chapter 5: circular motion; gravitation chapter 8: rotational motion

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Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

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Page 1: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Chapter 5: Circular Motion; Gravitation

Chapter 8: Rotational Motion

Page 2: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

5-1: Kinematics of Circular Motion

• Uniform circular motion: movement in a circle at constant speed1- Is the object accelerating? YES/NO ? WHY?

HINT:

2- Direction of ?HINT: What is the direction of ? (What is the direction of 2 and 1 ?) Remember vectors add tip to tail!

3- = ; proof see text page 107

Page 3: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

5-1: Kinematics of Circular Motion

• Examples: Earth, moon, heart rate, waves breaking on the shore, ….Can you name some more….?

Page 4: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

5-2: Applying N2L to Uniform Circular Motion• Remember Newton’s 2nd Law:

• Let’s apply N2L to an object moving in a circle at constant speed?

• 1-What is the direction of ? • 2-Brainstorm some possible sources of :

Page 5: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

5-6: Newton’s Law of Universal Gravitation

• The above gives only the magnitude of the force of gravity NOT the direction, gravity is always an attractive force that acts along the line joining and

• G=6.67 x 10-11 units??? What are the units of G?

Page 6: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

5-7: Applying N2L to Gravity; g

• Remember Newton’s 2nd Law:

• Let’s apply N2L to two masses • =• Now let’s say is the Earth and is a person standing on the surface of the

Earth: =; cancels; substitute

• ==

Page 7: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion
Page 8: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Polar Plot: (r,θ)

Page 9: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Good news:

We will only be studying rotational motion of CONSTANT radius.

Why do we care?

Imagine you are walking in a circle, riding a bicycle, twisting a wrench, torqueing a screw driver, rolling a ball, or doing a cart wheel. All of these consist of motion in both the x and y– which must be resolved into two—one dimensional problems before they can be analyzed.

However, using polar coordinates—when the radius is held constant—only one variable changes: θ YESSSSS! Much Simpler!

Page 10: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

2𝜋𝑟𝑎𝑑𝑖𝑎𝑛𝑠=360𝑑𝑒𝑔𝑟𝑒𝑒𝑠

Page 11: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Example:

The hockey puck spins 185 times between defending zone and the attacking zone. How many radians? How many degrees?

Page 12: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

For every linear (straight line) physical quantity, there is a rotational analogue:

To review the linear physical quantities to date:

x (distance), v, a, m, F, KE, p,

Page 13: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

ω = angular velocity = (omega)

compare with linear velocity=

α = angular acceleration =

compare with linear acceleration=

Position Velocity Acceleration

Page 14: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Examples: ,

1- A small spider walks an arc length of constant radius around a sun dial from 1 o’clock to 8 o’clock. What is the of the ant? ( in “hours”, in degrees, in radians) The journey takes 2.6 minutes what is the of the spider? (radians/second)

2- Timmy hops on his bicycle and starts pedaling. He completes 4.2 revolutions of the rear tire in the first 3 seconds. What is of the tire? One minute later the rear tire completes 15.6 revolutions in 0.6 seconds. What is of the tire? What is the angular acceleration of the tire?

Page 15: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Remember this equation from middle school:

Circumference of a circle = 2PI *r

…well that was just a special case of the following:

Page 16: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Manipulating l=rθ to connect linear and angular quantities; a little bit of calculus (PRODUCT RULE)

l=r

+

v = r ω

𝑑𝑑𝑡

[ 𝑓 (𝑡 )×𝑔 (𝑡 ) ]= 𝑑 𝑓𝑑𝑡×𝑔 (𝑡 )+ 𝑓 (𝑡)×

𝑑𝑔𝑑𝑡

v = r ωExample: A cyclist with a 24 inch diameter tire glances down at his speedometer and notices his speed is 28 miles/hour . What is the angular velocity of the wheel in radians/second?

Page 17: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

v=r

+

a = r α

Applying the PRODUCT RULE a second time

atangetial = r α

𝑑𝑑𝑡

[ 𝑓 (𝑡 )×𝑔 (𝑡 ) ]= 𝑑 𝑓𝑑𝑡×𝑔 (𝑡 )+ 𝑓 (𝑡)×

𝑑𝑔𝑑𝑡

Example: At the Indianapolis 6000 a x-wing fighter banks a turn around the 4th moon of Xarnex at 18000 m/. The radius of curvature is 200 meters. What is the angular acceleration?

