Foreword Chapter 1 Introduction 1.1 Mechanics 1.2 Fundamental Concepts and Principles 1.2.1 Fundamental Concepts 1.2.2 Newton's Laws of Motion 1.2.3 Newton's Law of Gravitational Attraction 1.3 Units of Measurement 1.4 Procedure of Problem Solving Problems Chapter 2 Vectors and Vector Operations 2.1 Vectors and the Parallelogram Law 2.2 Cartesian Vectors 2.2.1 Cartesian Vector Representation 2.2.2 Addition and Subtraction of Cartesian Vectors 2.3 Vector Directed Along a Line 2.4 Dot Product and Cross Product 2.4.1 Cartesian Vector Formulation of the Dot Product 2.4.2 Applications of the Dot Product 2.4.3 Cartesian Vector Formulation of the Cross Product Problems Chapter 3 Simplification of Force Systems 3.1 Moment of a Force About a Point 3.1.1 Vector Formulation 3.1.2 Principle of Moments 3.1.3 Scalar Formulation 3.2 Moment of a Force About a Specified Axis 3.3 Moment ofaCouple 3.3.1 Vector Formulation 3.3.2 Scalar Formulation 3.4 Simplification of a System of Forces and Couples 3.4.1 Equivalent System 3.4.2 Reduction to One Force and One Couple 3.4.3 Further Simplification 3.5 Application of Simplification of Parallel Forces 3.5.1 Center of Gravity, Center of Mass, and Centroid of a Body 3.5.2 Center of Gravity, Center of Mass, and Centroid of Composite Bodies 3.5.3 Reduction of Distributed Loading Problems Chapter 4 Equifibrium of Rigid Bodies 4.1 Conditions for Rigid-Body Equilibrium 4.2 Free-Body Diagrams 4.2.1 Support Reactions 4.2.2 Procedure of Drawing a Free-Body Diagram 4.3 Equilibrium Problems of a Rigid Body 4.4 Two- and Three-Force Members 4.5 Constrains and Statical Determinacy 4.6 Equilibrium Problems of Structures 4.7 Simple Trusses 4.7.1 The Method of Joints 4.7.2 Zero-Force Members 4.7.3 The Method of Sections Problems Chapter 5 Friction 5.1 Characteristics of Friction 5.1.1 Laws of Sliding Friction 5.1.2 Angles of Friction and Self-Locking 5.2 Problems Involving Sliding Friction 5.3 Rolling Resistance Problems Chapter 6 Kinematics of Particles 6.1 General Curvilinear Motion 6.2 Curvilinear Motion: Rectangular Components 6.3 Curvilinear Motion: Tangential and Normal Components 6.3.1 The t-n-b Coordinate System 6.3.2 Velocity 6.3.3 Acceleration 6.4 Absolute Dependent Motion Analysis of Particles 6.5 Relative-Motion Analysis Using Translating Axes Problems Chapter 7 Planar Kinematics of Rigid Bodies 7.1 Translation 7.2 Rotation about a Fixed Axis 7.2.1 Angular Motion 7.2.2 Motion of a Particle on a Rotating Body 7.3 Absolute Dependent Motion Analysis of Bodies 7.4 General Plane Motion 7.4.1 Relative-Motion Analysis: Velocity and Acceleration 7.4.2 Instantaneous Center of Rotation Problems Chapter 8 Kinetics: Equations of Motion 8.1 Newton's Second Law of Motion 8.2 Equation of Motion for a Particle 8.3 Equation of Motion for a System of Particles 8.4 Mass Moment of Inertia 8.4.1 Parallel-Axis Theorem and Radius of Gyration 8.4.2 Mass Moment of Inertia of Composite Bodies 8.5 Planar Kinetic Equations of Motion 8.5.1 Equations of Motion for Translation 8.5.2 Equations of Motion for Rotation about a Fixed Axis 8.5.3 Equations of Motion for General Plane Motion Problems Chapter 9 Kinetics: Work and Energy 9.1 Work and Power 9.1.1 Work 9.1.2 Power 9.2 Kinetic Energy 9.2.1 Kinetic Energy of a Particle 9.2.2 Kinetic Energy of a System of Particles 9.2.3 Kinetic Energy of a Rigid Body in Planar Motion 9.3 Principle of Work and Energy 9.3.1 Principle of Work and Energy for a Particle 9.3.2 Principle of Work and Energy for a System of Particles 9.4 Con
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