Engineering Dynamics: A Comprehensive Introduction available in Hardcover, eBook
Engineering Dynamics: A Comprehensive Introduction
- ISBN-10:
- 0691135371
- ISBN-13:
- 9780691135373
- Pub. Date:
- 03/14/2011
- Publisher:
- Princeton University Press
- ISBN-10:
- 0691135371
- ISBN-13:
- 9780691135373
- Pub. Date:
- 03/14/2011
- Publisher:
- Princeton University Press
Engineering Dynamics: A Comprehensive Introduction
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Overview
This textbook introduces undergraduate students to engineering dynamics using an innovative approach that is at once accessible and comprehensive. Combining the strengths of both beginner and advanced dynamics texts, this book has students solving dynamics problems from the very start and gradually guides them from the basics to increasingly more challenging topics without ever sacrificing rigor.
Engineering Dynamics spans the full range of mechanics problems, from one-dimensional particle kinematics to three-dimensional rigid-body dynamics, including an introduction to Lagrange's and Kane's methods. It skillfully blends an easy-to-read, conversational style with careful attention to the physics and mathematics of engineering dynamics, and emphasizes the formal systematic notation students need to solve problems correctly and succeed in more advanced courses. This richly illustrated textbook features numerous real-world examples and problems, incorporating a wide range of difficulty; ample use of MATLAB for solving problems; helpful tutorials; suggestions for further reading; and detailed appendixes.
- Provides an accessible yet rigorous introduction to engineering dynamics
- Uses an explicit vector-based notation to facilitate understanding
Professors: A supplementary Instructor's Manual is available for this book. It is restricted to teachers using the text in courses. For information on how to obtain a copy, refer to: https://press.princeton.edu/class_use/solutions.html
Product Details
| ISBN-13: | 9780691135373 |
|---|---|
| Publisher: | Princeton University Press |
| Publication date: | 03/14/2011 |
| Edition description: | New Edition |
| Pages: | 688 |
| Product dimensions: | 7.20(w) x 10.00(h) x 1.60(d) |
About the Author
Table of Contents
Preface xiChapter 1. Introduction 11.1 What Is Dynamics? 11.2 Organization of the Book 61.3 Key Ideas 81.4 Notes and Further Reading 91.5 Problems 10
Chapter 2. Newtonian Mechanics 112.1 Newton’s Laws 112.2 A Deeper Look at Newton’s Second Law 152.3 Building Models and the Free-Body Diagram 192.4 Constraints and Degrees of Freedom 212.5 A Discussion of Units 242.6 Tutorials 252.7 Key Ideas 372.8 Notes and Further Reading 382.9 Problems 38
PART ONE. PARTICLE DYNAMICS IN THE PLANEChapter 3. Planar Kinematics and Kinetics of a Particle 453.1 The Simple Pendulum 453.2 More on Vectors and Reference Frames 473.3 Velocity and Acceleration in the Inertial Frame 563.4 Inertial Velocity and Acceleration in a Rotating Frame 663.5 The Polar Frame and Fictional Forces 793.6 An Introduction to Relative Motion 833.7 How to Solve a Dynamics Problem 873.8 Derivations—Properties of the Vector Derivative 883.9 Tutorials 933.10 Key Ideas 1003.11 Notes and Further Reading 1013.12 Problems 102
Chapter 4. Linear and Angular Momentum of a Particle 1134.1 Linear Momentum and Linear Impulse 1134.2 Angular Momentum and Angular Impulse 1174.3 Tutorials 1314.4 Key Ideas 1414.5 Notes and Further Reading 1424.6 Problems 143
Chapter 5. Energy of a Particle 1485.1 Work and Power 1485.2 Total Work and Kinetic Energy 1535.3 Work Due to an Impulse 1585.4 Conservative Forces and Potential Energy 1595.5 Total Energy 1695.6 Derivations—Conservative Forces and Potential Energy 1725.7 Tutorials 1735.8 Key Ideas 1795.9 Notes and Further Reading 1805.10 Problems 181
PART TWO. PLANAR MOTION OF A MULTIPARTICLE SYSTEMChapter 6. Linear Momentum of a Multiparticle System 1896.1 Linear Momentum of a System of Particles 1896.2 Impacts and Collisions 2056.3 Mass Flow 2206.4 Tutorials 2286.5 Key Ideas 2356.6 Notes and Further Reading 2376.7 Problems 237
