Multibody System -- 3.7 Steady-state Response of a Damped Multibody System -- 3.8 Steady-state Response of a Multibody System -- 3.9 Static Response of a Multibody System. Chapter 4 Transfer Matrix Method for Nonlinear and Multidimensional Multibody Systems -- 4.1 Introduction -- 4.2 Incremental Transfer Matrix Method for Nonlinear Systems -- 4.3 Finite Element Transfer Matrix Method for Two-dimensional Systems -- 4.4 Finite Element Riccati Transfer Matrix Method for Two-dimensional Nonlinear Systems -- 4.5 Fourier Series Transfer Matrix Method for Two-dimensional Systems -- 4.6 Finite Difference Transfer Matrix Method for Two-dimensional Systems -- 4.7 Transfer Matrix Method for Two-dimensional Systems -- Part II Transfer Matrix Method for Multibody Systems -- Chapter 5 Transfer Matrix Method for Multi-rigid-body Systems -- 5.1 Introduction -- 5.2 State Vectors, Transfer Equations and Transfer Matrices -- 5.3 Overall Transfer Equation and Overall Transfer Matrix -- 5.4 Transfer Matrix of a Planar Rigid Body -- 5.5 Transfer Matrix of a Spatial Rigid Body -- 5.6 Transfer Matrix of a Planar Hinge -- 5.7 Transfer Matrix of a Spatial Hinge -- 5.8 Transfer Matrix of an Acceleration Hinge -- 5.9 Algorithm of the Transfer Matrix Method for Multibody Systems -- 5.10 Numerical Examples of Multibody System Dynamics -- Chapter 6 Transfer Matrix Method for Multi-flexible-body Systems -- 6.1 Introduction -- 6.2 State Vector, Transfer Equation and Transfer Matrix -- 6.3 Overall Transfer Equation and Overall Transfer Matrix -- 6.4 Transfer Matrix of a Planar Beam -- 6.5 Transfer Matrix of a Spatial Beam -- 6.6 Numerical Examples of Multi-flexible-body System Dynamics -- Part III Discrete Time Transfer Matrix Method for Multibody Systems -- Chapter 7 Discrete Time Transfer Matrix Method for Multibody Systems -- 7.1 Introduction -- 7.2 State Vector, Transfer Equation and Transfer Matrix -- 7.3 Step-by-step Time Integration Method and Linearization -- 7.4 Transfer Matrix of a Planar Rigid Body. 7.5 Transfer Matrices of Spatial Rigid Bodies -- 7.6 Transfer Matrices of Planar Hinges -- 7.7 Transfer Matrices of Spatial Hinges -- 7.8 Algorithm of the Discrete Time Transfer Matrix Method for Multibody Systems -- 7.9 Numerical Examples of Multibody System Dynamics -- Chapter 8 Discrete Time Transfer Matrix Method for Multi-flexible-body Systems -- 8.1 Introduction -- 8.2 Dynamics of a Flexible Body with Large Motion -- 8.3 State Vector, Transfer Equation and Transfer Matrix -- 8.4 Transfer Matrix of a Beam with Large Planar Motion -- 8.5 Transfer Matrices of Smooth Hinges Connected to a Beam with Large Planar Motion -- 8.6 Transfer Matrices of Spring Hinges Connected to a Beam with Large Planar Motion -- 8.7 Transfer Matrix of a Fixed Hinge Connected to a Beam -- 8.8 Dynamics Equation of a Spatial Large Motion Beam -- 8.9 Transfer Matrix of a Spatial Large Motion Beam -- 8.10 Transfer Matrices of Fixed Hinges Connected to a Beam with Large Spatial Motion -- 8.11 Transfer Matrices of Smooth Hinges Connected to a Beam with Large Spatial Motion -- 8.12 Transfer Matrices of Spring Hinges Connected to a Beam with Large Spatial Motion -- 8.13 Algorithm of the Discrete Time Transfer Matrix Method for Multi-flexible-body Systems -- 8.14 Planar Multi-flexible-body System Dynamics -- 8.15 Spatial Multi-flexible-body System Dynamics -- Chapter 9 Transfer Matrix Method for Controlled Multibody Systems -- 9.1 Introduction -- 9.2 Mixed Transfer Matrix Method for Multibody Systems -- 9.3 Finite Element Transfer Matrix Method for Multibody Systems -- 9.4 Finite Segment Transfer Matrix Method for Multibody Systems -- 9.5 Transfer Matrix Method for Controlled Multibody Systems I -- 9.6 Transfer Matrix Method for Controlled Multibody Systems II -- Chapter 10 Derivation and Computation of Transfer Matrices -- 10.1 Introduction. 