Rotational Motion Angles, Angular Velocity and Angular ...€¦ · Rotational Motion. Angles,...

52
Chapter 7 Chapter 7 Rotational Motion Angles, Angular Velocity and Angular Acceleration Universal Law of Gravitation Kepler’s Laws

Transcript of Rotational Motion Angles, Angular Velocity and Angular ...€¦ · Rotational Motion. Angles,...

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Chapter 7Chapter 7

Rotational MotionAngles, Angular Velocity and

Angular AccelerationUniversal Law of Gravitation

Kepler’s Laws

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Angular DisplacementAngular Displacement

Circular motion about AXISThree different measures of angles:

1. Degrees2. Revolutions (1 rev. = 360 deg.)3. Radians (2π rad.s = 360 deg.)

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Angular Displacement, cont.Angular Displacement, cont.

Change indistance of a point:

radians)in is (

s)revolution counts (N2θθ

πr

Nrs==

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ExampleExampleAn automobile wheel has a radius of 42 cm. If a car drives 10 km, through what angle has the wheel rotated?

a) In revolutions

b) In radians

c) In degrees

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SolutionSolutionNote distance car moves = distance outside of wheel moves

a) Find N:Known: s = 10 000 m, r = 0.42 m

b) Find θ in radiansKnown: N

c) Find θ in degreesKnown: N

θπrrNs

== 2

formula Basic

= 3 789

θ = 2.38 x 104 rad.Nevolution)(radians/r2πθ =

Nevolution)(degrees/r360=θ

rsNπ2

=

θ = 1.36 x 106 deg

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Angular SpeedAngular Speed Can be given in Revolutions/sRadians/s --> Called ωDegrees/s

Linear Speed at r

radiansint

if θθω

−=

rt

θθrt

θθrt

θθrv

if

if

if

ωπ

π

π

π

=−

⋅=

−⋅=

−⋅=

radians)(in 2

2

degrees)(in 3602

s)revolution(in 2

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ExampleExampleA race car engine can turn at a maximum rate of 12 000 rpm. (revolutions per minute).

a) What is the angular velocity in radians per second.

b) If helipcopter blades were attached to the crankshaft while it turns with this angular velocity, what is the maximum radius of a blade such that the speed of the blade tips stays below the speed of sound. DATA: The speed of sound is 343 m/s

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SolutionSolutiona) Convert rpm to radians per second

revrad2

minsec60

minrev.00012

π = 1256 radians/s

b) Known: v = 343 m/s, ω = 1256 rad./sFind r

ωvr =rv ω=

formula Basic= .27 m

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Angular AccelerationAngular Acceleration

Denoted by α

ω must be in radians per sec.Units of angular acceleration are rad/s²Every portion of the object has same angular speed and same angular acceleration

αt

if ωω −=

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Analogies Between Linear and Analogies Between Linear and Rotational MotionRotational Motion

ti α+ω=ω

2

21 tti αωθ +=∆

( )tfi

2ωω

θ+

=∆

θ∆α+ω=ω 22i

2 xa2vv 2i

2 ∆+=

2i at

21tvx +=∆

( )t

vvx fi

2+

=∆

Linear MotionRotational Motion

atvv i +=

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Linear movement of a rotating pointLinear movement of a rotating pointDistance

Speed

Acceleration

Different points on the same object have different linear motions!

rs θ=

rv ω=

ra α=

Only works when θ, ω and α are in radians!

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ExampleExampleA pottery wheel is accelerated uniformly from rest to a rate of 10 rpm in 30 seconds. a.) What was the angular acceleration? (in rad/s2)

b.)How many revolutions did the wheel undergo during that time?

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SolutionSolutionFirst, find the final angular velocity in radians/s.

( )

=

⋅⋅

=

secrad047.1

revrad2

minsec/601

minrev.10 πω f

a) Find angular acceleration

tif ωω

α−

=tif αωω +=formula Basic = 0.0349 rad./s2

= 2.5 rev.

b) Find number of revolutions: Known ωi=0, ωf =1.047, and t = 30First find ∆θ in radians

rad.7.152

==∆ tfω

θ

tfi

2

formula Basic

ωωθ

+=∆

)rad./rev.(2)rad.(

πθ∆

=N

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SolutionSolution

= 2.5 rev.

b) Find number of revolutions: Known ωi=0, ωf =1.047, and t = 30,

First find ∆θ in radians

rad.7.152

==∆ tfω

θtfi

2

formula Basic

ωωθ

+=∆

)rad./rev.(2)rad.(

πθ∆

=N

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ExampleExampleA coin of radius 1.5 cm is initially rolling with a rotational speed of 3.0 radians per second, and comes to a rest after experiencing a slowing down of α = 0.05 rad/s2.

a.) Over what angle (in radians) did the coin rotate?

b.) What linear distance did the coin move?

