Dynamics

Known for its accuracy, clarity, and dependability, Meriam & Kraige's Engineering Mechanics: Dynamics has provided a solid foundation of mechanics principles for more than 60 years. Now in its seventh edition, the text continues to help students develop their problem-solving skills with an extensive variety of engaging problems related to engineering design. More than 50% of the homework problems are new, and there are also a number of new sample problems. To help students build necessary visualization and problem-solving skills, the text strongly emphasizes drawing free-body diagrams-the most important skill needed to solve mechanics problems.

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