10.2 Derivation from Dynamics Equations -- 10.3 Derivation from an nth-order Differential Equation -- 10.4 Derivation from n First-order Differential Equations -- 10.5 Derivation from Stiffness Matrices -- 10.6 Computational Method of the Transfer Matrix -- 10.7 Improved Algorithm for Eigenvalue Problems -- 10.8 Properties of the Inverse Matrix of a Transfer Matrix -- 10.9 Riccati Transfer Matrix Method for Multibody Systems -- 10.10 Stability of the Transfer Matrix Method for Multibody Systems -- Chapter 11 Theorem to Deduce the Overall Transfer Equation Automatically -- 11.1 Introduction -- 11.2 Topology Figure of Multibody Systems -- 11.3 Automatic Deduction of the Overall Transfer Equation of a Closed-loop System -- 11.4 Automatic Deduction of the Overall Transfer Equation of a Tree System -- 11.5 Automatic Deduction of the Overall Transfer Equation of a General System -- 11.6 Automatic Deduction Theorem of the Overall Transfer Equation -- 11.7 Numerical Example of Closed-loop System Dynamics -- 11.8 Numerical Example of Tree System Dynamics -- 11.9 Numerical Example of Multi-level System Dynamics -- 11.10 Numerical Example of General System Dynamics -- Part IV Applications of the Transfer Matrix Method for Multibody Systems -- Chapter 12 Dynamics of Multiple Launch Rocket Systems -- 12.1 Introduction -- 12.2 Launch Dynamics Model of the System and its Topology -- 12.3 State Vector, Transfer Equation and Transfer Matrix -- 12.4 Overall Transfer Equation of the System -- 12.5 Vibration Characteristics of the System -- 12.6 Dynamics Response of the System -- 12.7 Launch Dynamics Equation and Forces Acting on the System -- 12.8 Dynamics Simulation of the System and its Test Verifying -- 12.9 Low Rocket Consumption Technique for the System Test -- 12.10 High Launch Precision Technique for the System. Chapter 13 Dynamics of Self-propelled Launch Systems -- 13.1 Introduction -- 13.2 Dynamics Model of the System and its Topology -- 13.3 State Vector, Transfer Equation and Transfer Matrix -- 13.4 Overall Transfer Equation of the System -- 13.5 Vibration Characteristics of the System -- 13.6 Dynamic Response of the System -- 13.7 Launch Dynamic Equations and Forces Analysis -- 13.8 Dynamics Simulation of the System and its Test Verifying -- Chapter 14 Dynamics of Shipboard Launch Systems -- 14.1 Introduction -- 14.2 Dynamics Model of Shipboard Launch Systems -- 14.3 State Vector, Transfer Equation and Transfer Matrix -- 14.4 Overall Transfer Equation of the System -- 14.5 Launch Dynamics Equation and Forces of the System -- 14.6 Solution of Shipboard Launch System Motion -- 14.7 Dynamics Simulation of the System and its Test Verifying -- Chapter 15 Transfer Matrix Library for Multibody Systems -- 15.1 Introdution -- 15.2 Springs -- 15.3 Rotary Springs -- 15.4 Elastic Hinges -- 15.5 Lumped Mass Vibrating in a Longitudinal Direction -- 15.6 Vibration of Rigid Bodies -- 15.7 Beam with Transverse Vibration -- 15.8 Shaft with Torsional Vibration -- 15.9 Rod with Longitudinal Vibration -- 15.10 Euler-Bernoulli Beam -- 15.11 Rectangular Plate -- 15.12 Disk -- 15.13 Strip Element of a Two-dimensional Thin Plate -- 15.14 Thick-walled Cylinder -- 15.15 Thin-walled Cylinder -- 15.16 Coordinate Transformation Matrix -- 15.17 Linearization and State Vectors -- 15.18 Spring and Damper Hinges Connected to Rigid Bodies -- 15.19 Smooth Hinges Connected to Rigid Bodies -- 15.20 Rigid Bodies Moving in a Plane -- 15.21 Spatial Rigid Bodies with Large Motion and Various Connections -- 15.22 Planar Beam with Large Motion -- 15.23 Spatial Beam with Large Motion -- 15.24 Fixed Hinges Connected to a Planar Beam with Large Motion. 15.25 Fixed Hinges Connected to a Spatial Beam with Large Motion.
