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Optimal Auxiliary Functions Method for Nonlinear Dynamical Systems

✍ Scribed by Vasile Marinca, Nicolae Herisanu, Bogdan Marinca

Publisher
Springer
Year
2021
Tongue
English
Leaves
476
Edition
1
Category
Library
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✦ Synopsis

This book presents the optimal auxiliary functions method and applies it to various engineering problems and in particular in boundary layer problems. The cornerstone of the presented procedure is the concept of “optimal auxiliary functions” which are needed to obtain accurate results in an efficient way. Unlike other known analytic approaches, this procedure provides us with a simple but rigorous way to control and adjust the convergence of the solutions of nonlinear dynamical systems. The optimal auxiliary functions are depending on some convergence-control parameters whose optimal values are rigorously determined from mathematical point of view. The capital strength of our procedure is its fast convergence, since after only one iteration, we obtain very accurate analytical solutions which are very easy to be verified. Moreover, no simplifying hypothesis or assumptions are made.

The book contains a large amount of practical models from various fields of engineering such as classical and fluid mechanics, thermodynamics, nonlinear oscillations, electrical machines, and many more.

The book is a continuation of our previous books “Nonlinear Dynamical Systems in Engineering. Some Approximate Approaches”, Springer-2011 and “The Optimal Homotopy Asymptotic Method. Engineering Applications”, Springer-2015.

