CHAPTER 3

1. CHAPTER 3 Two-Dimensional Motion and Vectors

2. (x, y) y x VECTOR quantities: Vectors have magnitude and direction. Representations: (x, y) (r, q) Other vectors: velocity, acceleration, momentum, force …

3. Vector subtraction Vector Addition/Subtraction • 2nd vector begins at end of first vector • Order doesn’t matter Vector addition A – B can be interpreted as A+(-B)

4. Vector Components Cartesian components are projections along the x- and y-axes Going backwards,

5. True or False: a) The magnitude of A-B = 0 b) The x-component of A-B > 0 c) The y-component of A-B > 0 Example 3.1 a) F b) F c) T

6. Carol Bob Alice Example 3.2 Alice and Bob carry a bottle of wine to a picnic site. Alice carries the bottle 5 miles due east, and Bob carries the bottle 10 miles traveling 30 degrees north of east. Carol, who is bringing the glasses, takes a short cut which goes directly to the picnic site. How far did Carol walk? What was Carol’s direction? 14.55 miles, at 20.10 degrees

7. Arcsin, Arccos and Arctan: Watch out! samecosine sametangent same sine Arcsin, Arccos and Arctan functions can yield wrong angles if x or y are negative.

8. v = Dr / Dt It is a vector(rate of change of position) Trajectory 2-dim Motion: Velocity Graphically,

9. Vector multiplied/divided by scalar is a vector Magnitude of new vector is magnitudeo the orginial vector multiplied/divided by the |scalar| Direction of new vector is the same or opposite to original vector Multiplying/Dividing Vectors by Scalars, e.g. Dr / Dt

10. Principles of 2-d Motion • X- and Y-motion are independent • Can be treated as two separate 1-d problems • To get trajectory (x vs. y) • Solve for x(t) and y(t) • Invert one Eq. to get t(x) • Insert t(x) into y(t) to get y(x)

11. X-motion is at constant velocity ax=0, vx=constant Y-motion is at constant accelerationay=-g Projectile Motion Note: we have ignored • air resistance • rotation of earth (Coriolis force)

12. Projectile Motion Acceleration is constant

13. Pop and Drop Demo

14. The Ballistic Cart Demo

15. 1. Write down x(t) 2. Write down y(t) 3. Invert x(t) to find t(x) 4. Insert t(x) into y(t) to get y(x) Trajectory is parabolic Finding Trajectory, y(x)

16. Example 3.3 v0 An airplane drops food to two starving hunters. The plane is flying at an altitude of 100 m and with a velocity of 40.0 m/s. How far ahead of the hunters should the plane release the food? h X 181 m

17. v0 h q D Example 3.4 • The Y-component of v at A is (<0, 0, >0) • The Y-component of v at B is (<0, 0, >0) • The Y-component of v at C is (<0, 0, >0) • The total velocity is greatest at (A,B,C) • The X-component of v is greatest at (A,B,C) 1.>02. 03. <04. A5. Equal at all points

18. Range Formula • Good for when yf = yi

19. Range Formula • Maximum for q=45

20. Example 3.5a A softball leaves a bat with an initial velocity of 31.33 m/s. What is the maximum distance one could expect the ball to travel? 100 m

21. v0 h q D Example 3.5b A cannon aims a projectile at a target located on a cliff 500 m away in the horizontal direction and 75 meters above the cannon. The cannon is pointed 50 degrees to the horizontal. What muzzle velocity should the cannon employ to hit the target? 75.4 m/s

22. Example 3.7, Shoot the Monkey A hunter is a distance L = 40 m from a tree in which a monkey is perched a height h=20 m above the hunter. The hunter shoots an arrow at the monkey. However, this is a smart monkey who lets go of the branch the instant he sees the hunter release the arrow. The initial velocity of the arrow is v = 50 m/s. A. If the arrow traveled with infinite speed on a straight line trajectory, at what angle should the hunter aim the arrow relative to the ground? q=Arctan(h/L)=25.6 B. Considering the effects of gravity, at what angle should the hunter aim the arrow relative to the ground?

23. 1. Write height of arrow when x=L 2. Require y to be position of monkey at t=L/vx 3. Require monkey and arrow to be at same place Aim directly at Monkey! Must find v0,y/vx in terms of h and L Solution:

24. Shoot the Monkey Demo

25. Relative velocity • Velocity always defined relative to reference frame.All velocities are relative • Relative velocities are calculated by vector addition/subtraction. • Acceleration is independent of reference frame • For high, v ~c, rules are more complicated (Einstein)

26. Example 3.8 A plane that is capable of traveling 200 m.p.h. flies 100 miles into a 50 m.p.h. wind, then flies back with a 50 m.p.h. tail wind. How long does the trip take? What is the average speed of the plane for thetrip? 1.067 hours = 1 hr. and 4 minutes 187.4 mph

27. river wrt earth Boat wrt earth boat wrt river Relative velocity in 2-d • Sum velocities as vectors • velocity relative to ground= velocity relative to medium + velocity of medium. vbe = vbr + vre

28. 2 Cases pointed perpendicularto stream travels perpendicularto stream

29. Example 3.9 An airplane capable of moving 200 mph in still air. The plane points directly east, but a 50 mph wind from the north distorts his course. What is the resulting ground speed? What direction does the plane fly relative to the ground? 206.2 mph 14.0 deg. south of east

30. Example 3.10 An airplane capable of moving 200 mph in still air. A wind blows directly from the North at 50 mph. If the airplane accounts for the wind (by pointing the plane somewhat into the wind) and flies directly east relative to the ground. What is his resulting ground speed? In what direction is the nose of the plane pointed? 193.6 mph 14.5 deg. north of east