Record Nr.	UNINA-9910554841503321

Autore	Matuttis Hans-Georg
Pubbl/distr/stampa	Singapore : , : Wiley, , 2014
Descrizione fisica	1 online resource (480 p.)
Disciplina	531/.163
Soggetto topico	Granular flow Discrete element method Multibody systems Mechanics, Applied - Computer simulation
ISBN	1-118-56728-5 1-118-56722-6 1-118-56721-8
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	UNDERSTANDING THE DISCRETE ELEMENT METHOD SIMULATION OF NON-SPHERICAL PARTICLES FOR GRANULARAND MULTI-BODY SYSTEMS; Copright; Contents; Exercises; About the Authors; Preface; Acknowledgements; List of Abbreviations; 1 Mechanics; 1.1 Degrees of freedom; 1.1.1 Particle mechanics and constraints; 1.1.2 From point particles to rigid bodies; 1.1.3 More context and terminology; 1.2 Dynamics of rectilinear degrees of freedom; 1.3 Dynamics of angular degrees of freedom; 1.3.1 Rotation in two dimensions; 1.3.2 Moment of inertia; 1.3.3 From two to three dimensions 1.3.4 Rotation matrix in three dimensions1.3.5 Three-dimensional moments of inertia; 1.3.6 Space-fixed and body-fixed coordinate systems andequations of motion; 1.3.7 Problems with Euler angles; 1.3.8 Rotations represented using complex numbers; 1.3.9 Quaternions; 1.3.10 Derivation of quaternion dynamics; 1.4 The phase space; 1.4.1 Qualitative discussion of the time dependence of linear oscillations; 1.4.2 Resonance; 1.4.3 The flow in phase space; 1.5 Nonlinearities; 1.5.1 Harmonic balance; 1.5.2 Resonance in nonlinear systems; 1.5.3 Higher harmonics and frequency mixing 1.5.4 The van der Pol oscillator1.6 From higher harmonics to chaos; 1.6.1 The bifurcation cascade; 1.6.2 The nonlinear frictional oscillator and Poincar ́e maps; 1.6.3 The route to chaos; 1.6.4 Boundary conditions and many-particle systems; 1.7 Stability and conservationlaws; 1.7.1 Stability in statics; 1.7.2 Stability in dynamics; 1.7.3 Stable axes of rotation around the principal axis; 1.7.4 Noether's theorem and conservation laws; 1.8 Further reading; Exercises; References; 2Numerical Integration of OrdinaryDifferential Equations; 2.1 Fundamentals of numerical analysis 2.1.1 Floating point numbers2.1.2 Big-O notation; 2.1.3 Relative and absolute error; 2.1.4 Truncation error; 2.1.5 Local and global error; 2.1.6 Stability; 2.1.7 Stable integrators for unstable problems; 2.2 Numerical analysis for ordinary differential equations; 2.2.1 Variable notation and transformation of the order of adifferential equation; 2.2.2 Differences in the simulation of atoms and molecules,as compared to macroscopic particles; 2.2.3 Truncation error for solutions of ordinary differential equations; 2.2.4 Fundamental approaches; 2.2.5 Explicit Euler method 2.2.6 Implicit Euler method2.3 Runge-Kutta methods; 2.3.1 Adaptive step-size control; 2.3.2 Dense output and event location; 2.3.3 Partitioned Runge-Kutta methods; 2.4 Symplectic methods; 2.4.1 The classical Verlet method; 2.4.2 Velocity-Verlet methods; 2.4.3 Higher-order velocity-Verlet methods; 2.4.4 Pseudo-symplectic methods; 2.4.5 Order, accuracy and energy conservation; 2.4.6 Backward error analysis; 2.4.7 Case study: the harmonic oscillator with andwithout viscous damping; 2.5 Stiff problems; 2.5.1 Evaluating computational costs; 2.5.2 Stiff solutions and error as noise 2.5.3 Order reduction
Record Nr.	UNINA-9910132498003321

Autore	Tiwari Rajiv
Edizione	[1st ed. 2023.]
