Dynamics and statics Books

115 products


  • 15 in stock

    £24.65

  • 15 in stock

    £23.70

  • 15 in stock

    £15.95

  • 15 in stock

    £13.95

  • Creative Media Partners, LLC Satellite Attitude Control Using Atmospheric Drag

    15 in stock

    15 in stock

    £23.70

  • Creative Media Partners, LLC Satellite Attitude Control Using Atmospheric Drag

    15 in stock

    15 in stock

    £13.95

  • 15 in stock

    £22.75

  • 15 in stock

    £22.75

  • 15 in stock

    £22.75

  • 15 in stock

    £14.09

  • Creative Media Partners, LLC Input Shaping to Reduce Solar Array Structural Vibrations

    15 in stock

    15 in stock

    £14.96

  • 15 in stock

    £14.09

  • 15 in stock

    £13.95

  • 15 in stock

    £25.60

  • 15 in stock

    £18.95

  • Creative Media Partners, LLC Stresses Statically Determined

    15 in stock

    15 in stock

    £21.80

  • 15 in stock

    £65.13

  • 15 in stock

    £13.29

  • Brown Walker Press (FL) Thermodynamique: Principes et Applications

    15 in stock

    15 in stock

    £46.97

  • Norton Associates LLC Cam Design and Manufacturing Handbook

    15 in stock

    15 in stock

    £94.56

  • College Publications Basic Vehicle Dynamics and Suspension Design

    15 in stock

    15 in stock

    £22.32

  • Amazon Digital Services LLC - Kdp The Living Theory of Everything Mapping Reality with Daoist Wisdom

    15 in stock

    15 in stock

    £15.06

  • Books on Demand Physik in leicht: Mechanik: Kinematik, Dynamik

    15 in stock

    Book Synopsis

    15 in stock

    £26.50

  • Amazon Digital Services LLC - Kdp Quantum Field Theory

    15 in stock

    15 in stock

    £18.80

  • Independently Published Inertia

    15 in stock

    15 in stock

    £8.37

  • Amazon Digital Services LLC - Kdp The Mechanics of Motion

    15 in stock

    15 in stock

    £14.07

  • Amazon Digital Services LLC - Kdp Misconceptions of Newtonian Physics

    15 in stock

    15 in stock

    £10.11

  • Magnitude

    Black Dog & Leventhal Publishers Inc Magnitude

    5 in stock

    Book SynopsisIn the tradition of illustrated science bestsellers, like Thing Explainer and harkening back to the classic film The Powers of Ten, this unique, fully-illustrated, four-color book explores and visualizes the concept of scale in our universe.

