Upload File

quiz 5. 1. suppose that a planet was found to orbit the sun, and that its path was an ellipse with...

  • Home
  • Documents
  • Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at
29
Quiz 5

Upload: liam-bowditch

Post on 14-Dec-2015

214 views

Category:

Documents


0 download

Report

Tags:

TRANSCRIPT

Page 1: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

Quiz 5

Page 2: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

1.Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at the same speed, would it satisfy Kepler's second law? Choose the best answer of the four below.

1. Yes, because when an object sweeps out equal areas in equal time, it must travel slower when it is closer to the planet.

2. No, because when an object sweeps out equal areas in equal time, it must travel slower when it is closer to the planet.

3. Yes, because when an object sweeps out equal areas in equal time, it must travel faster when it is closer to the planet.

4. No, because when an object sweeps out equal areas in equal time, it must travel faster when it is closer to the planet.

Page 3: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

1.Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at the same speed, would it satisfy Kepler's second law? Choose the best answer of the four below.

1. Yes, because when an object sweeps out equal areas in equal time, it must travel slower when it is closer to the planet.

2. No, because when an object sweeps out equal areas in equal time, it must travel slower when it is closer to the planet.

3. Yes, because when an object sweeps out equal areas in equal time, it must travel faster when it is closer to the planet.

4. No, because when an object sweeps out equal areas in equal time, it must travel faster when it is closer to the planet.

Page 4: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

2.If you measured your weight with very high precision scale, would you see a difference between your weight at the top of a mountain versus at the bottom of the mountain? Select the best answer.

1. Yes, because the force that Earth exerts on me would be slightly less because my mass increases as I move away from Earth.

2. Yes, because the force that Earth exerts on me would be slightly less because I am slightly farther from it.

3. No, my weight will be the same everywhere.

4. Yes, because the force that Earth exerts on me would be slightly less because my mass decreases as I move away from Earth.

Page 5: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

2.If you measured your weight with very high precision scale, would you see a difference between your weight at the top of a mountain versus at the bottom of the mountain? Select the best answer.

1. Yes, because the force that Earth exerts on me would be slightly less because my mass increases as I move away from Earth.

2. Yes, because the force that Earth exerts on me would be slightly less because I am slightly farther from it.

3. No, my weight will be the same everywhere.

4. Yes, because the force that Earth exerts on me would be slightly less because my mass decreases as I move away from Earth.

Page 6: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

Bob Beamon

Page 7: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at
Page 8: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

3.Newton's Law of Gravity is F = G*m1*m2/(r*r)

.This equation states that if the distance between two objects increases by a factor of three, the force they exert on each other

1. decreases by a factor of nine.

2. increases by a factor of nine.

3. does not change.

4. increases by a factor of three.

5. decreases by a factor of three.

Page 9: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

3.Newton's Law of Gravity is F = G*m1*m2/(r*r)

.This equation states that if the distance between two objects increases by a factor of three, the force they exert on each other

1. decreases by a factor of nine.

2. increases by a factor of nine.

3. does not change.

4. increases by a factor of three.

5. decreases by a factor of three.

Page 10: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

4.Newton's Law of Gravity is F = G*m1*m2/(r*r)

.This equation states that if the distance between two objects increases by a factor of three, the force they exert on each other

1. decreases by a factor of nine.

2. increases by a factor of nine.

3. does not change.

4. increases by a factor of three.

5. decreases by a factor of three.

Page 11: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

4.Newton's Law of Gravity is F = G*m1*m2/(r*r)

.This equation states that if the distance between two objects increases by a factor of three, the force they exert on each other

1. decreases by a factor of nine.

2. increases by a factor of nine.

3. does not change.

4. increases by a factor of three.

5. decreases by a factor of three.

Page 12: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

5.Newton's Law of Gravity is F = G*m1*m2/(r*r)

This equation states that if the mass of each object increased by a factor of two, the force that object 1 exerts on object 2

1. decreases by a factor of 4.

2. increases by a factor of 4.

3. does not change.

4. increases by a factor of 2.

5. decreases by a factor of 2.

Page 13: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

5.Newton's Law of Gravity is F = G*m1*m2/(r*r)

This equation states that if the mass of each object increased by a factor of two, the force that object 1 exerts on object 2

1. decreases by a factor of 4.

2. increases by a factor of 4.

3. does not change.

4. increases by a factor of 2.

5. decreases by a factor of 2.

Page 14: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

6.In class, we came up with an equation that related a planet's orbital speed, v, with its distance from the sun, r given the sun had mass M, v*v = G*M/r

Why is this equation consistent with Kepler's second law?

1. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the smaller v is.

2. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the larger the gravitational force of the sun is on the planet.

3. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the larger the weight of the planet.

4. According to Kepler's second law, the further the planet is from the sun, the faster it moves. According to this equation, the larger r is, the larger v is.

Page 15: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

6.In class, we came up with an equation that related a planet's orbital speed, v, with its distance from the sun, r given the sun had mass M, v*v = G*M/r

Why is this equation consistent with Kepler's second law?

1. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the smaller v is.

2. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the larger the gravitational force of the sun is on the planet.

3. According to Kepler's second law, the further the planet is from the sun, the slower it moves. According to this equation, the larger r is, the larger the weight of the planet.

4. According to Kepler's second law, the further the planet is from the sun, the faster it moves. According to this equation, the larger r is, the larger v is.

Page 16: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

7.

In the following figure, at which position would the force of gravity due to Earth be about the same, but in opposite direction, as the force of gravity due to Mars?  Note that Mars has a smaller mass than Earth.

1. 1

2. 2

3. 3

Page 17: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

7.

In the following figure, at which position would the force of gravity due to Earth be about the same, but in opposite direction, as the force of gravity due to Mars?  Note that Mars has a smaller mass than Earth.

1. 1

2. 2

3. 3

Page 18: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

8.Given that Earth is much larger and more massive than the Moon, how does the strength of the gravitational force that the Moon exerts on Earth compare to the gravitational force that Earth exerts on the Moon?

Student 1: I thought that whenever one object exerts a force on the second object, the second object also exerts a force that is equal in strength, but in the other direction. So even if Earth is bigger and more massive than the Moon, they still pull on each other with a gravitational force of the same strength, just in different directions.

Student 2: I disagree. I said that Earth exerts the stronger force because it is way bigger than the Moon. Because its mass is bigger, the gravitational force Earth exerts has to be bigger too. I think that you are confusing Newton’s third law with the law of gravity.

Which student is correct?

1. Student 1

2. Student 2

Page 19: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

8.Given that Earth is much larger and more massive than the Moon, how does the strength of the gravitational force that the Moon exerts on Earth compare to the gravitational force that Earth exerts on the Moon?

Student 1: I thought that whenever one object exerts a force on the second object, the second object also exerts a force that is equal in strength, but in the other direction. So even if Earth is bigger and more massive than the Moon, they still pull on each other with a gravitational force of the same strength, just in different directions.

Student 2: I disagree. I said that Earth exerts the stronger force because it is way bigger than the Moon. Because its mass is bigger, the gravitational force Earth exerts has to be bigger too. I think that you are confusing Newton’s third law with the law of gravity.

Which student is correct?

1. Student 1

2. Student 2

Page 20: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

9.If the mass of the Earth was twice as large but its radius was the same, what would happen to your mass and weight?

1. Your mass and weight would both be unchanged.

2. Your mass would decrease and your weight would be the same.

3. Your mass would increase and your weight would be the same.

4. Your mass and weight would both increase.

5. Your mass would be the same and your weight would increase.

Page 21: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

9.If the mass of the Earth was twice as large but its radius was the same, what would happen to your mass and weight?

1. Your mass and weight would both be unchanged.

2. Your mass would decrease and your weight would be the same.

3. Your mass would increase and your weight would be the same.

4. Your mass and weight would both increase.

5. Your mass would be the same and your weight would increase.

Page 22: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

10.

If the mass of the Earth was twice as large and its radius was the same, what would its density be?

1. Its density would be one quarter of its current value

2. Its density would be the same

3. Its density would be one eighth of its current value

4. Its density would be one half of its current value

5. Its density would be twice its current value

Page 23: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

10.

If the mass of the Earth was twice as large and its radius was the same, what would its density be?

1. Its density would be one quarter of its current value

2. Its density would be the same

3. Its density would be one eighth of its current value

4. Its density would be one half of its current value

5. Its density would be twice its current value

Page 24: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

11.

According to Newton's Law of Gravity, if the mass of each object increased by a factor of four, the force that object 1 exerts on object 2

1. does not change.

2. increases by a factor of 2.

3. decreases by a factor of 4.

4. increases by a factor of 16.

5. decreases by a factor of 2.

6. increases by a factor of four

Page 25: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

11.

According to Newton's Law of Gravity, if the mass of each object increased by a factor of four, the force that object 1 exerts on object 2

1. does not change.

2. increases by a factor of 2.

3. decreases by a factor of 4.

4. increases by a factor of 16.

5. decreases by a factor of 2.

6. increases by a factor of four

Page 26: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

12.Newton's Law of Gravity is F = G*m1*m2/(r*r)

This equation states that if the distance between two objects increases by a factor of nine, the force they exert on each other

1. decreases by a factor of eighty-one.

2. does not change.

3. increases by a factor of three.

4. decreases by a factor of nine.

5. increases by a factor of nine.

Page 27: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

12.Newton's Law of Gravity is F = G*m1*m2/(r*r)

This equation states that if the distance between two objects increases by a factor of nine, the force they exert on each other

1. decreases by a factor of eighty-one.

2. does not change.

3. increases by a factor of three.

4. decreases by a factor of nine.

5. increases by a factor of nine.

Page 28: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

13.

Suppose you are on the moon and you drop two balls from the same height, one with mass1=m and the other with mass2=2m. A student notes that Newton's second law says that their accelerations should be a1=F/m and a2=F/(2m), respectively.

Is it correct to conclude mass 2 will take longer to hit the surface of the moon because its acceleration is smaller by a factor of two?