✦ Table of Contents

Preface
Contents
Part I A Short Introduction to the Optimal Auxiliary Functions Method
1 Introduction
References
2 The Optimal Auxiliary Functions Method
References
Part II The Optimal Auxiliary Functions Method in Engineering Applications
3 The First Alternative of the Optimal Auxiliary Functions Method
3.1 Dynamics of an Angular Misaligned Multirotor System
3.1.1 The Governing Equations
3.1.2 Optimal Auxiliary Functions Method for Nonlinear Vibration of Misaligned Multirotor System
3.1.3 Numerical Examples
References
4 Oscillations of a Pendulum Wrapping on Two Cylinders
4.1 Equation of Motion
4.2 Application of OAFM to a Pendulum Wrapping on Two Cylinders
4.3 Numerical Examples
References
5 Free Oscillations of Euler–Bernoulli Beams on Nonlinear Winkler-Pasternak Foundation
5.1 Nonlinear Euler–Bernoulli Beam Model
5.2 OAFM for Free Oscillations of Euler–Bernoulli Beam
5.3 Numerical Example
References
6 Nonlinear Vibrations of Doubly Clamped Nanobeam Incorporating the Casimir Force
6.1 Nonlinear Equation for Nanobeam
6.2 Galerkin Formulation
6.3 Application of OAFM to Eqs. (6.11) and (6.12)
6.4 Numerical Example
References
7 Transversal Oscillations of a Beam with Quintic Nonlinearities
7.1 The Governing Equation
7.2 OAFM for Nonlinear Differential Eq. (7.11)
7.3 Numerical Example
References
8 Approximate Analytical Solutions to Jerk Equations
8.1 OAFM for Jerk Equations
8.2 Numerical Examples
8.2.1 Case 1
8.2.2 Case 2
References
9 Vibration of Nonlinear Nonlocal Elastic Column with Initial Imperfection
9.1 Equation of Motion
9.2 Application of OAFM to Vibration of Nonlinear Nonlocal Elastic Column with Initial Imperfection
9.3 Numerical Example
References
10 Nonlinear Vibration of Bernoulli–Euler Beam on a Winkler Elastic Foundation
10.1 System Description
10.2 Discretization and Free Vibration of the Beam Under Study
10.3 Numerical Example
References
11 The Nonlinear Thermomechanical Vibration of a Functionally Graded Beam (FGB) on Winkler-Pasternak Foundation
11.1 The Governing Equations
11.2 Application of OAFM to Eqs. (11.33) and  (11.36)
11.3 Numerical Examples
References
12 Nonlinear Free Vibration of Microtubes
12.1 Problem Formulation
12.2 Free Vibration of the Microtube
12.3 OAFM for Eqs. (12.16) and  (12.18)
12.4 Numerical Example
References
13 Nonlinear Free Vibration of Elastically Actuated Microtubes
13.1 Problem Formulations
13.2 Free Vibration of the Microtube
13.3 Application of OAFM to Elastically Actuated Microtube
13.4 Numerical Examples
References
14 Analytical Investigation to Duffing Harmonic Oscillator
14.1 OAFM for Duffing Harmonic Oscillator
14.2 Numerical Examples
References
15 Free Vibration of Tapered Beams
15.1 OAFM for Free Vibration of Tapered Beams
15.2 Numerical Examples
References
16 Dynamic Analysis of a Rotating Electrical Machine Rotor-Bearing System
16.1 Application of OAFM to the Investigation of Nonlinear Vibration of the Considered Electrical Machine
16.2 Numerical Example
References
17 Investigation of a Permanent Magnet Synchronous Generator
17.1 Governing Equations of PMSG
17.2 Approximate Solution of Eqs. (17.11) and (17.10)
References
18 Dynamic Response of a Permanent Magnet Synchronous Generator to a Wind Gust
18.1 Approximate Solution of the Dynamic Model of the Wind-Power System
References
19 Axisymmetric Flow and Heat Transfer on a Moving Cylinder
19.1 Equations of Motion
19.2 Optimal Auxiliary Functions Method for Solving the System (3.17.9)–( 3.17.18)
19.3 Numerical Results
References
20 Blasius Problem
20.1 The Governing Equation
20.2 Approximate Solution of the Blasius Problem
20.3 Discussion
References
21 Thin Film Flow of a Fourth Grade Fluid Down a Vertical Cylinder
21.1 Governing Equations of Thin Film Flow of a Fourth Grade Fluid Down a Vertical Cylinder
21.2 Approximate Solution of the Eqs. (21.8) and (21.9)
21.3 Numerical Example for the First Alternative
21.4 Numerical Results by OAFM (The Second Alternative)
References
22 Viscous Flow Due to a Stretching Surface with Partial Slip
22.1 The Governing Equations
22.2 Application of OAFM to Viscous Fluid Given by Eqs. (22.8), (22.10), (22.11) and (22.12)
22.3 Numerical Examples
References
23 Axisymmetric MHD Flow and Heat Transfer to Modified Second Grade Fluid
23.1 The Governing Equations
23.2 OAFM for Solving the System (23.18), (23.19), (23.21), (23.22)
23.3 Numerical Examples
23.3.1 Example 1
23.3.2 Example 2
23.3.3 Example 3
References
24 Thin Film Flow of an Eyring Powel Fluid on a Vertical Moving Belt
24.1 The Governing Equation of Motion
24.2 Numerical Examples
24.2.1 Case 1
24.2.2 Case 2
24.2.3 Case 3
References
25 The Steady Flow of a Fourth Grade Fluid in a Porous Medium
25.1 The Governing Equations
25.2 OAFM for the Steady Flow of a Fourth Grade Fluid in a Porous Medium
25.2.1 Case 1
25.2.2 Case 2
25.2.3 Case 3
25.2.4 Case 4
25.2.5 Case 5
25.2.6 Case 6
25.2.7 Case 7
25.2.8 Case 8
25.2.9 Case 9
25.2.10 Case 10
25.2.11 Case 11
25.2.12 Case 12
25.2.13 Case 13
25.2.14 Case 14
References
26 Thin Film Flow of an Oldroyd Six-Constant Fluid Over a Moving Belt
26.1 Governing Equations
26.2 OAFM for Eqs. (26.15) and  (26.16)
References
27 Cylindrical Liouville-Bratu-Gelfand Problem
27.1 OAFM for Cylindrical Liouville-Bratu-Gelfand Problem
27.1.1 Case A
27.1.2 Case B
27.2 Numerical Examples
27.2.1 Case A
27.2.2 Case B
27.2.3 Case C
References
28 The Polytrophic Spheres of the Nonlinear Lane—Emden—Type Equation Arising in Astrophysics
28.1 The Nonlinear Lane—Emden Equation
28.2 OAFM for the Polytrophic Spheres of the Lane—Emden Equation
28.2.1 Case 1
28.2.2 Case 2
References
Part III Some Variants and Modifications of the Basic Optimal Auxiliary Functions Method
29 The Second Alternative to the Optimal Auxiliary Functions Method
29.1 Dynamic Response of a Permanent Magnet Synchronous Generator to a Wind Gust
29.1.1 Application of an Alternative of OAFM to the Considered Problem (29.16) and (29.17)
29.1.2 Numerical Examples
29.2 Lambert W Function with Application in Electronics and Seismic Waves
29.2.1 Evaluation of the Lambert W Function by OAFM
29.2.2 Application of the Lambert Function in Electronics and Seismic Waves
29.3 Nonlinear Blasius and Sakiadis Flows
29.3.1 Approximate Solutions for the Blasius and Sakiadis Problems Using the Alternative of the OAFM
29.4 Poisson–Boltzman (P.B) Equations
29.4.1 P.B Equation for a Charged Rod in Absence of Added Salt
29.4.2 OAFM for P.B given by Eqs. (29.134) and (29.135)
29.4.3 Numerical Examples
References
30 Piecewise Optimal Auxiliary Functions Method
30.1 The Lane-Emden Equation of the Second Kind
30.1.1 The Nonlinear Lane-Emden Equation of the Second Kind
30.1.2 POAFM for the Lane-Emden Equation of Second Kind
References
31 Some Exact Solutions for Nonlinear Dynamical Systems by Means of the Optimal Auxiliary Functions Method
31.1 Some Exact Solutions for MHD Flow and Heat Transfer to Modified Second Grade Fluid with Variable Thermal Conductivity in the Presence of Thermal Radiation and Heat Generation/Absorption
31.1.1 Some Exact Solutions for Eqs. (31.6)–(31.9) Using OAFM
31.2 Exact Solutions of Nonlinear Dynamical Systems Arising in Fluid Dynamics
31.2.1 Case 1. The Flow of a Fourth Grade Fluid Past a Porous Plate
31.2.2 Case 2. The Flow of a Second Grade Fluid Over a Stretching Sheet with Suction/Injection
31.2.3 Case 3. Thin Film of an Oldroyd 6-Constant Fluid Over a Moving Belt
31.2.4 Case 4. Viscous Flow Due to a Stretching Surface with Partial Slip
31.2.5 Case 5. Thermal Radiation on MHD Flow Over a Stretching Porous Sheet
31.2.6 Case 6. Upper-Convected Maxwell Fluid Over a Porous Stretching Plate
31.2.7 Case 7. Unsteady Viscous Flow Over a Shrinking Cylinder
31.2.8 Case 8. The Flow of a Viscous Incompressible Fluid Over a Porous Stretching Wall
31.3 Exact Solutions to Oscillations of Some Nonlinear Dynamical Systems
31.3.1 Oscillations of a Uniform Cantilever Beam Carrying an Intermediate Lumped Mass and Rotary Inertia
31.3.2 Nonlinear Jerk Equations
31.4 Exact Solutions to Duffing Equation
31.5 Solutions of the Double-Well Duffing Equation
References

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