    5 in stock

    £23.75

  • Advances in Computational Dynamics of Particles

    John Wiley & Sons Inc Advances in Computational Dynamics of Particles

    1 in stock

    Book SynopsisThis volume provides a comprehensive treatment of modern computational mechanics work in particle and continuum dynamics. The coverage encompasses classical Newtonian, Lagrangian, and Hamiltonian mechanics, as well as new and alternate contemporary approaches and their equivalences to address various problems in engineering sciences and physics.Table of ContentsPREFACE xv ACKNOWLEDGMENTS xxi ABOUT THE AUTHORS xxiii 1 INTRODUCTION 11.1 Overview 11.2 Applications 13 2 MATHEMATICAL PRELIMINARIES 152.1 Sets and Functions 152.2 Vector Spaces 182.3 Matrix Algebra 242.4 Vector Differential Calculus 282.5 Vector Integral Calculus 322.6 Mean Value Theorem 332.7 Function Spaces 342.8 Tensor Analysis 38 PART I N-BODY DYNAMICAL SYSTEMS 3 CLASSICAL MECHANICS 573.1 Newtonian Mechanics 573.2 Lagrangian Mechanics 603.3 Hamiltonian Mechanics 91 4 PRINCIPLE OF VIRTUAL WORK 1084.1 Virtual Work in N-Body Dynamical Systems 1084.2 Vector Formalism: Newtonian Mechanics in N-Body Dynamical Systems 1144.3 Scalar Formalisms: Lagrangian and Hamiltonian Mechanics in N-Body Dynamical Systems 116 5 HAMILTON’S PRINCIPLE AND HAMILTON’S LAW OF VARYING ACTION 1215.1 Introduction 1215.2 Variation of the Principal Function 1225.3 Calculus of Variations 1255.4 Hamilton’s Principle 1295.5 Hamilton’s Law of Varying Action 133 6 PRINCIPLE OF BALANCE OF MECHANICAL ENERGY 1416.1 Introduction 1426.2 Principle of Balance of Mechanical Energy 1426.3 Total Energy Representations and Framework in the Differential Calculus Setting 1446.4 Appendix: Total Energy Representations and Framework in the Variational Calculus Setting 156 7 EQUIVALENCE OF EQUATIONS 1637.1 Equivalence in the Lagrangian Form of D’Alembert’s Principle/Principle of Virtual Work 1637.2 Equivalence in Hamilton’s Principle or Hamilton’s Law of Varying Action 1657.3 Equivalence in the Principle of Balance of Mechanical Energy 1667.4 Equivalence Relations Between Governing Equations 1677.5 Conservation Laws 1717.6 Noether’s Theorem 171 PART II CONTINUOUS-BODY DYNAMICAL SYSTEMS 8 CONTINUUM MECHANICS 1758.1 Displacements, Strains and Stresses 1758.2 General Principles 1978.3 Constitutive Equations in Elasticity 2068.4 Virtual Work and Variational Principles 2208.5 Direct Variational Methods for Two-Point Boundary-Value Problems 237 9 PRINCIPLE OF VIRTUAL WORK: FINITE ELEMENTS AND SOLID/STRUCTURAL MECHANICS 2679.1 Introduction 2679.2 Finite Element Library 3019.3 Nonlinear Finite Element Formulations 3439.4 Scalar Formalisms: Lagrangian and Hamiltonian Mechanics and Finite Element Formulations in Continuous-Body Dynamical Systems 350 10 HAMILTON'S PRINCIPLE AND HAMILTON'S LAW OF VARYING ACTION: FINITE ELEMENTS AND SOLID/STRUCTURAL MECHANICS 36410.1 Introduction 36410.2 Hamilton’s Principle and Hamilton’s Law of Varying Action in Elastodynamics 36510.3 Lagrangian Mechanics Framework and Finite Element Formulations 37010.4 Hamiltonian Mechanics Framework and Finite Element Formulations 400 11 PRINCIPLE OF BALANCE OF MECHANICAL ENERGY: FINITE ELEMENTS AND SOLID/STRUCTURAL MECHANICS 42611.1 Introduction 42711.2 Total Energy Representations and Framework in the Differential Calculus Setting and Finite Element Formulations 42911.3 Lagrangian Mechanics Framework in the Differential Calculus Setting and Finite Element Formulations 44911.4 Hamiltonian Mechanics Framework in the Differential Calculus Setting and Finite Element Formulations 45411.5 Appendix: Total Energy Representations and Framework in the Variational Calculus Setting and Finite Element Formulations 458 12 EQUIVALENCE OF EQUATIONS 47512.1 Equivalence in the Principle of Virtual Work in Dynamics 47512.2 Equivalence in Hamilton’s Principle or Hamilton’s Law of Varying Action 47812.3 Equivalence in the Principle of Balance of Mechanical Energy 48212.4 Equivalence of Strong and Weak Forms for Initial Boundary-Value Problems 48312.5 Equivalence of the Semi-Discrete Finite Element Equations of Motion 48712.6 Equivalence of Finite Element Formulations 48812.7 Conservation Laws 490 PART III THE TIME DIMENSION 13 TIME DISCRETIZATION OF EQUATIONS OF MOTION: OVERVIEW AND CONVENTIONAL PRACTICES 49513.1 Introduction 49513.2 Single-Step Methods for First-Order Ordinary Differential Equations 50013.3 Linear Multistep Methods 50513.4 Second-Order Systems and Single Step and/or Equivalent LMS Methods: Brief Overview of Classical Methods from Historical Perspectives and Chronological Developments 50713.5 Symplectic-Momentum Conservation and Variational Time Integrators 52713.6 Energy-Momentum Conservation and Time Integration Algorithms 536 14 TIME DISCRETIZATION OF EQUATIONS OF MOTION: RECENT ADVANCES 55314.1 Introduction 55314.2 Time Discretization and the Total Energy Framework: Linear Dynamic Algorithms and Designs - Generalized Single Step Single Solve [GSSSS] Unified Framework Encompassing LMS Methods 55514.3 Time Discretization and the Total Energy Framework: Nonlinear Dynamics Algorithms and Designs - Generalized Single Step Single Solve [GSSSS] Framework Encompassing LMS Methods 57814.4 Time Discretization and Total Energy Framework: N-Body Systems 63214.5 Time Discretization and Total Energy Framework: Nonconservative/Conservative Mechanical Systems with Holonomic-Scleronomic Constraints 64914.5.1 General Formulations 650Exercises 662 REFERENCES 669 INDEX 681

