Dynamics in engineering practice

Most undergraduate books for engineering dynamics exhibit a continuing disconnect from either the requirements of subsequent coursework or the practice of dynamics in an engineering career. Dynamics in Engineering Practice, Tenth Edition counters this dated viewpoint with a modern approach that is better suited to today's engineering study and practice. Written by a renowned teacher, researcher, and professional consultant in applied dynamics, this book represents a revolutionary approach to modern engineering dynamics analysis-one you can assimilate quickly and easily to get immediate results. Real-World Guidance to Reconnect Principles and Practice The book begins by establishing the premise that most "dynamics engineers" are developing and analyzing models to predict motion, and that the subject of differential equations is the natural language for dynamics. From this starting point, the author immediately presents mechanical vibration examples to demonstrate applications of f=ma and work-energy principles, and he includes multiple "real-world" 1DOF and MDOF planar dynamics examples, which are completely worked out. Learn Exactly How an Engineer REALLY Solves Engineering Modeling and Analysis Problems Dynamics describes the continuous evolution of motion, yet most textbooks approach the field as a series of ``snapshots,'' posing questions about variables at specific idealized positions or orientations. Advancing the idea that a practicing dynamics engineer's central role is to develop and analyze models, this book: Presents an ordered and logical set of procedures and alternatives for developing models and solutions for any planar dynamic or vibration example Uses repeated examples to demonstrate how models are analyzed via current computer approaches Includes the latest MATLAB (R) updates and other proven methods for modeling and analysis Helps readers ask the right questions to get the most out of problems and optimize modeling of general dynamic systems. Based on the author's more than 40 years of experience teaching and developing courses in dynamics, this book teaches general skills-where effectiveness can be demonstrated for a wide range of problems, rather than a collection of problem-specific "tricks." An essential resource at both the academic and professional levels, this text will be indispensable to both students and working engineers analyzing real dynamic systems.

Introduction and Fundamentals A Short History of Dynamics Units Planar Kinematics of Particles Motion in a Straight Line Particle Motion in a Plane: Cartesian Coordinates Coordinate Transformations: Relationships between Components of a Vector in Two Coordinate Systems Particle Motion in a Plane: Polar Coordinates Particle Motion in a Plane: Normal-Tangential (Path) Coordinates Moving between Cartesian, Polar, and Path-Coordinate Definitions for Velocity and Acceleration Components Time-Derivative Relationships in Two Coordinate Systems Velocity and Acceleration Relationships in Two Cartesian Coordinate Systems Relative Position, Velocity, and Acceleration Vectors between Two Points in the Same Coordinate System Planar Kinetics of Particles Nomenclature Differential Equations of Motion for a Particle Moving in a Straight Line: An Introduction to Physical Modeling More Motion in a Straight Line: Degrees of Freedom and Equations of Kinematic Constraints Motion in a Plane: Equations of Motion and Forces of Constraint Particle Kinetics Examples with More Than One Degree of Freedom Work-Energy Applications for One-Degree-of-Freedom Problems in Plane Motion Linear-Momentum Applications in Plane Motion Moment of Momentum Planar Kinematics of Rigid Bodies Rotation about a Fixed Axis Velocity and Acceleration Relationships for Two Points in a Rigid Body Rolling without Slipping Planar Mechanisms Planar Kinetics of Rigid Bodies Nomenclature Inertia Properties and the Parallel-Axis Formula Governing Force and Moment Equations for a Rigid Body Kinetic Energy for Planar Motion of a Rigid Body Fixed-Axis-Rotation Applications of the Force, Moment, and Energy Equations Compound-Pendulum Applications General Applications of Force, Moment, and Energy Equations for Planar Motion of a Rigid Body Moment of Momentum for Planar Motion Appendices Index