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SolutionSolutiona) Find ∆θ, Given ωi= 3.0 rad/s, ωf = 0, α = -0.05 rad/s2

θαωω ∆+= 222formula Basic

if αωθ2

2

−=∆ i

= 90 radians = 90/2π revolutions

b) Find s, the distance the coin rolledGiven: r = 1.5 cm and ∆θ = 90 rad

θ∆= rsformula Basic

rad.s)in is (, θθ ∆∆= rs = 135 cm

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Centripetal AccelerationCentripetal Acceleration

Moving in circle at constant SPEED does not mean constant VELOCITYCentripetal acceleration results from CHANGING DIRECTION of the velocity

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Centripetal Acceleration, cont.Centripetal Acceleration, cont.

Acceleration is directed toward the center of the circle of motion

tva

formula Basic rr ∆

=

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Derivation: a = Derivation: a = ωω22r = vr = v22/r/rFrom the geometry of the Figure

θθθ

∆∆=∆=∆

smallfor )2/sin(2

vvv

From the definition of angular velocity

rvrv

tva

tvvt

22 ===

∆=

=∆=∆

ωω

ωωθ

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Forces Causing Centripetal Forces Causing Centripetal AccelerationAcceleration

Newton’s Second Law

Radial acceleration requires radial forceExamples of forces

Spinning ball on a stringGravityElectric forces, e.g. atoms

amF rr=

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ExampleExampleA space-station is constructed like a barbell with two 1000-kg compartments separated by 50 meters that spin in a circle (r=25 m). The compartments spins once every 10 seconds.

a) What is the acceleration at the extreme end of the compartment? Give answer in terms of “g”s.

b) If the two compartments are held together by a cable, what is the tension in the cable?

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SolutionSolutiona) Find acceleration a

Given: T = 10 s, r = 25 m

=

srevN

revradπω 2

formula Basic First, find ω in rad/s

1.02 ⋅= πω

rrva 2

2formula Basic

ω==Then, find acceleration

ra 2ω= = 9.87 m/s2 = 1.006 g

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SolutionSolutionb) Find the tension

Given m = 1000 kg, a = 1.006 g

maF =formula Basic

= 9870 NmaT =

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ExampleExampleA race car speeds around a circular track.

a) If the coefficient of friction with the tires is 1.1, what is the maximum centripetal acceleration (in “g”s) that the race car can experience?

b) What is the minimum circumference of the track that would permit the race car to travel at 300 km/hr?

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SolutionSolution

gamgmamgf

µµµ

===

a) Find the maximum centripetal accelerationKnown: µ = 1.1Remember, only consider forces towards center

maFnf

== µ

formula Basic

Maximum a = 1.1 g

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SolutionSolutionb) Find the minumum circumference

Known: v = 300 km/hr = 83.33 m/s, a = 1.1 gFirst, find radius

rrva 2

2formula Basic

ω==avr

2

=

Then, find circumference

= 4 043 mrL π2=

In the real world: tracks are banked

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ExampleExampleA A yo-yo is spun in a circle as shown.

If the length of the string is L = 35 cm and the circular path is repeated 1.5 times per second, at what angle θ (with respect to the vertical) does the string bend?

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SolutionSolution

amF rr=

formula Basic Apply F=ma for both the horizontal and

vertical components.

TLmTF

Lmrmmax

x

==

==∑

2

22

sinsin

ωθ

θωω

mgTmgTF

may

y

=−=

=∑

θθ

coscos

0

ra 2formula Basic

ω=

r = Lsinθ

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SolutionSolutionWe want to find θ, given ω=2π·1.5 & L=0.35

TLmTF

Lmrmmax

x

==

==∑

2

22

sinsin

ωθ

θωω

mgTmgTF

may

y

=−=

=∑

θθ

coscos

0

2 eq.s & 2 unknowns (T and θ)

Lg

Tmg

2cosω

θ == θ = 71 degrees

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Accelerating Reference FramesAccelerating Reference FramesConsider a frame that is accelerating with af

)( ff aammaFmaF

−=−=

Fictitious forceLooks like “gravitational” force

If frame acceleration = g, fictitious force cancels real gravity.

Examples: Falling elevator, planetary orbitrotating space stations

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DEMO: FLYING POKER CHIPSDEMO: FLYING POKER CHIPS

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ExampleExample

Which of these astronauts experiences “zero gravity”?

a) An astronaut billions of light years from any planet.b) An astronaut falling freely in a broken elevator.c) An astronaut orbiting the Earth in a low orbit.d) An astronaut far from any significant stellar object in a

rapidly rotating space station

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Newton’s Law of Universal Newton’s Law of Universal GravitationGravitation

Force is always attractiveForce is proportional to both massesForce is inversely proportional to separation squared

×=

=

−2

311

221

m1067.6skg

GrmmGF

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Gravitation ConstantGravitation Constant

Determined experimentallyHenry Cavendish, 1798Light beam / mirror amplify motion

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ExampleExampleGiven: In SI units, G = 6.67x10-11, g=9.81 and the radius of Earth is 6.38 x106.Find Earth’s mass:

mgrMmGF

=

= 2

formula Basic

2RMmGmg =

GgRM

2

= = 5.99x1024 kg

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ExampleExampleGiven: The mass of Jupiter is 1.73x1027 kg

and Period of Io’s orbit is 17 daysFind: Radius of Io’s orbit

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SolutionSolutionGiven: T= 17·24·3600=1.47x106, M=1.73x1027, G=6.67x10-11

