Phys211C3 p1 2 & 3-D Motion Beyond straight line motion vector descriptions

Phys211C3 p2 x y  vyvy vxvx v The instantaneous velocity is in the direction of motion

Phys211C3 p3 Acceleration: changing velocity x y v1v1 v2v2 vv Interactive Physics a_v_plr simulation: how controlling a controls motion.

Phys211C3 p4 Parallel and perpendicular components of acceleration If a is parallel || to v change in velocity is along the direction of velocity effect is solely a change in speed If a is perpendicular  to v change in velocity is perpendicular to the direction of velocity effect is solely a change in direction The parallel component of a results in a change of speed, while the perpendicular component of a results in a change of direction of v. v1v1 v2v2 vv v1v1 v2v2 vv v1v1 v2v2 vv  v || vv

Phys211C3 p5 Motion in the vertical plane: a simple illustration natural choice of coordinate axes horizontal motion: no acceleration vertical motion: acceleration of gravity (downwards) motion is resolved into horizontal and vertical components Dropped ball vs. ball rolled off of a horizontal table Projectile Motion: prototype for 2+D constant acceleration A B + ballistic cart demo: another combination of two motions

Phys211C3 p6 Projectile Motion: Initial Velocity from initial speed and direction:  0 is the initial angle of the velocity wrt the positive x axis

Phys211C3 p7 Other relations for projectile motion:

Phys211C3 p8 Example 3-6: A motorcycle stunt rider rides off the edge of a cliff at a speed of 9 m/s. Determine the rider’s position, distance (both relative to the edge of the cliff) and velocity after.50 s. Example 3-7: A batter hits a baseball so that it leaves the bat with an initial speed of 37.0 m/s at an angle of 53.1°. Find the position and velocity of the ball after 2.00 s. Find the time it takes the ball to reach its maximum height, and the maximum height. Find the horizontal range of the ball (  distance when it hits the ground again)

Phys211C3 p9 Example 3-8: Zoo keeper and the monkey Example 3-9: Range-Height equations  d

Phys211C3 p10 Example 3-10: A water balloon is tossed out a window 8.00 m above the ground at a speed of 10.0 m/s and an angle of 20.0 ° above the horizon. How far from the window does the balloon hit the ground?

Phys211C3 p11 Uniform Circular Motion motion in a circle at constant speed v2v2 v1v1 R  ss vv v2v2 v1v1

Phys211C3 p12 Example 3-11: An automobile is capable of a lateral acceleration of “.87g” which is the maximum centripetal acceleration the car can undergo without skidding. What is the minimum turning radius of the car at speed of 40.0m/s? What is the minimum turning radius of the car at speed of 20.0m/s? Example 3-12: Passengers in a carnival ride travel at a constant speed around a 5.00 m radius circle. They make one circuit every 4.00s. What is their centripetal acceleration?

Phys211C3 p13 Non-Uniform Circular Motion two components of acceleration radial (centripetal) tangential (how fast speed is changing) v a a ra d a tan