Page 18: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion
Page 19: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

1 Dimensional kinematic equation also in cases of constant angular acceleration with appropriate change in variable

Example: A cyclist with a 24 inch diameter tire glances down at his speedometer and notices his speed is 28 miles/hour . What is the angular velocity of the wheel in radians/second? He comes to a stop in 6 seconds. How many revolutions does his wheel turn during this time?

Page 20: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Torque: the rotational analogue of force

suppose we have a rigid, massive body:

if a force F is applied a distance r away from a fixed axis of rotation,

then the rigid body will experience a torque τwhen a force is directed in a straight line the result is a push or a pull; a linear force;however when that force causes a rotation it is called a torque

It is only when the force is applied perpendicular to the lever arm r, that a torque is generated.

What if the force is at an angle?

Page 21: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Torque Example: Susan is changing her tire and applies a 20 Newton force perpendicular to the end of a wrench that is 20 centimeters long. What is the magnitude of the torque generated?

𝜏= �⃗�× �⃗�=|𝑟||⃗𝐹|sin𝜃

Page 22: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Torque examples everyday life:

Page 23: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Center of Mass (cm) or Center of Gravity: average of the masses factored by their distances from a reference point

If you take out your cell phone and balance it on the tip of your finger why does it balance and not fall over?

Example:

Page 24: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Continuous Mass Distribution

Page 25: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Moment of Inertia: the rotational analogue of mass

When a force is applied to a mass that then moves in a straight line, we consider as if all of the mass were located at the center of mass; the balance point of mass distribution and only consider the total mass.

However, when we consider torques we need to know the position of where the mass is located. It takes more force to rotate a mass around an axis of symmetry when the mass is located 100 meters away then when it is 4 meters away.

Moment of intertia=Example: Determine the moment of inertia of a system of 4 point masses located at coordinates (1,2), (-2,3), (-3,4), and (-5,-7) each of mass 2 kilograms when the axis of rotation is about the z-axis.

Page 26: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Moment of intertia=Continuous mass distributions

Page 27: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Newtons’ 2nd Law:

Example: If each of the three rotor blades is 8cm long and has a mass of 95 gram, calculate the amount of torque that the motor must supply to bring the blades up to a speed of 5 rev/sec in 8.0 seconds.

Page 28: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Linear Kinetic Energy Rotational Kinetic Energy

m

Example: A pitcher throws a fastball with all translational kinetic energy (ZERO spin) at 44 meters/second. If the pitcher throws the same baseball with a curveball pitch with the same total kinetic energy at 33 meters/second determine how many rotations/second the baseball spins at. NOTE: mass_baseball=143 grams; diameter_baseball=75 millimeters;

Page 29: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Angular Momentum

Linear Momentum: p=mv Angular Momentum: L=Iω

What are the units of angular momentum?

Example: Determine the angular momentum of the baseball in the previous example.

Page 30: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Newton’s 2nd Law revisited:

We initially saw N2L like this: however, Issac originally wrote it like: =)=)===SO…use this and our new definition of angular momentum to derive N2L for rotational motion:

=)=)==

𝑑𝑑𝑡

[ 𝑓 (𝑡 )×𝑔 (𝑡 ) ]= 𝑑 𝑓𝑑𝑡×𝑔 (𝑡 )+ 𝑓 (𝑡)×

𝑑𝑔𝑑𝑡

Page 31: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Conservation of angular momentum: L=IExplain:

Page 32: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Translation Rotation Connection

x x=rθ

v v=rω

a a=rα

m I=Σmr2

F Τ=rFsinθ

KE=½mv2 KE=½Iω2

p=mv L=Iω

W=Fd W=τα

ΣF=ma Στ=Iα

ΣF= Στ=

Comparison chart:

Page 33: Chapter 5: Circular Motion; Gravitation Chapter 8: Rotational Motion

Add example problems after each slide where a new concept is introduced that might be unclear

Comparison chart at the end; with linear and rotational values