    1 in stock

    £121.60

  • Statistical Mechanics in a Nutshell

    Princeton University Press Statistical Mechanics in a Nutshell

    10 in stock

    Book SynopsisStatistical mechanics is one of the most important areas of physics, and it also has applications to subjects as diverse as economics, social behavior, algorithmic theory, and evolutionary biology. This bokk introduces important developments in classical statistical mechanics, and guides readers to the very threshold of research.Trade Review"Unlike typical textbooks ... [Statistical Mechanics in a Nutshell] presents statistical mechanics as a more general theory with broader applications... A graduate student or researcher who wants to explore the applications of statistical mechanics would be very well served by this book."--Choice "Peliti's Statistical Mechanics in a Nutshell is a fantastic reference for those who know the subject, teach it, or need a quick technical reminder, especially on the topic of phase transitions, which are consistently featured in modern-day discussions... Statistical Mechanics in a Nutshell provides the more general overview, with topics such as the renormalization group method. It includes a good mix of fundamental thermodynamics, phase behaviour, and other key subjects."--Physics TodayTable of ContentsPreface to the English Edition xi Preface xiii Chapter 1: Introduction 1 1.1 The Subject Matter of Statistical Mechanics 1 1.2 Statistical Postulates 3 1.3 An Example: The Ideal Gas 3 1.4 Conclusions 7 Recommended Reading 8 Chapter 2: Thermodynamics 9 2.1 Thermodynamic Systems 9 2.2 Extensive Variables 11 2.3 The Central Problem of Thermodynamics 12 2.4 Entropy 13 2.5 Simple Problems 14 2.6 Heat and Work 18 2.7 The Fundamental Equation 23 2.8 Energy Scheme 24 2.9 Intensive Variables and Thermodynamic Potentials 26 2.10 Free Energy and Maxwell Relations 30 2.11 Gibbs Free Energy and Enthalpy 31 2.12 The Measure of Chemical Potential 33 2.13 The Koenig Born Diagram 35 2.14 Other Thermodynamic Potentials 36 2.15 The Euler and Gibbs-Duhem Equations 37 2.16 Magnetic Systems 39 2.17 Equations of State 40 2.18 Stability 41 2.19 Chemical Reactions 44 2.20 Phase Coexistence 45 2.21 The Clausius-Clapeyron Equation 47 2.22 The Coexistence Curve 48 2.23 Coexistence of Several Phases 49 2.24 The Critical Point 50 2.25 Planar Interfaces 51 Recommended Reading 54 Chapter 3: The Fundamental Postulate 55 3.1 Phase Space 55 3.2 Observables 57 3.3 The Fundamental Postulate: Entropy as Phase-Space Volume 58 3.4 Liouville's Theorem 59 3.5 Quantum States 63 3.6 Systems in Contact 66 3.7 Variational Principle 67 3.8 The Ideal Gas 68 3.9 The Probability Distribution 70 3.10 Maxwell Distribution 71 3.11 The Ising Paramagnet 71 3.12 The Canonical Ensemble 74 3.13 Generalized Ensembles 77 3.14 The p-T Ensemble 80 3.15 The Grand Canonical Ensemble 82 3.16 The Gibbs Formula for the Entropy 84 3.17 Variational Derivation of the Ensembles 86 3.18 Fluctuations of Uncorrelated Particles 87 Recommended Reading 88 Chapter 4: Interaction-Free Systems 89 4.1 Harmonic Oscillators 89 4.2 Photons and Phonons 93 4.3 Boson and Fermion Gases 102 4.4 Einstein Condensation 112 4.5 Adsorption 114 4.6 Internal Degrees of Freedom 116 4.7 Chemical Equilibria in Gases 123 Recommended Reading 124 Chapter 5: Phase Transitions 125 5.1 Liquid-Gas Coexistence and Critical Point 125 5.2 Van der Waals Equation 127 5.3. Other Singularities 129 5.4 Binary Mixtures 130 5.5 Lattice Gas 131 5.6 Symmetry 133 5.7 Symmetry Breaking 134 5.8 The Order Parameter 135 5.9 Peierls Argument 137 5.10 The One-Dimensional Ising Model 140 5.11 Duality 142 5.12 Mean-Field Theory 144 5.13 Variational Principle 147 5.14 Correlation Functions 150 5.15 The Landau Theory 153 5.16 Critical Exponents 156 5.17 The Einstein Theory of Fluctuations 157 5.18 Ginzburg Criterion 160 5.19 Universality and Scaling 161 5.20 Partition Function of the Two-Dimensional Ising Model 165 Recommended Reading 170 Chapter 6: Renormalization Group 173 6.1 Block Transformation 173 6.2 Decimation in the One-Dimensional Ising Model 176 6.3 Two-Dimensional Ising Model 179 6.4 Relevant and Irrelevant Operators 183 6.5 Finite Lattice Method 187 6.6 Renormalization in Fourier Space 189 6.7 Quadratic Anisotropy and Crossover 202 6.8 Critical Crossover 203 6.9 Cubic Anisotrophy 208 6.10 Limit n 209 6.11 Lower and Upper Critical Dimensions 213 Recommended Reading 214 Chapter 7: Classical Fluids 215 7.1 Partition Function for a Classical Fluid 215 7.2 Reduced Densities 219 7.3 Virial Expansion 227 7.4 Perturbation Theory 244 7.5 Liquid Solutions 246 Recommended Reading 249 Chapter 8: Numerical Simulation 251 8.1 Introduction 251 8.2 Molecular Dynamics 253 8.3 Random Sequences 259 8.4 Monte Carlo Method 261 8.5 Umbrella Sampling 272 8.6 Discussion 274 Recommended Reading 275 Chapter 9: Dynamics 277 9.1 Brownian Motion 277 9.2 Fractal Properties of Brownian Trajectories 282 9.3 Smoluchowski Equation 285 9.4 Diffusion Processes and the Fokker-Planck Equation 288 9.5 Correlation Functions 289 9.6 Kubo Formula and Sum Rules 292 9.7 Generalized Brownian Motion 293 9.8 Time Reversal 296 9.9 Response Functions 296 9.10 Fluctuation-Dissipation Theorem 299 9.11 Onsager Reciprocity Relations 301 9.12 Affinities and Fluxes 303 9.13 Variational Principle 306 9.14 An Application 308 Recommended Reading 310 Chapter 10: Complex Systems 311 10.1 Linear Polymers in Solution 312 10.2 Percolation 321 10.3 Disordered Systems 338 Recommended Reading 356 Appendices 357 Appendix A Legendre Transformation 359 A.1 Legendre Transform 359 A.2 Properties of the Legendre Transform 360 A.3 Lagrange Multipliers 361 Appendix B Saddle Point Method 364 B.1 Euler Integrals and the Saddle Point Method 364 B.2 The Euler Gamma Function 366 B.3 Properties of N-Dimensional Space 367 B.4 Integral Representation of the Delta Function 368 Appendix C A Probability Refresher 369 C.1 Events and Probability 369 C.2 Random Variables 369 C.3 Averages and Moments 370 C.4 Conditional Probability: Independence 371 C.5 Generating Function 372 C.6 Central Limit Theorem 372 C.7 Correlations 373 Appendix D Markov Chains 375 D.1 Introduction 375 D.2 Definitions 375 D.3 Spectral Properties 376 D.4 Ergodic Properties 377 D.5 Convergence to Equilibrium 378 Appendix E Fundamental Physical Constants 380 Bibliography 383 Index 389

    10 in stock

    £70.40

  • The Semiclassical Way to Dynamics and

    Princeton University Press The Semiclassical Way to Dynamics and

    4 in stock

    Book SynopsisTrade Review"This thought-provoking and unique presentation of the semiclassical approach to quantum physics is by a grandmaster of the subject. All the explanations are original and the illustrations are beautiful. The subject deserves to be better known to researchers in physics and chemistry."—Michael Berry, University of Bristol"This book captures a lifetime of research, achievement, and deep understanding of the semiclassical approach to quantum mechanics. I know of no volume that covers the same eclectic mix of topics, and Heller's insights are invaluable. A heroic undertaking, this book will be a tremendous boon to many research fields."—Kieron Burke, University of California, Irvine"Among the books on quantum mechanics, this one is unique due to the originality of its content, presentation, and interpretation of the results. Heller succeeds in demonstrating remarkable and surprising connections between classical and quantum mechanics, which allows him to explain seemingly complicated quantum-mechanical phenomena in very simple terms. Filling an important gap in the field, this book will be welcome by specialists and nonspecialists alike."—Jiri Vanicek, École Polytechnique Fédérale de Lausanne