Pubbl/distr/stampa	Singapore : , : Springer Nature Singapore : , : Imprint : Springer, , 2023
Descrizione fisica	1 online resource (602 pages)
Disciplina	620.3
Altri autori (Persone)	Ram MohanY. S DarpeAshish K KumarV. Arun TiwariMayank
Collana	Mechanisms and Machine Science
Soggetto topico	Multibody systems Vibration Mechanics, Applied Machinery Control engineering Robotics Automation Multibody Systems and Mechanical Vibrations Machinery and Machine Elements Control, Robotics, Automation
ISBN	981-9947-21-9
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Identification in a Magnetically Levitated Rigid Rotor System Integrated with Misaligned Sensors and Active Magnetic Bearings -- Thermo-Elastic Bending and Buckling Behavior of Functionally Graded Shafts with Various Grading Patterns -- Modeling and Analysis of Low-Pressure Steam Turbine Blade -- Enhanced energy harvesting application of Piezoceramics (PZT) in MEMS Devices -- Diesel Locomotive Alternator Bearing Damage Detection by Adopting Comprehensive Condition Monitoring Techniques -- Response Analysis of Inclined Edge Cracked Beam Under Moving Mass -- Non-Stationary Response of a Bridge Due to Moving Vehicle with Random Arrival Rate -- Multiclass Fault Diagnosis and Novelty Detection of Induction Motor Using Deep Learning Algorithm Based on Frequency Domain Signal -- Modelling and Analysis of Active Magnetic Bearing Integrated Reaction Wheels for Satellite Applications -- Single Plane Balancing of Rotor-AMB System using Virtual Trial Unbalances -- Comparison of Linear and Non-Linear Feedforward Algorithms to Control Chaotic and Impulsive Noise -- Effect of Thermo-Mechanical Coupling and Large Deformation on the Response of SMA Structures -- Performance Enhancement of Bistable Energy Harvester with Asymmetric Potential Function using an Elastic Magnifier -- Vibration Reduction in Ambulance using Modified Stretcher with Vibration Absorber -- Simulation Studies of Low Velocity Impact Damage in FRPS -- Experimental Identification of Unbalance and Crack Parameters in an Internally Damped Rotor System Integrated with an Active Magnetic Bearing -- Vibration Response Prediction in Rotor Systems with External Damping by Deep Learning using Geometrical Features -- Effect of Bluff Body on the Performance of Flutter Based Energy Harvester -- A Systematic Review of Rotor Unbalance Diagnosis in Rotating Machinery Based on Machine Learning Algorithms -- Tuning of PID Parameters for Misaligned Rotor Bearing System -- Machine Learning based Fault Prediction of Electromechanical System with Current and Vibration Signals -- Identifying Condition Indicators for Artificially Intelligent Fault Classification in Rolling Element Bearings -- Influence of Local Surface Cracks on Dynamic Parameters of Multi-Span Beam -- Crack Detection in A Shaft Using Wavelet Packet Transform -- Design and Modeling of Piezoresistive MEMS Accelerometer for Crash Test Application -- Classification of Orbits of Rotor Supported nn Squeeze Film Damper by Supervised Learning Method -- Free Vibration Response of Three Dimensional Braided Reinforced Composite Conoidal Shell Using Third-Order Shear Deformation Theory -- The Behavior of Iron Nanopowder and Micron-Sized Flake-Shaped Carbonyl Iron Magnetic Fluid Under Creep and Recovery, Oscillatory, and Frequency Sweep Modes -- A Dynamic Model for Polymer Draft Gears -- -- Modelling and Dynamic Analysis of Viscoelastic Tapered Laminated Composite Beam -- Analysis of Limiting Load Capacity and Stiffness Coefficients of Porous-Bump-Recess Foil Journal Bearing -- Limiting Load Capacity and Stiffness Coefficients of Bump Recess Foil Journal Bearing with FGM -- Modal Analysis of Three-Dimensional Braided Composite Reinforced Twisted Spherical Shell Using 3D Finite Element Method -- Dynamic Analysis of Flexible Joint and Single Flexible Link Manipulator by Using Finite Element Analysis -- Prediction of Fatigue Crack Growth Behavior Under Cold-TURBISTAN Spectrum Loads Using Variable Crack Closure Approach in GRM 720 Nickel Base Super Alloy -- Optimization of Active Vibration Absorber by Acceleration Feedback using Fixed Point Theory and Genetic Algorithm -- Study of Time Varying Oil Film Damping and Contact Stiffness of Ball Bearings -- Static and Vibration Response Analysis of PZT-5a/Pt Based Smart Functionally Graded (SFG) Plate Subjected to Electromechanical Loading -- Influence of Squeeze Film Damper on the Rub-Impact Response of a Dual-Rotor Model -- Delamination Damage Detection in a Composite Beam using Discrete Wavelet Transform -- Effect of Input Torque on