Centripetal Acceleration and Circular Motion

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Centripetal Acceleration and Circular Motion
Physics 101 Lecture 08

• Todays lecture will cover Chapter 5

• This weeks quiz Projectile motion
• Hour Exam 1
• Monday, Feb. 18 _at_ 700 pm rooms on web page
• Bring 1. Calculator, 2. ID
• Conflict exam _at_ 515 pm (sign up online)
• Double conflicts email Prof. Alexey Bezryadin
  bezryadi_at_uiuc.edu
• Centripetal motion is not covered on HE1
• Gone on Wed (ugh!) last time I promise!
• My office hours Tuesday 1-2pm, 104 MRL (building
  N of Loomis)
• Review session, Sunday 8 pm, 141 Loomis

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Suggested Practice Problems

• Old hour exams http//online.physics.uiuc.edu/cou
  rses/phys101/fall07/practice/index.html
• (centripetal motion is not on HE1 this semester!)
• Ch 2
• Examples 2.2, 2.5, 2.8, 2.12, 2.13, 2.14
• Problems 1, 5, 7, 11, 13, 17, 29, 49, 69
• Ch 3
• Examples 3.1, 3.2, 3.6, 3.9, 3.11, 3.13
• Problems 5, 13, 33, 47, 57, 65, 67
• Ch 4
• Examples 4.1, 4.6, 4.7, 4.9, 4.12, 4.14
• Problems 1, 3, 5, 9, 17, 19, 23, 25, 27, 35, 41,
  53, 55

• Study suggestions
• Work practice problems (old exams, discussion,
  HW, text)
• Every exam problem unique think in pictures
  dont learn recipes
• Ask Why did work it like that?
• Keep your cool!

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Feedback
Its all good, homes.
I think it is stupendous
The class is understandable...and the demos make
it fun.
You not being here this week is breaking my
heart.
announce what will be covered on the quiz each
week.
the room is too warm, it makes me sleepy
not enough seats!
I think that you go a little too fast during
calculations it is hard to follow along
sometimes. Also, I think it is important to
explain to us where all of the formulas are form
because sometimes while I am working on problems
on my own, I get confused and do not know which
formula to use or how you knew to use it in the
class examples.
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Circular Motion Act
B
A
C
v
Answer B
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?
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5
Acceleration in Uniform Circular Motion
wine glass demo
aave Dv / Dt Acceleration inward
Acceleration is due to change in direction, not
speed. Since turns toward center, acceleration
is toward the center.
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Preflights

• Consider the following situation You are driving
  a car with constant speed around a horizontal
  circular track. On a piece of paper, draw a Free
  Body Diagram (FBD) for the car. How many forces
  are acting on the car? A) 1 B) 2 C) 3
  D) 4 E) 5

1 18 34 28 18
normal force, gravity, friction
force on the car by the engine, frictional
force, force due to gravity, normal force acting
on the car, centripetal force.
wind resistance, friction in bearings, Coriolis
force due to earth motion, gravitational force
due to moos, sun
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Preflights

• Consider the following situation You are driving
  a car with constant speed around a horizontal
  circular track. On a piece of paper, draw a Free
  Body Diagram (FBD) for the car. The net force on
  the car is

A. Zero B. Pointing radially inward C.
Pointing radially outward
10 82 7
Centripetal acceleration is always pointing
INWARD toward the center of the circle you are
moving in
the car is driving with a constant speed (no
acceleration) so net force would equal zero
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ACT

• Suppose you are driving through a valley whose
  bottom has a circular shape. If your mass is m,
  what is the magnitude of the normal force FN
  exerted on you by the car seat as you drive past
  the bottom of the hill
• A. FN lt mg B. FN mg C. FN gt mg

v
SF ma FN - mg mv2/R FN mg mv2/R
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Roller Coaster Example

• What is the minimum speed you must have at the
  top of a 20 meter diameter roller coaster loop,
  to keep the wheels on the track.

Y Direction F ma -N mg m a -N mg -m
v2/R N mg m v2/R Let N 0, just
touching mg m v2/R g v2 / R v
?(gR) v ?(9.8)(10) 9.9 m/s
mg
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Circular Motion

• Angular displacement Dq q2-q1
• How far it has rotated
• Units are radians (or degrees), 2p rad 1 turn
• Angular velocity w Dq/Dt
• How fast it is rotating
• Units radians/second, 2p rad/s 1 turn/s
• Period 1/frequency T 1/f 2p / w
• Time to complete 1 revolution

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Circular to Linear

• Displacement Ds R Dq (q in radians)
• Speed v Ds/Dt R Dq/Dt
• v Rw
• Direction of v is tangent to circle

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Merry-Go-Round ACT

• Bonnie sits on the outer rim of a merry-go-round
  with radius 3 meters, and Klyde sits midway
  between the center and the rim. The
  merry-go-round makes one complete revolution
  every two seconds.
• Klydes speed is

Klyde
Bonnie
(a) the same as Bonnies (b) twice
Bonnies (c) half Bonnies
Bonnie travels 2 p R in 2 seconds vB 2
p R / 2 9.42 m/s Klyde travels 2 p (R/2) in
2 seconds vK 2 p (R/2) / 2 4.71 m/s
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Merry-Go-Round ACT II
BC demo (time?)

• Bonnie sits on the outer rim of a merry-go-round,
  and Klyde sits midway between the center and the
  rim. The merry-go-round makes one complete
  revolution every two seconds.
• Klydes angular velocity w is

Klyde
Bonnie
(a) the same as Bonnies (b) twice
Bonnies (c) half Bonnies

• The angular velocity w of any point on a solid
  object rotating about a fixed axis is the same.
• Both Bonnie Klyde go around once (2p radians)
  every two seconds.

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Angular Acceleration

• Angular acceleration is the change in angular
  velocity w divided by the change in time.
• If the speed of a roller coaster car is 15 m/s at
  the top of a 20 m loop, and 25 m/s at the bottom.
  What is the cars average angular acceleration if
  it takes 1.6 seconds to go from the top to the
  bottom?

0.64 rad/s2
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Constant angular acceleration summary (with
comparison to 1-D kinematics)

• Angular Linear

And for a point at a distance R from the rotation
axis
x R????????????v ?R ??????????a ?R
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CD Player Example

• The CD in your disk player spins at about 20
  radians/second. If it accelerates uniformly from
  rest with angular acceleration of 15 rad/s2, how
  many revolutions does the disk make before it is
  at the proper speed?

Dq 13.3 radians
1 Revolutions 2 p radians
Dq 13.3 radians 2.12 revolutions
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Summary of Concepts

• Uniform Circular Motion
• Speed is constant
• Direction is changing
• Acceleration toward center a v2 / r
• Newtons Second Law F ma
• Circular Motion
• q angular position radians
• w angular velocity radians/second
• a angular acceleration radians/second2
• Linear to Circular conversions s r q
• Uniform Circular Acceleration Kinematics
• Similar to linear!

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