    4 in stock

    £80.75

  • Actionminimizing Methods in Hamiltonian Dynamics

    Princeton University Press Actionminimizing Methods in Hamiltonian Dynamics

    1 in stock

    Book SynopsisJohn Mather's seminal works in Hamiltonian dynamics represent some of the most important contributions to our understanding of the complex balance between stable and unstable motions in classical mechanics. His novel approach--known as Aubry-Mather theory--singles out the existence of special orbits and invariant measures of the system, which posseTable of ContentsPreface vii 1 Tonelli Lagrangians and Hamiltonians on Compact Manifolds 1 1.1 Lagrangian Point of View 1 1.2 Hamiltonian Point of View 4 2 From KAM Theory to Aubry-Mather Theory 8 2.1 Action-Minimizing Properties of Measures and Orbits on KAM Tori 8 3 Action-Minimizing Invariant Measures for Tonelli Lagrangians 18 3.1 Action-Minimizing Measures and Mather Sets 18 3.2 Mather Measures and Rotation Vectors 24 3.3 Mather's a-and B-Functions 28 3.4 The Symplectic Invariance of Mather Sets 35 3.5 An Example: The Simple Pendulum (Part I) 39 3.6 Holonomic Measures and Generic Properties of Tonelli Lagrangians 45 4 Action-Minimizing Curves for Tonelli Lagrangians 48 4.1 Global Action-Minimizing Curves: Aubry and Mane Sets 48 4.2 Some Topological and Symplectic Properties of the Aubry and Mane Sets 66 4.3 An Example: The Simple Pendulum (Part II) 68 4.4 Mather's Approach: Peierls' Barrier 71 5 The Hamilton-Jacobi Equation and Weak KAM Theory 76 5.1 Weak Solutions and Subsolutions of Hamilton-Jacobi and Fathi's Weak KAM theory 76 5.2 Regularity of Critical Subsolutions 85 5.3 Non-Wandering Points of the Mane Set 87 Appendices A On the Existence of Invariant Lagrangian Graphs 89 A.1 Symplectic Geometry of the Phase Space 89 A.2 Existence and Nonexistence of Invariant Lagrangian Graphs 91 B Schwartzman Asymptotic Cycle and Dynamics 97 B.1 Schwartzman Asymptotic Cycle 97 B.2 Dynamical Properties 99 Bibliography 107 Index 113

    1 in stock

    £37.80

  • Whats Next  The Mathematical Legacy of William P.

    Princeton University Press Whats Next The Mathematical Legacy of William P.

    1 in stock

    Book Synopsis

    1 in stock

    £138.55

  • Whats Next  The Mathematical Legacy of William P.

    Princeton University Press Whats Next The Mathematical Legacy of William P.

