Gravitational Orbits: Circular vs. Elliptical

In summary, an elliptical orbit is one in which the momentum of the orbiting object is constantly changing direction.
  • #1
Fredley_Banyo
6
0

Homework Statement



1. Which of the following statements about a circular orbit are true? (The planet is orbiting around the star.)


a. At any instant the momentum of the planet is tangent to the planet's trajectory.

b. The magnitude of the planet's momentum is constant.

c. At every instant, dvector p/dt points from the planet to the star.

d. The direction of the planet's momentum is changing at every instant.

e.The gravitational force on the planet due to the star always acts at a right angle to the planet's momentum.




2. Which of the following statements about an elliptical orbit are true? (The planet is orbiting around the star.)


a. At any instant the momentum of the planet is tangent to the planet's trajectory.

b. The magnitude of the planet's momentum is constant.

c. At every instant, dvector p/dt points from the planet to the star.

d. The direction of the planet's momentum is changing at every instant.

e.The gravitational force on the planet due to the star always acts at a right angle to the planet's momentum.





I want to know which choice applies to each so i can better understand the concepts of gravitational orbits.




The Attempt at a Solution



My guess for a circular orbit was a,b,d and e because the momentum's magnitude is constant but is constantly changing direction. The gravitational force from the star is pointed towards the center of the orbit so that is why i thought e was true as well. As for an elliptical orbit i really have to idea except for the fact that the magnitude of momentum is not constant which makes it elliptical and not circular.
 
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  • #2
Forget about orbits for a bit. Answers (a) and (c) are very basic.

- Regarding answer (a), what is momentum -- how is it defined?
- Regarding answer (c), what does Newton's second law have to say about dp/dt?
 
  • #3
Momentum is defined as mass*velocity and is a vector. dp/dt is the rate of change of momentum and there is both a perpendicular component to the motion, which is the gravitational force and also one parallel which deals with the direction, which is constantly changing.
 
  • #4
What does it mean for something to be parallel to the trajectory? Again, forget orbits. Think in very basic, very general terms.

What is Newton's second law? (Hint: It is not F=ma.)
 
  • #5
It says that the total vector sum of forces acting on a system is equal to the rate of change of its momentum (dp/dt)
 
  • #6
OK! Now look at answers (c) in light of what you just said.
 
  • #7
So that is saying that the net force is pointing towards the center of the orbit.
 
  • #9
I finally figured it out. For the circular orbit it is all five and for the elliptical it is a,c and d. Thank you for your help.
 
  • #10
Very good.

Oh yes, and welcome to PhysicsForums, Fredley.
 

1. What is a gravitational orbit?

A gravitational orbit is the path that an object takes around a more massive object, such as a planet or star, due to the force of gravity. The object in orbit is continuously falling towards the larger object, but its forward motion keeps it from crashing into it.

2. What is the difference between a circular and elliptical orbit?

A circular orbit is a type of orbit where the object moves around the larger object in a perfect circle, maintaining the same distance at all times. An elliptical orbit, on the other hand, is when the object moves around the larger object in an oval shape, with varying distances at different points in its orbit.

3. Which type of orbit is more stable?

A circular orbit is considered to be more stable because the object is always at the same distance from the larger object and is constantly moving in a predictable path. In an elliptical orbit, the distance between the objects is constantly changing, making it less stable.

4. How do objects enter into an elliptical orbit?

Objects can enter into an elliptical orbit in a few different ways. One way is through a gravitational slingshot, where the object gains enough speed and momentum from a larger object to enter into an elliptical orbit. Another way is through a collision or impact, causing the object to be pulled into an elliptical orbit by the larger object's gravity.

5. Can an object in a circular orbit transition into an elliptical orbit?

Yes, an object in a circular orbit can transition into an elliptical orbit. This can happen if the object is affected by other objects' gravitational forces or if it expends energy, causing it to lose speed and fall into an elliptical orbit. This transition can also occur due to tidal forces, such as when a planet's orbit becomes elliptical due to the gravitational pull of its moon.

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