Department of Physics and Astronomy PHY/EGR 321.001 Spring 2008 Harry D. Downing Professor and Chair Department of Physics and Astronomy

Roll Call Fill out Student Information Sheets Pass out syllabi then go to next slide Take pictures of each student in lab today

Let’s visit the web for course information. Downing’s PHY/EGR 321 Home Page physics.sfasu.edu

Homework Format

Cover Page Staple at 450 NAME PHY/EGR 321.001 Date Problems Grade

Cover Page, Example Pass out some example engineering pad paper Staple at 450 Harry Downing PHY/EGR 321.001 1-16-08 Ch 11 – 2, 6, 9, 16 Grade 5, 4, 5, 3 Pass out some example engineering pad paper

Kinematics of Particles CHAPTER 11 Kinematics of Particles

11.1 INTRODUCTION TO DYNAMICS Galileo and Newton (Galileo’s experiments led to Newton’s laws) Kinematics – study of motion Kinetics – the study of what causes changes in motion Dynamics is composed of kinematics and kinetics

RECTILINEAR MOTION OF PARTICLES

11.2 POSITION, VELOCITY, AND ACCELERATION For linear motion x marks the position of an object. Position units would be m, ft, etc. Average velocity is Velocity units would be in m/s, ft/s, etc. The instantaneous velocity is

The average acceleration is The units of acceleration would be m/s2, ft/s2, etc. The instantaneous acceleration is

Notice If v is a function of x, then One more derivative

Consider the function Plotted x(m) t(s) v(m/s) t(s) a(m/s2) t(s) 16 32 16 32 t(s) 2 4 6 v(m/s) 12 -12 -24 -36 2 4 6 t(s) a(m/s2) 12 -12 -24 2 4 6 t(s)

11.3 DETERMINATION OF THE MOTION OF A PARTICLE Three common classes of motion

with then get

or Both can lead to

Work Some Example Problems

11.4 UNIFORM RECTILINEAR MOTION

11.5 UNIFORMLY ACCELERATED RECTILINEAR MOTION Also

11.6 MOTION OF SEVERAL PARTICLES When independent particles move along the same line, independent equations exist for each. Then one should use the same origin and time.

Relative motion of two particles. The relative position of B with respect to A The relative velocity of B with respect to A

The relative acceleration of B with respect to A

Let’s look at some dependent motions.

xA G xB C D A B E F Let’s look at the relationships. System has one degree of freedom since only one coordinate can be chosen independently.

xC xA xB C A B System has 2 degrees of freedom. Let’s look at the relationships.

Work Some Example Problems

11.7 GRAPHICAL SOLUTIONS OF RECTILINEAR-MOTION Skip this section.

11.8 OTHER GRAPHICAL METHODS Skip this section.

CURVILINEAR MOTION OF PARTICLES 11.9 POSITION VECTOR, VELOCITY, AND ACCELERATION x z y P’ P Let’s find the instantaneous velocity.

x z y x z y P’ P

x z y x z y x z y P’ Note that the acceleration is not necessarily along the direction of the velocity. P

11.10 DERIVATIVES OF VECTOR FUNCTIONS

Rate of Change of a Vector The rate of change of a vector is the same with respect to a fixed frame and with respect to a frame in translation.

11.11 RECTANGULAR COMPONENTS OF VELOCITY AND ACCELERATION

y x z y P x z

x z y

Velocity Components in Projectile Motion

11.12 MOTION RELATIVE TO A FRAME IN TRANSLATION x’ z’ y’ B x z y A O

Work Some Example Problems

11.13 TANGENTIAL AND NORMAL COMPONENTS Velocity is tangent to the path of a particle. Acceleration is not necessarily in the same direction. It is often convenient to express the acceleration in terms of components tangent and normal to the path of the particle.

Plane Motion of a Particle x y P’ P

O x y P’ P

Discuss changing radius of curvature for highway curves

Motion of a Particle in Space x y P’ P z The equations are the same.

11.14 RADIAL AND TRANSVERSE COMPONENTS Plane Motion x y P

x y

Extension to the Motion of a Particle in Space: Cylindrical Coordinates

Work Some Example Problems