    7 in stock

    Book Synopsis

    7 in stock

    £70.20

  • Arnold Diffusion for Smooth Systems of Two and a

    Princeton University Press Arnold Diffusion for Smooth Systems of Two and a

    1 in stock

    Book Synopsis

    1 in stock

    £63.75

  • Arnold Diffusion for Smooth Systems of Two and a

    Princeton University Press Arnold Diffusion for Smooth Systems of Two and a

    1 in stock

    Book Synopsis

    1 in stock

    £138.55

  • The Arithmetic of Polynomial Dynamical Pairs

    Princeton University Press The Arithmetic of Polynomial Dynamical Pairs

    1 in stock

    Book Synopsis

    1 in stock

    £131.75

  • The Arithmetic of Polynomial Dynamical Pairs

    Princeton University Press The Arithmetic of Polynomial Dynamical Pairs

    Book Synopsis

    £58.50

  • Dynamics of Particles and Rigid Bodies

    John Wiley & Sons Inc Dynamics of Particles and Rigid Bodies

    1 in stock

    Book SynopsisA unique approach to teaching particle and rigid body dynamics using solved illustrative examples and exercises to encourage self-learning The study of particle and rigid body dynamics is a fundamental part of curricula for students pursuing graduate degrees in areas involving dynamics and control of systems. These include physics, robotics, nonlinear dynamics, aerospace, celestial mechanics and automotive engineering, among others. While the field of particle and rigid body dynamics has not evolved significantly over the past seven decades, neither have approaches to teaching this complex subject. This book fills the void in the academic literature by providing a uniquely stimulating, flipped classroom approach to teaching particle and rigid body dynamics which was developed, tested and refined by the author and his colleagues over the course of many years of instruction at both the graduate and undergraduate levels. Complete with numerous solved illustrTable of ContentsList of Figures xiii Preface xxiii Acknowledgement xxvii Introduction xxix About the Companion Website xliii 1 Kinematics of Particles 1 1.1 Inertial Frames 1 1.2 Rotating Frames 2 1.3 Rotation Matrices 4 1.4 Velocity of a Particle in a Three-dimensional Space 8 1.5 Acceleration of a Particle in a Three-dimensional Space 14 Exercises 21 2 Dynamics of Particles: Vectorial Approach 27 2.1 Newton’s Second Law of Dynamics 27 2.2 Stiffness and Viscous Damping 37 2.3 Dry Friction 40 2.4 Dynamics of a System of Particles 43 2.5 Newton’s Law of Gravitation 47 Exercises 50 Reference 54 3 Dynamics of Rigid Bodies: Vectorial Approach 55 3.1 Center of Mass 55 3.2 Mass Moment of Inertia 57 3.3 Parallel Axis Theorem 61 3.4 Rotation of the Inertia Matrix 65 3.4.1 The Principal Axes 66 3.5 Planar Motion of Rigid Bodies 69 3.5.1 Moment about an Inertial Point 72 3.5.2 Moment about a Moving Point on the Body 73 3.5.3 Moment about the Center of Mass or a Fixed Point on the Body 73 3.6 Non-planar Rigid-body Motion 83 3.6.1 Euler Rotational Equations 85 Exercises 94 Reference 101 4 System Constraints and Virtual Displacement 103 4.1 Constraints 103 4.1.1 Classification of Constraints 104 4.2 Actual and Virtual Displacements 110 4.3 Virtual Work 113 Exercises 115 Reference 116 5 Dynamics of Particles: Analytical Approach 117 5.1 The Brachistochrone Problem 117 5.2 Lagrange’s Equation for a Conservative System 123 5.3 Lagrange’s Equation for Non-conservative Systems 131 5.3.1 Viscous Damping 134 5.4 Lagrange’s Equations with Constraints 141 5.4.1 Physical Interpretation of Lagrange Multipliers 146 5.5 Cyclic Coordinates 151 5.6 Advantages and Disadvantages of the Analytical Approach 154 Exercises 155 References 159 6 Dynamics of Rigid Bodies: Analytical Approach 161 6.1 Kinetic Energy of a Rigid Body 161 6.2 Lagrange’s Equation Applied to Rigid Bodies 166 Exercises 176 7 Momentum 183 7.1 Linear Momentum 183 7.2 Collision 186 7.3 Angular Momentum of Particles 192 7.3.1 Angular Impulse 195 7.4 Angular Momentum of Rigid Bodies (Planar Motion) 199 7.4.1 Angular Momentum about an Axis Passing through the Center of Mass 199 7.4.2 Angular Momentum about an Axis Passing through a Fixed Point on the Body 201 7.4.3 Angular Momentum about an Axis Passing through an Arbitrary Inertial Point 201 7.5 Angular Momentum of Rigid Bodies (Non-planar Motion) 205 7.5.1 Angular Momentum about a Set of Axes Located at the Center of Mass 205 7.5.2 Angular Momentum about a Set of Axes Located at a Fixed Point 206 7.5.3 Angular Momentum about a Set of Axes Located at an Arbitrary Inertial Point 206 7.5.4 Conservation of Angular Momentum for Rigid Bodies 206 7.6 Generalized Momenta 213 Exercises 219 8 Motion of Charged Bodies in an Electric Field 227 8.1 Electrostatics 227 8.1.1 Electrostatic Forces 227 8.1.2 Electric Field 229 8.1.3 Electric Flux 232 8.1.4 Electrostatic Potential Energy 234 8.1.5 Electric Potential (Voltage) 235 8.1.6 Capacitance 237 8.1.7 Motion in an Electric Field 239 8.2 Electromagnetism 247 8.2.1 Electromagnetic Force 247 8.2.2 Forces on a Current-carrying Conductor 253 8.2.3 Electromagnetic Coupling 255 8.2.4 Ampere’s Law 257 8.2.5 Faraday’s Law of Induction 262 8.3 Lagrangian Formulation for Electrical Elements 268 8.3.1 Capacitor 268 8.3.2 Inductor 269 8.3.3 Resistor 269 8.4 Maxwell’s Equations 273 8.4.1 Maxwell’s First Equation 273 8.4.2 Maxwell’s Second Equation 273 8.4.3 Maxwell’s Third Equation 274 8.4.4 Maxwell’s Fourth Equation 274 8.5 Lagrangian Formulation of the Lorentz Force 275 Exercises 279 References 284 9 Introduction to Analysis Tools 285 9.1 Basic Definitions 285 9.2 Equilibrium Solutions of Dynamical Systems 287 9.3 Stability and Classification of Equilibrium Solutions 288 9.4 Phase-plane Representation of the Dynamics 296 9.4.1 Conservative Systems 296 9.4.2 Non-conservative Systems 303 9.5 Bifurcation of Equilibrium Solutions 308 9.5.1 Static Bifurcations 308 9.5.2 Dynamic (Hopf) Bifurcation 315 9.6 Basins of Attraction 323 Exercises 324 References 326 Index 327

    1 in stock

    £81.86

  • Mechanics of the Solid State

    University of Toronto Press Mechanics of the Solid State

    Book SynopsisCollected in this volume are nineteen selected contributions written by twenty-six scholars in the field, in honour of their teacher and colleague, Professor Joseph Marin.Latest developments in the following specific fields are presented: Mathematical Inference from Mechanics, Elasticity, Cosserat Continua, Elastic Waves, Hypervelocity Impact, Composite Materials, Viscoelasticity, Plasticity, Creep, Relaxation, Low Cycle Fatigue, Crack Formation, Fracture, Pressure Vessel and Extrusion Die Design. The volume is a valuable and original contribution to engineering literature and will be of interest not only to engineers, but also to mathematicians and physicists.Dr. Joseph Marin led a life-long campaign for the introduction of the term Mechanics of the Solid State as a worthy companion of Physics of the Solid State. In fulfillment of his wish and in honour of his memory the present volume has been named Mechanics of the Solid State. It provides a list of the 162 papers a

