1. Rotation: circular motion around an inside axis - example the earth spinning on its own axis.
Revolution: circular motion around an outside axis - example the earth moving around the sun.

2. Circular motion
We have several ways to describe the speed at which an object turns
Tangential speed
Linear speed
Rotational speed
Angular velocity

3. Circular motion
Tangential velocity or VT which describes the speed at which an ant on the outside of the spinning turntable would be traveling at any instant relative to an outside observer. This is also known as linear velocity.
This can also be thought of as the speed the ant would be going if he suddenly flew off of the rotating disk.

4. Circular motion
Rotational velocity or  (the greek lower case letter omega).
This is a measure of how fast an object is moving with relation to its axis of rotation. This motion will be described by how many revolutions the object makes around it axis of rotation. We will measure it in Revolutions per minute or RPMs in this class.

5. Linear speed or velocity = tangential speed or velocity = distance/time and is measured in “meter/second”
The red arrow represents the linear velocity
rotational speed or velocity or
angular speed or velocity, (omega), =
 = number of rotations
time
and is measured in RPM’s or degrees or radians
second second
Measure the time it takes for the blue arrow to go around once, its period,T, and calculate its angular speed in rotations per second.

6. On a spinning turn table which point has the fastest speed?
Well, it really depends!
Which has the greatest vT?
Which has the greatest ?

7. To calculate the linear velocity we could take distance/time
Or the circumference/time
v = 2πr/T
If the diameter of the circle is 4 m and the period is 3 seconds calculate the linear velocity.

8. If something moves in curved path must there be a force on it?
Use this to motivate circular motion involves acceleration.
A ball is going around in a circle attached to a string. If the string breaks at the instant shown, which path will the ball follow? 10

9. Centripetal Force
A center-seeking force that causes an object to follow a circular path.

10. Centripetal force Causes circular motion it is a real force
“center seeking”
Centripetal force

11. What is the direction of the centripetal force?

12. What direction would the acceleration be?

13. G Force, 10 m/s/s or your weight
0 stationary or moving at a constant velocity
0.4 "pedal to the metal" in a typical American car
1.7 "pedal to the metal" in a Formula One race car
2 Extreme Launch™ roller coaster at start
3 space shuttle, maximum at takeoff**; jet fighter landing on aircraft carrier
8 limit of sustained human tolerance
25 R. F. Gray, centrifuge*, 5 s duration,
40 USAF chimpanzee, centrifuge*, 60 s duration,
35 - 40J. P. Stapp, rocket powered impact sled, 1 s duration,
60 chest acceleration limit during car crash at 48 km/h with airbag
70 - 100 crash that killed Diana, Princess of Wales,
83 E. L. Beeding, rocket powered impact sled, 0.04 s duration,
247 USAF chimpanzee, rocket powered impact sled, s duration,

14. “center-fleeing”, away from center
Centrifugal force
“center-fleeing”, away from center
Apparent outward force experienced by a rotating body
Fictitious force – it is not real but do to the effect of inertia

15. What is the direction of the centrifugal force?

17. Centrifugal Force
Rotational direction

18. The whiteboard was being carried along a straight line path; the ball rest on top of the whiteboard and followed the same straight-line path. Then suddenly, the board was turned leftward to begin a circular motion; yet the ball kept moving straight.

21. An accelerometer measures the acceleration
An accelerometer measures the acceleration. When the water in this accelerometer feels a lurch, a fictitious force, due to the effect of inertia

22. When the accelerometer is accelerated uniformly in a straight line it will look like this

23. When the accelerometer is rotated it will look like this

24. Directions Linear velocity Angular acceleration Centripetal Force
Centrifugal Force

25. Formula’s
 = revolutions/time
v = 2πr/T
Fc = mv2/r

26. A linebacker rides on the outside horse of a merry-go-round
A linebacker rides on the outside horse of a merry-go-round. The merry-go-round’s diameter is 10 m it takes 5 seconds to complete 1 rotation. If the linebacker has a mass of 100 kg…
Is he revolving or rotating?
He is revolving…..
The merry-go-round is rotating

27. A linebacker rides on the outside horse of a merry-go-round
A linebacker rides on the outside horse of a merry-go-round. The merry-go-round’s diameter is 10 m it takes 5 seconds to complete 1 rotation. If the linebacker has a mass of 100 kg…
Calculate his linear velocity.