the Modulation Sidebands of Planetary Gears in a Wind Turbine Gearbox under Gravity Excitations -- Stochastic Identification of Damped Beams using Frequency Response Function Data -- Study of Vibration and Wear Debris Damage Detection Methods for Mild Wear in Spur Gear System -- Transient Rotor Dynamics Behaviour of Shrink Fitted Overhung Rotor -- Fault Diagnosis of Gear with Multiple Defects in Planetary Gearbox -- Vibration Analysis of Turbine Blade using Finite Element Method -- Analytical Prediction of the Jet Force in Pelton Turbine -- Intelligent Fault Detection scheme for Rolling Bearing based on Generative Adversarial Network and Auto-Encoders using Convolutional Neural Network -- Sparse Frequency Representation using Autocorrelation of Variational Mode Functions to Detect Compound Fault in Rotating Machines -- Estimation of Theoretical and Experimental Natural Frequencies of Rotating Shafts -- Steady State Non-Linear Forced Vibrational Response of Laminated Sectorial Plates -- Data Driven Modeling and Control of Delivery Drone -- Fault Diagnosis in a Motor Under Variable Speed Conditions: A Survey -- Stability of Cage in Bearings of Reaction Wheels for Satellite Application: A Critical Review -- Fatigue Life Estimation of Pelton Turbine Using Local Strain Approach -- Rotor Crack Depth Estimation using Recurrence Quantification Analysis -- Identification of Dominant Source of Vibration in Geared Rotors using Full Spectrum Analysis -- Influence of Geometric Parameters on the Dynamic Performance of Spiral Bevel Gear -- Finite Element Modelling and Dynamic Stability Analysis of a Functionally Graded Rotor Shaft-Bearing System -- Moment Independent Sensitivity Analysis of Porous Functionally Graded Plates Subjected to Free Vibrations -- Effect of Misalignment in a Geared Rotor System Integrated with Active Magnetic Bearings -- Coupled Vibration Suppression and Energy Harvesting System from Laminated Composite Structure -- Development of Flexible Rotor Balancing Procedure using Response Matching Technique -- Vibration Control and Energy Harvesting Using Coupled Pendulum Absorbers -- Spindle Bearing Vibration Characteristics of Surface Grinding Machine Tool -- Fault Prediction in Induction Motor using Artificial Neural Network Algorithms -- Novel Method for Selective &Controlled Online Mass Removal using Laser Beam for in-Situ Balancing of Flexible Rotor Bearing System -- Optimum Design of Intershaft Squeeze Film Damper (ISSFD) Ring for Vibration Attenuation -- Friction Analysis of an Unbalanced Disk with Recurrence Plot by Using Simpson -- Integration and Empirical Mode Decomposition -- Improving Wideband Sound Absorption of Single Layer Micro-Perforated Panel -- Absorber: A Finite Element and Experimental Approach -- Influence of Auxetic Structure Parameters on Dynamic Impact Energy Absorption -- Vibration Analysis of Functionally Graded Folded Plate -- Mitigation of Plate Vibrations Using Inerter Based Vibration Absorber -- Updation of Structural Dynamic Response Simulation using Measured Data for a Typical Naval Aircraft Arrested Landing -- Damage due to Stress Wave Propagation in Composite Fan Blades of Aircraft Engine Subjected to Bird Strike Loading -- Vibration and Stability Response of Laminated Composite Panels with Elliptical Cutout under Hygrothermal Conditions.
Record Nr.	UNINA-9910770264003321

Autore	Holm Sverre
Edizione	[1st ed. 2019.]
Pubbl/distr/stampa	Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019
Descrizione fisica	1 online resource (336 pages)
Disciplina	534
Soggetto topico	Sound Multibody systems Vibration Mechanics, Applied Mathematical physics Ultrasonics Acoustical engineering Geophysics Acoustics Multibody Systems and Mechanical Vibrations Mathematical Physics Engineering Acoustics
ISBN	3-030-14927-7
Formato	Materiale a stampa
Livello bibliografico	Monografia
Lingua di pubblicazione	eng
Nota di contenuto	Preface -- Acknowledgements -- About the Author -- List of Symbols -- List of Figures -- List of Tables -- 1 Introduction -- Part I Acoustics and Linear Viscoelasticity -- 2 Classical Wave Equations -- 3 Models of Linear Viscoelasticity -- 4 Absorption Mechanisms and Physical Constraints -- Part II Modeling of Power-Law Media -- 5 Power-Law Wave Equations from Constitutive Equations -- 6 Phenomenological Power-Law Wave Equations -- 7 Justification for Power Laws and Fractional Models -- 8 Power Laws and Porous Media -- 9 Power Laws and Fractal Scattering Media -- Appendix A Mathematical Background -- Appendix B Wave and Heat Equations -- Index.
Record Nr.	UNINA-9910337872303321