    £25.19

  • Risk and Reliability in Structural Engineering: Theoretical Basis

    Momentum Press Risk and Reliability in Structural Engineering: Theoretical Basis

    Book SynopsisThe primary purpose of this book is to introduce risk and reliability concept into structural design.A structure should be designed taking into account safety, reliability, and economy. Reliability is the probability of successful function, and risk is the potential for unwanted negative consequence of an event. In structural engineering, risk analysis involves the investigation of the probability of rare events. Risk analyses are typically made on the basis of information, which is subject to uncertainty. These uncertainties may be divided into inherent or natural variability. The objective of a structural design is the assurance of successful performance over the useful life of structures or engineering systems.The primary purpose of this book is to introduce risk and reliability concept into structural design. It will cover and review reliability theory and risk analysis to solve structural engineering problems. The book was formed from the easy to the difficult and complicated concepts. Content was written from the basic concepts of uncertainties, structural safety analysis, structural reliability under repeated load, and fatigue reliability. Based on the introduction of failure modes and bounds theory, structural system reliability theory is subsequently discussed. Numerical formulation and examples are provided to enhance the study efficiency of students, engineers, and researchers.This book is suitable for adoption as a textbook or a reference book in a structural reliability analysis course. Furthermore, this book also provides a theoretical foundation for better understanding of the structural safety assessment.

    £38.66

  • Energy Methods in Stress Analysis

    Momentum Press Energy Methods in Stress Analysis

    Book SynopsisThis book builds the subject from a foundation that static equilibrium occurs when the rate of change of work done by the load is equal to the rate of change of strain energy in the structure, Energy methods are a powerful tool for the stress analysis of loaded structures. This book builds the subject from a foundation that static equilibrium occurs when the rate of change of work done by the load is equal to the rate of change of strain energy in the structure. Advanced applications of the method are easily developed from this fundamental principle by partial differentiation of the appropriate terms. The methods solve linear problems, statically indeterminate structures, non-linear problems, frames and the derivation of stiffness matrices used in finite element analysis. Critical buckling loads for struts, plates and panels are modelled by comparison of the strain energy stored in the unbuckled and buckled shapes. This method develops an interesting discussion on the theory of buckling of a long slender strut which is additional to those in traditional texts. Post buckling stiffness of plates and panels are modelled using assumed shapes for strain energy calculation. The presentation offers a clear reasoning leading to analysis possibilities not seen in traditional texts which espouse concepts of virtual work, minimum potential energy, complementary energy, and the unit load method.

    £38.66

  • Mechanical Vibration: Theory and Application

    Rutgers University Press Mechanical Vibration: Theory and Application

    1 in stock

    Book SynopsisThe Fifth edition of this classic textbook includes a solutions manual. Extensive supplemental instructor resources are forthcoming in the Fall of 2022.Mechanical Vibration: Theory and Application presents comprehensive coverage of the fundamental principles of mechanical vibration, including the theory of vibration, as well as discussions and examples of the applications of these principles to practical engineering problems. The book also addresses the effects of uncertainties in vibration analysis and design and develops passive and active methods for the control of vibration. Many example problems with solutions are provided. These examples as well as compelling case studies and stories of real-world applications of mechanical vibration have been carefully chosen and presented to help the reader gain a thorough understanding of the subject. There is a solutions manual for instructors who adopt this book. Request a solutions manual here (https://www.rutgersuniversitypress.org/mechanical-vibration).Trade ReviewThis fifth edition of Mechanical Vibration, a broad and deep exposition not only of vibration, but also of system uncertainties and control, has been expanded and re-written in many parts. The comprehensive coverage includes elementary as well as advanced and professional topics. There are numerous engineering case studies, new appendixes on damping models, and extensive MATLAB resources. The exposition of concepts is careful and precise and yet the presentation is casual, a combination that makes the book remarkably easy and enjoyable to read. -- Fai Ma * Mechanical Engineering, University of California, Berkeley *Mechanical vibration permeates every aspect of engineering design including automotive, aerospace, electronics, machine tools, robotics and structural systems. This text provides a well-integrated, clear and concise discussion of the theory and practice of mechanical vibration as well as the related subjects of random vibration and vibration control. It presents a wide array of real-world examples and meaningful case studies, highlighted by interesting photographs that motivate the subject. There are many solved problems, detailed derivations, and insights that draw on the academic and industrial experiences of the authors. Some of the examples address very classical systems, and others target next generation systems that are currently at the leading edge of technology. The authors are to be congratulated for writing an engaging textbook that makes the challenging and important subject of vibration accessible to engineering students in various disciplines. -- Thomas R. Kurfess * George W. Woodruff School of Mechanical Engineering, Georgia Institute of Technology *For a broad range of engineers involved in structural analysis, this is, in my opinion, a definitely "must have" book. It is perfectly relevant to numerous applications of vibrational analysis in civil, mechanical, aerospace, and biomechanical engineering fields. Although it is written primarily as a textbook, an experienced reader will find it equally useful as a systematic reference of major modern concepts, solutions, and demonstrations cases. The authors have found an optimum balance between “mathematical” and “applied” sides, emphasizing, on one hand, the motivation and modeling of reality, and lessons learned from generated results and, on the other hand, providing rigorous mathematical implementations in a very clear and logical way. The book is extremely well written, and very easy to read, with numerous examples. It also includes an appendix with extensive MATLAB programs for quick implementation into engineering practice. I especially value the chapters on random vibration that demonstrate the importance of probabilistic solutions of structural reliability. It is also a pleasure indeed to read historical anecdotes and life sketches and understand the development of modern mechanics as a process. -- Mark Gurvich * Technical Fellow, Collins Aerospace *Whether tuning a suspension, maximizing tire grip, honing a cylinder bore or determining (just enough) engine isolation, the topic of vibration is critical to vehicle design. This book is impressive, not only in its scope, but also in its approach. The presentation of material is well thought-out, the examples and derivations are quite detailed and easy to follow, while the prose, pictures and bios provide unique context that make the subject matter surprisingly engaging. Aside from making this broad topic approachable to students, this book serves as a concise reference for professionals. The inclusion of an overview of basic (time domain) controls, as well as random vibration, adds additional value and perspective. -- Jim Sadauckas * Staff System Engineer, Vehicle Dynamics & Simulation, Harley-Davidson Motor Company *In the design of vehicles, vibration is a constant issue as it influences complete vehicle properties such as cabin comfort, driving performance, and vehicle dynamics and can lead to fatigue, damage, and failure. Control of vibration is a key factor in successful vehicle design, making this book on modern vibration highly relevant. The book connects theory with practice, includes many worked examples and case studies, and is a resource on vibration that imparts deep physical as well as mathematical understanding to the student or engineer. It is highly recommended. -- Julian Weber * Head of Innovation Projects E-Mobility, BMW *I have heard people say that good writing has a ‘voice.’ Mechanical Vibration by Benaroya, Nagurka, and Han has a voice that tells a rich story about vibration analysis in all its glory – from the beauty of its mathematics through its impact on our daily lives to the history of the people who brought it to life. -- Keith Buffinton * Dean of Engineering, emeritus, Bucknell University *Table of Contents1. INTRODUCTION AND BACKGROUND2. SINGLE DEGREE-OF-FREEDOM UNDAMPED VIBRATION 3. SINGLE DEGREE-OF-FREEDOM DAMPED VIBRATION4. SINGLE DOF VIBRATION: GENERAL LOADING AND ADVANCED TOPICS5. VARIATIONAL PRINCIPLES AND ANALYTICAL DYNAMICS6. MULTI DEGREE-OF-FREEDOM VIBRATION7. CONTINUOUS MODELS FOR VIBRATION 8. CONTINUOUS MODELS FOR VIBRATION: ADVANCED MODELS9. RANDOM VIBRATION: PROBABILISTIC FORCES10. VIBRATION CONTROL 11. NONLINEAR VIBRATIONA: MATHEMATICAL CONCEPTS FOR VIBRATIONB: VISCOELASTIC DAMPINGC: SOLVING VIBRATION PROBLEMS WITH MATLABIndex