28. A linebacker rides on the outside horse of a merry-go-round
A linebacker rides on the outside horse of a merry-go-round. The merry-go-round’s diameter is 10 m it takes 5 seconds to complete 1 rotation. If the linebacker has a mass of 100 kg…
Calculate his centripetal force .

29. A linebacker rides on the outside horse of a merry-go-round
A linebacker rides on the outside horse of a merry-go-round. The merry-go-round’s diameter is 10 m it takes 5 seconds to complete 1 rotation. If the linebacker has a mass of 100 kg…
Calculate his centrifugal force.
It’s not real, just like…..

30. How does a train stay on the tracks?
Believe it or not it is not the inner rim. The rail often does not touch it

31. The wheels of the train are tapered
The wheels of the train are tapered. A cylinder rolls straight, whereas a cone will roll in a circle.
Why?

32. Which part of the tapered wheel moves with a greater VT
Which part of the tapered wheel moves with a greater VT? The part with the smaller radius A, or the larger radius B?
Since B is moving faster it covers more distance and causes it turn.

33. Let’s see what happens if we roll a cylinder wheel down a Curved track
Will the wheel stay on the track?
If the track starts turning right, underneath the train, (which has plenty of momentum), what will happen?
There will be nothing to make the wheels turn right
It does not correct itself as it slides off the track
It is a train wreck

35. Let’s see what happens if we roll a tapered wheel like the one shown down a track
Will the wheel stay on the track, if the track starts turning left?
The trains momentum tries to carry it straight forward.
It does not correct itself, it wants to go right which is opposite of direction it needs to go!
Faster
Slower

37. What happens if the track turns left
The right wheel will move faster, with the same rotational speed but a larger VT, and the left wheel will move slower, so the train will roll to the left and self corrects. Staying on track.
Faster
Slower
Slower
Faster

38. So if you want Thomas the Train to turn, you let its momentum do the work for you!
If you want the train to turn left, you just make the tracks turn left and the rest happens by itself!! Horray for Thomas the Train!
Slower
Faster

39. Trains are really smart, and very useful. But some are Evil!

40. Artificial Gravity Space Station

42. What would happen if the rotation was faster?
What would happen if you increased the radius of the space station?
To feel 1 g force, if the space station is larger would it have to be spinning as fast?

43. Does an astronaut have to apply a force to an apple keep it moving in a circle?
Would the astronaut feel “weight” from the apple?
What would happen if he lets go of it?
Is there a net force on it when he lets it go?
What direction does the apple go as seen by the astronaut?

44. Inertia - resists acceleration, a property of matter, a kind of laziness of matter - depends on the mass
Rotational Inertia “The moment of inertia” “I”, resists rotational acceleration, depends on the distribution of the mass, that is where the mass is located

45. The further the mass is away from the axis of rotation, fulcrum, the greater the rotational inertia, that is the more lazy it to change its rotational motion.
If these two rods have the same mass and CG but rod A has the mass located in the center and rod B has most of the mass located at the ends.
Which is harder to rotate?
Why?

46. What happens when you put an equivalent force on each roll?
Which one will rotate easier?
Why?

47. Which of these would have the least rotational inertia in their legs?
Which would have the fastest gate?

48. A solid hoop and a hollow cylinder roll down an incline.
Which one will have the greatest rotational inertia?
Why?
Which one will be more sluggish?
Which one will win the race?

49. angular momentum (A.M.) is equal to - rotational velocity or
- angular velocity,
TIMES,
I - rotational inertia or the moment of inertia
A.M. = I

50. conservation of angular momentum
the total angular momentum of a system does NOT change,
unless an outside force
acts on it, therefore,
angular momentum before = angular momentum after Ibefore = Iafter