1. Bell Work: Left figure shows strobe photographs taken of a disk moving from left to right under different conditions. The time interval between images is constant. Taking the direction to the right to be positive, describe the motion of the disk in each case. For which case is (a) the acceleration positive? (b) the acceleration negative? (c) the velocity constant?

2. September 24 Monday  Agenda Introducing Free Fall (Section 2.6) Summary  Objectives Differentiate Aristotle and Galileo point of views Describe free fall Apply prior knowledge to solve free fall problems

3. Kinematic Equations  Used in situations with uniform acceleration

4. Galileo Galilei  1564 - 1642  Galileo formulated the laws that govern the motion of objects in free fall  Also looked at: Inclined planes Relative motion Thermometers Pendulum

5. Free Fall  All objects moving under the influence of gravity only are said to be in free fall Free fall does not depend on the object’s original motion  All objects falling near the earth’s surface fall with a constant acceleration  The acceleration is called the acceleration due to gravity, and indicated by g

6. Acceleration due to Gravity  Symbolized by g  g = 9.80 m/s² When estimating, use g 10 m/s 2  g is always directed downward toward the center of the earth  Ignoring air resistance and assuming g doesn’t vary with altitude over short vertical distances, free fall is constantly accelerated motion

7. Free Fall – an object dropped  Initial velocity is zero  Let up be positive  Use the kinematic equations Generally use y instead of x since vertical  Acceleration is g = -9.80 m/s 2 v o = 0 a = g

8. Free Fall – an object thrown downward  a = g = -9.80 m/s 2  Initial velocity  0 With upward being positive, initial velocity will be negative

9. Free Fall -- object thrown upward  Initial velocity is upward, so positive  The instantaneous velocity at the maximum height is zero  a = g = -9.80 m/s 2 everywhere in the motion v = 0

10. Thrown upward, cont.  The motion may be symmetrical Then t up = t down Then v = -v o  The motion may not be symmetrical Break the motion into various parts  Generally up and down

11. Non-symmetrical Free Fall  Need to divide the motion into segments  Possibilities include Upward and downward portions The symmetrical portion back to the release point and then the non- symmetrical portion

12. Combination Motions Phase 1: a = 29.4 m/s 2 Phase 2: a = g = -9.8m/s 2

13. What is your reaction time? Hold your index finger and thumb of your dominant hand about 25c apart, and then have your partner hold a ruler vertically in the space between your finger and thumb. Note the position of the ruler relative to your index finger. Let your partner release the ruler and you try to catch it without moving your hand. Your reaction time can be determined by d = ½ gt 2