Find: r First, find ω from the period

tNπω 2

formula Basic

= s1028.412 6−×==T

πω

Next, solve for r

rmmaF 2formula Basic

ω==

=

=

23

22

ω

ω

GMrrMGr

2

formula Basic

rMmGF =

r = 1.84x109 m

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Tycho Brahe Tycho Brahe (1546(1546--1601)1601)

Lost part of nose in a duelEXTREMELY ACCURATE astronomical observations, nearly 10X improvement, corrected for atmosphereBelieved in Retrograde MotionHired Kepler to work as mathematician

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Johannes Johannes Kepler Kepler (1571(1571--1630)1630)First to:

Explain planetary motion Investigate the formation of pictures with a pin hole camera; Explain the process of vision by refraction within the eye Formulate eyeglass designed for nearsightedness and farsightedness; Explain the use of both eyes for depth perception. First to describe: real, virtual, upright and inverted images and magnification

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Johannes Johannes Kepler Kepler (1571(1571--1630)1630)First to:

explain the principles of how a telescope worksdiscover and describe total internal reflection. explain that tides are caused by the Moon. He tried to use stellar parallax caused by the Earth's orbit to measure the distance to the stars; the same principle as depth perception. Today this branch of research is called astrometry.suggest that the Sun rotates about its axis derive the birth year of Christ, that is now universally accepted. derive logarithms purely based on mathematics,

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Isaac Newton (1642Isaac Newton (1642--1727)1727)Invented CalculusFormulated the universal law of gravitationShowed how Kepler’s laws could be derived from an inverse-square-law forceInvented Wave MechanicsNumerous advances to mathematics and geometry

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Kepler’sKepler’s LawsLaws

1. All planets move in elliptical orbits with the Sun at one of the focal points.

2. A line drawn from the Sun to any planet sweeps out equal areas in equal time intervals.

3. The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet.

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Kepler’sKepler’s First LawFirst Law

All planets move in elliptical orbits with the Sun at one focus.

Any object bound to another by an inverse square law will move in an elliptical pathSecond focus is empty

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Kepler’s Second LawKepler’s Second Law

A line drawn from the Sun to any planet will sweep out equal areas in equal times

Area from A to B and C to D are the same

This is true for any central force due to angular momentum conservation (next chapter)

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Kepler’s Third LawKepler’s Third Law

The square of the orbital period of any planet is proportional to cube of the average distance from the Sun to the planet.

For orbit around the Sun, KS = 2.97x10-19

s2/m3

K is independent of the mass of the planet

sun3

2

KrT

=

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Derivation of Derivation of Kepler’s Kepler’s Third LawThird Law

rarMmGmaF

22

formula Basic

ω=

==2

2

2

rMmGrmrMmGma

=

=

ω

sun

2

3

2

22

3

44

KGMr

T

TGMr

==

=

ππ

Tπω 2

formula Basic

=

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ExampleExampleData: Radius of Earth’s orbit = 1.0 A.U.

Period of Jupiter’s orbit = 11.9 yearsPeriod of Earth’s orbit = 1.0 years

Find: Radius of Jupiter’s orbit

3

2

3

2

Jupiter

Jupiter

Earth

Earth

rT

rT

=

2

233

Earth

JupiterEarthJupiter T

Trr =

sun3

2formula Basic

KrT

=

= 5.2 A.U.3/2

=

Earth

JupiterEarthJupiter T

Trr

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Gravitational Potential EnergyGravitational Potential Energy

PE = mgy is valid only near the Earth’s surfaceFor arbitrary altitude

Zero reference level is infinitely far from the earth

rmMGPE E−=

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Graphing PE vs. positionGraphing PE vs. position

rmMGPE E−=

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ExampleExampleYou wish to hurl a projectile is hurled from the surface of the Earth (Re= 6.3x106 m) to an altitude of 20x106 m above the surface of the Earth. Ignore the rotation of the Earth and airresistance.

a) What initial velocity is required?

b) What velocity would be required in order for the projectile to reach infinitely high? I.e., what is the escape velocity?

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SolutionSolutionGiven: R0 = 6.3x106, R = 26.3x106, G, M = 6.0x1024

Find: v0First, get expression for change in PE

rMmGPE −=

formula Basic

−=∆rr

GMmPE 11

0

Then, apply energy conservation

20

0 2111 mv

rrGMm

KEPE

=

∆=∆2

formula Basic

21 mvKE =

Finally, solve for v0= 6 600 m/s

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Solution For Escape VelocitySolution For Escape VelocityGiven: R0 = 6.3x106, R = ∞, G, M = 6.0x1024

Find: v0First, get expression for change in PE

rMmGPE −=

formula Basic

0

1r

GMmPE =∆

Then, apply energy conservation

20

0 211 mv

rGMm

KEPE=

∆=∆2

formula Basic

21 mvKE =

Solve for v0 = 11 270 m/s