1. No. Both accelerations will be the same. Although mass 2 is heavier, the force that the moon exerts on it is a factor of two larger.

2. Yes, both accelerations will be the same and therefore they will both move at identical speeds as they fall.

Page 29: Quiz 5. 1. Suppose that a planet was found to orbit the Sun, and that its path was an ellipse with eccentricity of 0.5. If the planet always moved at

13.

Suppose you are on the moon and you drop two balls from the same height, one with mass1=m and the other with mass2=2m. A student notes that Newton's second law says that their accelerations should be a1=F/m and a2=F/(2m), respectively.

Is it correct to conclude mass 2 will take longer to hit the surface of the moon because its acceleration is smaller by a factor of two?

1. No. Both accelerations will be the same. Although mass 2 is heavier, the force that the moon exerts on it is a factor of two larger.

2. Yes, both accelerations will be the same and therefore they will both move at identical speeds as they fall.


 · 14. Find the length of major axis, minor axis, latus rectum, eccentricity, coordinates of the centre, foci and equations of directrices of the ellipse. 9x2 + 16y2 = 144 . 15..Find

The giant dipole vortex - hfa1.physics.msstate.edu · The dipole moment is given by with d o > 0. ... of the vortex diminishes with increasing eccentricity of the ellipse [6]. In

14 Ellipse

ECCENTRICITY PRACTICE

Eccentricity is the ratio of the distance between the foci and the length of the major axis of an ellipse

Ellipse Derived

Pile Eccentricity

To each conic section (ellipse, parabola, hyperbola, circle) there is a number called the eccentricity that uniquely characterizes the shape of the curve

Eccentricity from transit_photometry_small_planets_in_kepler_multi_planet_systems_have_low_eccentricities

Perihelion – when a planet is closest to the sun in its orbit. Aphelion – when a planet is farthest from the sun in its orbit. Ellipse – the oval

Capa 0 - Fundación Argentina Diabetes...Ellipse 2 copy 3. 70%. 90%. 90%. 80%. Ellipse 3. Ellipse 3 copia. Ellipse 3 copia 2. Ellipse 3 copia 3. Ellipse 3 copia 4. ... do mi experienc'a

Ellipse Final

bppdcg.weebly.combppdcg.weebly.com/uploads/1/3/6/8/13685178/ellipse.pdfEccentricity Method The eccentricity for an ellipse is always less than 1, e.g. 3/4, 2/3, 0.7, 0.61 etc. but

ATEX style emulateapj v. 12/16/11 · 2018. 9. 10. · the Roche limit, with extremely large eccentricity or with moderate ones that may result from planet-planet inter-actions (e.g.,

ECCENTRICITY, SPACE BENDING DIMENSION

Dynamic Balancing Eccentricity

Ellipse Brochure

Class-XI Mathematics Conic Sections Chapter-11 Chapter ... · Class-XI Mathematics Conic Sections Chapter-11 ... 3 F 1 +P 3 F 2 ... The eccentricity of an ellipse is the ratio of

ECCENTRICITY, SPACE BENDING, DIMMENSION

Wk7 Raft foundations + Eccentricity

 · 2017-02-05 · 13. If S and T are the foci of an ellipse and B is one end of the minor axis. If STB is an equilateral triangle, then find the eccentricity of the ellipse. 14

1. Details of Module and its structure · 2. Ellipse 3. Special cases of ellipse 4. Eccentricity 5. Standard equations of an ellipse 6. Latus rectum 7. Examples 8. Summary 1. Introduction:

 · 13. If S and T are the foci of an ellipse and B is one end of the minor axis. If STB is an equilateral triangle, then find the eccentricity of the ellipse. 14. Find the centre

UNIT I PLANE CURVES AND FREE HAND …chettinadtech.ac.in/storage/11-09-13/11-09-13-05-22-54-1147...Conics – Construction of ellipse, Parabola and hyperbola by eccentricity method

pile eccentricity calculation

Ellipse - Sakshi · ELLIPSE A conic is said to be an ellipse if it’s eccentricity e is less than 1. Equation of an Ellipse in Standard Form: The equation of an ellipse in the standard

Two Way Eccentricity

Ellipse (english)

Kepler's Law Kepler’s First Law – the orbit of any planet is an ellipse with the sun at one focus

Jerarquias Ellipse

ECCENTRICITY, SPACE BENDING, DIMENSION

Mathematics Ellipse

Ellipse /Circle Router Jig Instructionsgo.rockler.com/tech/router-ellipse-circle-jig-instructions.pdf · Ellipse/Circle Router Jig Instructions The Ellipse/Circle Router Jig allows

ELLIPSE - Sakshi Educationsakshieducation.com/.../CoOrdinateGeometry/Ellipse.pdf 20. If the distance between a focus and corresponding directrix of an ellipse be 8 and the eccentricity

Curves - PVT...38 Geometrical Drawing EXAMPLE 2.1: Construct an ellipse having eccentricity 2/3 with distance between the directrix and focus as 70 mm. SOLUTION: Given data: e = 2/3,