Kinematics: What is velocity and acceleration?

1. Kinematics:What is velocity and acceleration?

2. Let’s Review Distance traveled (m) Average Velocity (m/sec) v = d t Time taken (sec) Instantaneous Velocity: the speed at any given moment (like what your speedometer shows)

3. Slope of Position vs Time graph is the Average Velocity • The slope of a line is the ratio of the “rise” (vertical change) to the “run”(horizontal change) of the line.

4. Constant Speed • On a Velocity vs Time graph constant velocity is a straight line

5. Area under the velocity vs time graph is equal to the distance travelled.

6. What is a Motion Diagram? • Motion Diagram: Is a more sophisticated dot diagram that conveys more information about the situation. • What do the arrows indicate? • What does the length of each arrow indicate about the motion of the object?

7. Change in Velocity • What must you do to the first velocity arrow to get the second velocity arrow? What direction? How much? • The arrow you drew to show the difference between the velocity arrows is called a ∆v or change in velocity arrow. • What does the ∆v arrow tell you about the motion of the object?

8. Let’s Try!

9. Lesson 11: Speeding Index

10. Motion of a Falling Object • Using the video of the falling object we have collected the following data: • Draw a motion diagram. • Plot a position time graph. • Does this object represent an object with constant velocity? Explain how you know.

11. What is Acceleration? • Acceleration is a vector quantitythat is defined as the rate at which an object changes its velocity • There are 3 types of acceleration: • If an object is increasing in speed (+ acceleration) • If an object is decreasing in speed (- acceleration, also called deceleration) • Or if the object changes direction (+ or -)

12. Acceleration is the change in speed over the change in time. The slope of the speed versus time graph is the acceleration. How do we calculate Acceleration?

13. How to Solve Motion Problems

14. Rearrange the equation to get final velocity

15. How do we determine the distance travelled by the object if velocity is changing?

17. Equations to Remember

18. x t Motion Graphs v a t t x 0

19. Motion Graphs Starting PointDirectionVelocityAcceleration x v a t t t x 0 0 + Positive + V (speeding up) +constant

20. Acceleration Example #1 V (m/s) a (m/s/s) 0 +5 + 5 + 5 +10 + 5 15 + 5 Δv from +5 to +10 m/s requires a +5 m/s/s acceleration!

21. x Motion Graphs Starting PointDirectionVelocityAcceleration v a t t t x 0 0 Positive (+) +V (slowing down) -constant

22. Acceleration Example #2 V (m/s) a (m/s/s) + 10 - 5 + 5 - 5 0 - 5 Δv from +10 to + 5 m/s requires a - 5 m/s/s acceleration!

23. Motion Graphs Starting PointDirectionVelocityAcceleration x v a t t t x 0 -constant -V (speeding up) above negative (-)

24. Acceleration Example #3 V (m/s) a (m/s/s) 0 -5 - 5 - 5 -10 - 5 -15 - 5 Δv from -5 to -10 m/s requires a -5 m/s/s acceleration! Direction is negative (-), velocity is increasing (+) Therefore acceleration is (-)

25. x t Motion Graphs a Starting PointDirectionVelocityAcceleration v t t x 0 +constant - V (slowing down) above negative (-)

26. Acceleration Example #4 V (m/s) a (m/s/s) - 10 + 5 - 5 + 5 0 + 5 Δv from -10 to -5 m/s requires a +5 m/s/s acceleration! Direction is (-), velocity is slowing down (-) Therefore acceleration is (+)

27. Summary of Velocity & Acceleration

28. Determining signs for velocity and acceleration Increasing speed + direction + Decreasing speed + direction - Increasing speed - direction - + Decreasing speed - direction