    1 in stock

    £107.20

  • Physics of Nonlinear Optics

    Springer Nature Switzerland AG Physics of Nonlinear Optics

    1 in stock

    Book SynopsisThe book is designed to serve as a textbook for courses offered to upper-undergraduate students enrolled in physics. The first edition of this book was published in 2014. As there is a demand for the next edition, it is quite natural to take note of the several advances that have occurred in the subject over the past five years and to decide which of these are appropriate for inclusion at the textbook level, given the fundamental nature and the significance of the subject area. This is the prime motivation for bringing out a revised second edition. Among the newer mechanisms and materials, the book introduces the super-continuum generation, which arises from an excellent interplay of the various mechanisms of optical nonlinearity. The topics covered in this book are quantum mechanics of nonlinear interaction of matter and radiation, formalism and phenomenology of nonlinear wave mixing processes, optical phase conjugation and applications, self-focusing and self-phase modulation and their role in pulse modification, nonlinear absorption mechanisms, and optical limiting applications, photonic switching and bi-stability, and physical mechanisms leading to a nonlinear response in a variety of materials. This book has emerged from an attempt to address the requirement of presenting the subject at the college level. This textbook includes rigorous features such as the elucidation of relevant basic principles of physics; a clear exposition of the ideas involved at an appropriate level; coverage of the physical mechanisms of non-linearity; updates on physical mechanisms and emerging photonic materials and emphasis on the experimental study of nonlinear interactions. The detailed coverage and pedagogical tools make this an ideal textbook for students and researchers enrolled in physics and related courses.Table of Contents1 From Optics to Photonics 1.1 The Charm and Challenge of Modern Optics 1.2 The Nature of Optical Non-linearity 1.3 Overcoming the Materials Bottleneck 1.4 The Expanding Frontiers 1.5 Problems and Prospects 1.6 Explorations 2 A Phenomenological View of Nonlinear Optics 2.1 Optics in the Nonlinear World 2.1.1 Introduction 2.1.2 First Order Susceptibility 2.1.3 Second Order Susceptibility 2.1.4 Third Order Susceptibility 2.2 Time Domain Response 2.2.1 First Order Polarization- Time Domain Response 2.2.2 Second Order Polarization - Time Domain Response 2.3 Frequency Domain Response 2.3.1 First Order Susceptibility 2.3.2 Second Order Susceptibility 2.3.3 General Order (n) Susceptibility 2.4 The nth order polarization 2.5 Monochromatic Waves 2.6 Calculation of the Factor K 2.6.1 Optical Rectification 2.6.2 Second Harmonic Generation 2.6.3 Pockels Effect 2.6.4 Frequency Mixing : Sum and Difference Frequency generation 2.6.5 Third Harmonic Generation 2.6.6 Nondegenerate Four Wave Mixing 2.7 Explorations 3. Symmetry and Susceptibility 3.1 Introduction 3.2 Crystal Symmetry and Susceptibility Tensors 3.2.1 Neumann Principle 3.2.2 Symmetry of Second Order Susceptibility 3.2.3 Second Harmonic Generation 3.2.4 Kleinmann Symmetry 3.2.5 Symmetry of Third Order Susceptibility 3.3 The Dielectric Permittivity Tensor 3.4 The Refractive Index Ellipsoid 3.5 Explorations 4 Calculation of Non-linear Susceptibilities 4.1 Introduction 4.1.1 Physical Quantities in Quantum Physics 4.1.2 The Projection Operator 4.2 The Equation of Motion 4.3 Ensembles of Particles 4.4 Time-dependent Perturbation 4.5 Dipolar Interaction 4.6 First Order Density Matrix 4.7 Second Order Density Matrix 4.8 Third order Density Matrix 4.9 Double Integrals in the Expressions for the Density Matrix 4.10 Second Harmonic Susceptibility 4.11 Relaxation Effects 4.12 Applications to Color Centers 4.12.1 Third Order Susceptibility 4.12.3 Second Order Susceptibility 4.13. Explorations 5 Nonlinear Wave Mixing Processes 5.1 Introduction 5.2 Elements of Electromagnetism 5.3 Travelling Electromagnetic Waves in Free Space 5.3.1 Energy Density in the Travelling Wave 5.4 Propagation of Electromagnetic Waves in Linear Materials 5.5 Propagation of Electromagnetic Waves in Nonlinear Materials 5.5.1 The Wave Equation 5.5.2 Energy Transfer Rate 5.6 Three Wave Mixing 5.6.1 An Approximation 5.7 Second Harmonic Generation 5.7.1 Phase Matching Schemes 5.7.2 Accurate Treatment of Second Harmonic Generation 5.8 Explorations 6 Optical Phase Conjugation and Bi-stability 6.1 Optical Phase Conjugation 6.1.1 Phase Conjugation as Time reversal 6.1.2 Phase Conjugation through Four-wave-mixing 6.1.3 Practical Realization 6.1.4 The Peculiar Properties of the Phase Conjugate Beam 6.1.5 The Grating Picture 6.1.6 Applications of Phase Conjugation 6.2 Optical Bi-stability and Photonic Switching 6.2.1 Refractive Index at High Intensities : An Overview 6.2.2. Fabry-Perot Etalon 6.2.2 Photonic Switching in a Nonlinear Fabry-Perot Etalon 6.3 Explorations 7 Self Focusing, Phase Modulation and Pulse Shaping 7.1 Self Focusing of Light 7.1.1 The Concept of Self Focusing 7.1.2 Self Trapping and Spatial Solitons 7.1.3 The z-Scan Experiment 7.1.4 Analysis of the z-scan trace 7.1.5 Measurement of Nonlinear Optical Absorption 7.1.6 Mechanisms of Nonlinear Absorption 7.2 Self Phase Modulation 7.3 Pulse Shaping and Optical Soliton Propagation 7.3.1 Solitary Waves and Optical Solitons 7.4 Explorations 8 Materials and Mechanisms 8.1 Introduction 8.2 Mechanisms of Non-linearity 8.2.1 Anharmonicity of Potential 8.2.2 Thermal Mechanism 8.2.3 Orientational Mechanism 8.2.4 Inelastic Photon Scattering 8.2.5 Photorefractivity 8.2.6 Saturable Absorption 8.2.7 Band Gap Distortion (Franz-Keldysh Effect) 8.2.8 Band filling Mechanism 8.2.9 Non-parabolicity of Bands 8.2.10 Delocalization of Electrons 8.3 A Perspective on Newer Materials and Mechanisms 8.3.1 Low Dimensional Materials 8.3.2 Photonic Bandgap Materials 8.3.3 Slowing of light and the effect on non-linearity 8.3.4 Super-continuum Generation 8.4 Explorations 9. Basics of Multi-photon Microscopy 9.1 Introduction 9.2. Techniques for Bio-imaging with High resolution 9.2.1 Fluorescence Microscopy 9.2.2 Confocal Scanning Microscopy 9.3. Multi-photon Microscopy with IR Laser Sources 9.3.1 Principles and Experimental Techniques 9.3.2 Fluorescent Labels in Microscopy 9.4 Use of Multiphoton Absorption in Quantum Dots 9.5 Outlook 9.6 Explorations

