Topics in Modal Analysis & Parameter Identification, Volume 9 [[electronic resource] ] : Proceedings of the 41st IMAC, A Conference and Exposition on Structural Dynamics 2023 / / edited by Brandon J. Dilworth, Timothy Marinone, Michael Mains |
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 |
Dilworth Brandon J
![]() |
||
Cham : , : Springer Nature Switzerland : , : Imprint : Springer, , 2024 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Transfer matrix method for multibody systems : theory and applications / / Xiaoting Rui, Guoping Wang, Jianshu Zhang |
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 |
Rui Xiaoting
![]() |
||
Hoboken, NJ : , : Wiley, , 2019 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Transfer matrix method for multibody systems : theory and applications / / Xiaoting Rui, Guoping Wang, Jianshu Zhang |
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-9910809804003321 |
Rui Xiaoting
![]() |
||
Hoboken, NJ : , : Wiley, , 2019 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Understanding the discrete element method : simulation of non-spherical particles for granular and multi-body systems / / Hans-Georg Matuttis, Jian Chen |
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 |
Matuttis Hans-Georg
![]() |
||
Singapore : , : Wiley, , 2014 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Understanding the discrete element method : simulation of non-spherical particles for granular and multi-body systems / / Hans-Georg Matuttis, Jian Chen |
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-9910821695203321 |
Matuttis Hans-Georg
![]() |
||
Singapore : , : Wiley, , 2014 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Vibration Engineering and Technology of Machinery, Volume I [[electronic resource] ] : Select Proceedings of VETOMAC XVI 2021 / / edited by Rajiv Tiwari, Y. S. Ram Mohan, Ashish K. Darpe, V. Arun Kumar, Mayank Tiwari |
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 |
Tiwari Rajiv
![]() |
||
Singapore : , : Springer Nature Singapore : , : Imprint : Springer, , 2023 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|
Waves with Power-Law Attenuation [[electronic resource] /] / by Sverre Holm |
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 |
Holm Sverre
![]() |
||
Cham : , : Springer International Publishing : , : Imprint : Springer, , 2019 | ||
![]() | ||
Lo trovi qui: Univ. Federico II | ||
|