Engineering mechanics. Volume 2. Dynamics J.L. Meriam, L.G. Kraige, Virginia Polytechnic Institute and State University

Description based on: v. 1.

Includes bibliographical references and index.

v. 1. Statics -- v. 2. Dynamics.

Part 1 Dynamics of Particles. <p>Chapter 1: Introduction to Dynamics. <p>1.1 History and Modern Applications. <p>1.2 Basic Concepts. <p>1.3 Newton's Laws. <p>1.4 Units. <p>1.5 Gravitation. <p>1.6 Dimensions. <p>1.7 Solving Problems in Dynamics. <p>1.8 Chapter Review. <p>Chapter 2: Kinematics of Particles. <p>2.1 Introduction. <p>2.2 Rectilinear Motion. <p>2.3 Plane Curvilinear Motion. <p>2.4 Rectangular Coordinates (x-y). <p>2.5 Normal and Tangential Coordinates (n-t). <p>2.6 Polar Coordinates (r-?). <p>2.7 Space Curvilinear Motion. <p>2.8 Relative Motion (Translating Axes). <p>2.9 Constrained Motion of Connected Particles. <p>2.10 Chapter Review. <p>Chapter 3: Kinetics of Particles. <p>3.1 Introduction. <p>Section A: Force, Mass, and Acceleration. <p>3.2 Newton's Second Law. <p>3.3 Equation of Motion and Solution of Problems. <p>3.4 Rectilinear Motion. <p>3.5 Curvilinear Motion. <p>Section B: Work and Energy. <p>3.6 Work and Kinetic Energy. <p>3.7 Potential Energy. <p>Section C: Impulse and Momentum. <p>3.8 Introduction. <p>3.9 Linear Impulse and Linear Momentum. <p>3.10 Angular Impulse and Angular Momentum. <p>Section D: Special Applications. <p>3.11 Introduction. <p>3.12 Impact. <p>3.13 Central-Force Motion. <p>3.14 Relative Motion. <p>3.15 Chapter Review. <p>Chapter 4: Kinetics of Systems of Particles. <p>4.1 Introduction. <p>4.2 Generalized Newton's Second Law. <p>4.3 Work-Energy. <p>4.4 Impulse-Momentum. <p>4.5 Conservation of Energy and Momentum. <p>4.6 Steady Mass Flow. <p>4.7 Variable Mass. <p>4.8 Chapter Review. <p>Part 2 Dynamics of Rigid Bodies. <p>Chapter 5: Plane Kinematics of Rigid Bodies. <p>5.1 Introduction. <p>5.2 Rotation. <p>5.3 Absolute Motion. <p>5.4 Relative Velocity. <p>5.5 Instantaneous Center of Zero Velocity. <p>5.6 Relative Acceleration. <p>5.7 Motion Relative to Rotating Axes. <p>5.8 Chapter Review. <p>Chapter 6: Plane Kinetics of Rigid Bodies. <p>6.1 Introduction. <p>Section A: Force, Mass, and Acceleration. <p>6.2 General Equations of Motion. <p>6.3 Translation. <p>6.4 Fixed-Axis Rotation. <p>6.5 General Plane Motion. <p>Section B: Work and Energy. <p>6.6 Work-Energy Relations. <p>6.7 Acceleration from Work-Energy; Virtual Work. <p>SectionC: Impulse and Momentum. <p>6.8 Impulse-Momentum Equations. <p>6.9 Chapter Review. <p>Chapter 7: Introduction to Three-Dimensional Dynamics ofRigid Bodies. <p>7.1 Introduction. <p>Section A: Kinematics. <p>7.2 Translation. <p>7.3 Fixed-Axis Rotation. <p>7.4 Parallel-Plane Motion. <p>7.5 Rotation about a Fixed Point. <p>7.6 General Motion. <p>Section B: Kinetics. <p>7.7 Angular Momentum. <p>7.8 Kinetic Energy. <p>7.9 Momentum and Energy Equations of Motion. <p>7.10 Parallel-Plane Motion. <p>7.11 Gyroscopic Motion: Steady Precession. <p>7.12 Chapter Review. <p>Chapter 8: Vibration and Time Response. <p>8.1 Introduction. <p>8.2 Free Vibration of Particles. <p>8.3 Forced Vibration of Particles. <p>8.4 Vibration of Rigid Bodies. <p>8.5 Energy Methods. <p>8.6 Chapter Review. <p>Appendix A: Area Moments of Inertia. <p>Appendix B: Mass Moments of Inertia. <p>B.1 Mass Moments of Inertia about an Axis. <p>B.2 Products of Inertia. <p>Appendix C: Selected Topics of Mathematics. <p>C.1 Introduction. <p>C.2 Plane Geometry. <p>C.3 Solid Geometry. <p>C.4 Algebra. <p>C.5 Analytic Geometry. <p>C.6 Trigonometry. <p>C.7 Vector Operations. <p>C.8 Series. <p>C.9 Derivatives. <p>C.10 Integrals. <p>C.11 Newton's Method for Solving Intractable Equations. <p>C.12 Selected Techniques for Numerical Integration. <p>Appendix D: Useful Tables. <p>Table D.1 Physical Properties. <p>Table D.2 Solar System Constants. <p>Table D.3 Properties of Plane Figures. <p>Table D.4 Properties of Homogeneous Solids.