Chapter 7. Angular Momentum and Energy of a Multiparticle System 2457.1 Angular Momentum of a System of Particles 2457.2 Angular Momentum Separation 2527.3 Total Angular Momentum Relative to an Arbitrary Point 2597.4 Work and Energy of a Multiparticle System 2637.5 Tutorials 2747.6 Key Ideas 2857.7 Notes and Further Reading 2877.8 Problems 288
PART THREE. RELATIVE MOTION AND RIGID-BODY DYNAMICS IN TWO DIMENSIONSChapter 8. Relative Motion in a Rotating Frame 2958.1 Rotational Motion of a Planar Rigid Body 2958.2 Relative Motion in a Rotating Frame 3028.3 Planar Kinetics in a Rotating Frame 3118.4 Tutorials 3188.5 Key Ideas 3288.6 Notes and Further Reading 3298.7 Problems 330
Chapter 9. Dynamics of a Planar Rigid Body 3379.1 A Rigid Body Is a Multiparticle System 3379.2 Translation of the Center of Mass—Euler’s First Law 3409.3 Rotation about the Center of Mass— Euler’s Second Law 3439.4 Rotation about an Arbitrary Body Point 3609.5 Work and Energy of a Rigid Body 3689.6 A Collection of Rigid Bodies and Particles 3769.7 Tutorials 3859.8 Key Ideas 3949.9 Notes and Further Reading 3979.10 Problems 398
PART FOUR. DYNAMICS IN THREE DIMENSIONSChapter 10. Particle Kinematics and Kinetics in Three Dimensions 40910.1 Two New Coordinate Systems 40910.2 The Cylindrical and Spherical Reference Frames 41310.3 Linear Momentum, Angular Momentum, and Energy 42210.4 Relative Motion in Three Dimensions 42610.5 Derivations—Euler’s Theorem and the Angular Velocity 44510.6 Tutorials 45010.7 Key Ideas 45810.8 Notes and Further Reading 45910.9 Problems 460
Chapter 11. Multiparticle and Rigid-Body Dynamics in Three Dimensions 46511.1 Euler’s Laws in Three Dimensions 46511.2 Three-Dimensional Rotational Equations of Motion of a Rigid Body 47211.3 The Moment Transport Theorem and the Parallel Axis Theorem in Three Dimensions 49511.4 Dynamics of Multibody Systems in Three Dimensions 50211.5 Rotating the Moment of Inertia Tensor 50411.6 Angular Impulse in Three Dimensions 50911.7 Work and Energy of a Rigid Body in Three Dimensions 51011.8 Tutorials 51511.9 Key Ideas 52311.10 Notes and Further Reading 52611.11 Problems 527
PART FIVE. ADVANCED TOPICSChapter 12. Some Important Examples 53712.1 An Introduction to Vibrations and Linear Systems 53712.2 Linearization and the Linearized Dynamics of an Airplane 55112.3 Impacts of Finite-Sized Particles 56812.4 Key Ideas 57812.5 Notes and Further Reading 579
Chapter 13. An Introduction to Analytical Mechanics 58013.1 Generalized Coordinates 58013.2 Degrees of Freedom and Constraints 58313.3 Lagrange’s Method 58913.4 Kane’s Method 60513.5 Key Ideas 61813.6 Notes and Further Reading 619
APPENDICESAppendix A. A Brief Review of Calculus 623A.1 Continuous Functions 623A.2 Differentiation 624A.3 Integration 626A.4 Higher Derivatives and the Taylor Series 627A.5 Multivariable Functions and the Gradient 629A.6 The Directional Derivative 632A.7 Differential Volumes and Multiple Integration 633Appendix B. Vector Algebra and Useful Identities 635B.1 The Vector 635B.2 Vector Magnitude 637B.3 Vector Components 637B.4 Vector Multiplication 638Appendix C. Differential Equations 645C.1 What Is a Differential Equation? 645C.2 Some Common ODEs and Their Solutions 647C.3 First-Order Form 650C.4 Numerical Integration of an Initial Value Problem 651C.5 Using matlab to Solve ODEs 657Appendix D. Moments of Inertia of Selected Bodies 660Bibliography 663Index 667
What People are Saying About This
"There are few courses in the engineering curriculum that cause students more difficulty than rigid-body dynamics. By laying out the foundations of the subject with precision and clarity through unambiguous notation and rigorous definitions, Engineering Dynamics goes a long way toward remedying this situation. Numerous examples with motivating applications demonstrate the underlying ideas and solution techniques. This landmark text stands apart in the field, and will be welcomed by students and instructors alike."—Dennis S. Bernstein, University of Michigan
"Kasdin and Paley provide a thorough and rigorous introduction to engineering dynamics. They hit all the required topics, and also present material not normally addressed by an introductory text. This is an ambitious book and the authors carry it out well. It is in many ways better than almost all other comparable texts."—Geoffrey Shiflett, University of Southern California