    1 in stock

    £47.49

  • Taylor & Francis Ltd Metallic GlassBased Nanocomposites Molecular

    15 in stock

    Book SynopsisMetallic Glass-Based Nanocomposites: Molecular Dynamics Study of Properties provides readers with an overview of the most commonly used tools for MD simulation of metallic glass composites and provides all the basic steps necessary for simulating any material on Materials Studio. After reading this book, readers will be able to model their own problems on this tool for predicting the properties of metallic glass composites. This book provides an introduction to metallic glasses with definitions and classifications, provides detailed explanations of various types of composites, reinforcements and matrices, and explores the basic mechanisms of reinforcement-MG interaction during mechanical loading. It explains various models for calculating the thermal conductivity of metallic glass composites and provides examples of molecular dynamics simulations. Aimed at students and researchers, this book caters to the needs of those working in the field of molecuTable of Contents1. Introduction to Metallic Glass. 2. Metallic Glass Nanocomposites. 3. Molecular Modeling of Metallic Glass and Their Nanocomposites. 4. Predicting Thermal Conductivity of Metallic Glasses and Their Nanocomposites. 5. Damping Behavior of Metallic Glass Composites at Nanoscale. 6. MATLAB Programming of Properties of Metallic Glasses and Their Nanocomposites

    15 in stock

    £137.75

  • Taylor & Francis Ltd Road Vehicle Dynamics Fundamentals and Modeling with MATLAB Ground Vehicle Engineering

    15 in stock

    a huge range and FREE tracked UK delivery on ALL orders.

    15 in stock

    £120.00

  • Taylor & Francis Ltd Finite Element Analysis of Solids and Structures

    15 in stock

    a huge range and FREE tracked UK delivery on ALL orders.

    15 in stock

    £104.50

  • Taylor & Francis Ltd Rail Vehicle Mechatronics

    15 in stock

    a huge range and FREE tracked UK delivery on ALL orders.

    15 in stock

    £145.00

© 2026 Book Curl

    • American Express
    • Apple Pay
    • Diners Club
    • Discover
    • Google Pay
    • Maestro
    • Mastercard
    • PayPal
    • Shop Pay
    • Union Pay
    • Visa

    Login

    Forgot your password?

    Don't have an account yet?
    Create account