Chapter 2: Motion in One Dimension EXAMPLES

1. Chapter 2:Motion in One DimensionEXAMPLES

2. Example 2.1Displacement • x1 = 30 m x2 = 10 m • Displacement is a VECTOR

3. Example 2.2 Average Velocity & Speed • Suppose the person walks during 50 seconds. • Displacement Distance (d) = 100m • Average velocity: • Average Speed: Xi Xf

4. Example 2.3 Instantaneous & average velocities • If an objects moves at uniform velocity (constant), then: Instantaneous velocity and average velocity at any instant (t) are the same. Instantaneous = average

5. Example 2.4 Instantaneous & average velocities • Are Instantaneous velocity and Average velocity at any instant t the same? NOT ALWAYS!!!! • Example: A car starts from rest, speed up to 50km/h, remains at that speed for a time. Slow down to 20 km/hr in a traffic jam, the finally stops. Traveling a total of 15 km in 30 min (0.5 hr).

6. Example 2.4, cont

7. 2.4 Acceleration

8. Example 2.5 Average Acceleration • ax (+), vx(+) Speeding Up!! • ax (), vx() Speeding Up!!

9. Example 2.6 Average Acceleration • ax (+), vx() Slowing Down!! • ax (), vx(+) Slowing Down!!

10. Example 2.7 Conceptual Question • Velocity and acceleration are both vectors (they have magnitude & direction). • Are the velocity and the acceleration always in the same direction? NO WAY!!

11. Example 2.8 Conceptual Question • Velocity and acceleration are both vectors (they have magnitude & direction). • Is it possible for an object to have a zero acceleration and a non-zero velocity? YES!!! Drive 65 miles/h on the Freeway

12. Example 2.0 Conceptual Question • Velocity and acceleration are both vectors (they have magnitude & direction). • Is it possible for an object to have a zero velocity and a non-zero acceleration? YES!!! Start your car!!!

13. Material for the Midterm • Examples to Read!!! • Example 2.5 (Text book Page 31) • Example 2.8 (Text book Page 37)

14. 2.6 Constant Acceleration

15. Example 2.10 Free Fall Example • Initial velocity at A is upward (+) and acceleration is g (– 9.8 m/s2) • At B, the velocity is 0 and the acceleration is g (– 9.8 m/s2) • At C, the velocity has the same magnitude as at A, but is in the opposite direction • The displacement is – 50.0 m (it ends up 50.0 m below its starting point)

16. Example 2.10, cont • (1) From (A) → (B) Vyf(B) = vyi(A) + ayt(B)  0 = 20m/s + (–9.8m/s2)t(B) t = t (B) = 20/9.8 s = 2.04 s ymax = y(B) = y(A) +vyi(A)t + ½ayt2 y(B) = 0 + (20m/s)(2.04s) + ½(–9.8m/s2)(2.04s)2 y(B) = 20.4 m

17. Example 2.10, cont • (2)From (B) → (C): y(C) = 0 y(C) = y(A)+ vyi(A) t – ½ayt2 • 0 = 0 + 20.0t – 4.90t2 (Solving for t): t(20 – 4.9t) = 0 • t = 0 or t(C) = t = 4.08 s vyf(C) = vyi(A) + ayt (C) • vyf(C) = 20m/s + (– 9.8m/s2)(4.08 s) • vyf(C) = –20.0 m/s

18. Example 2.10, cont • (3) From (C) → (D) Using position (C) as the reference point the tat (D) position is not 5.00s. It will be: t (D) = 5.00 s – 4.08 s = 0.96 • vyf(D) = vyi(C) + ayt (D) • vyf(D) = -20m/s + (– 9.8m/s2)(0.96 s) vyf(D) = – 29.0 m/s  y(D) = y(C) +vyi(C)t + ½ayt2 • y(D) = 0 – (29.0m/s)(0.96s) – (4.90m/s2)(0.96s)2 = – 22.5 m • y(D) = –22.5 m

19. Example 2.11 (Problem #66 page 54) • From the free fall of the rock the distance will be: • From the sound de same distance will be: • But: t1 + t2 = 2.40s  t1 = 2.40 – t2 • Replacing (t1 ) into the first equation and equating to the second:    .

20. Example 2.12 Objective Question #13 • A student at top of the building of height h throws one ball upward with speed vi and then throws a second ball downward with the same initial speed, vi . How do the final velocities of the balls compare when they reach the ground? After Ball 1 reaches maximum height it falls back downward passing the student with velocity –vi . This velocity is the same as Ball 2 initial velocity, so after they fall through equal height h, their impact speeds will also be the same!!! BALL 2 BALL 1 +vi - vi - vi h h

21. Material for the Midterm • Material from the book to Study!!! • Objective Questions: 2-13-16 • Conceptual Questions: 6-7-9 • Problems: 3-6-11-16-17-20-29-42-44