Moon Orbit Period Calc: Equatorial Radius of Earth & Time

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The discussion revolves around calculating the Moon's orbital period based on its distance from Earth, which is approximately 60 times the Earth's equatorial radius. Participants emphasize the importance of using the correct gravitational formulas and constants, particularly the mass of the Earth and the value of pi. There is confusion regarding the application of gravitational acceleration at different distances from Earth's core, with suggestions to derive local gravity values using ratios. The conversation highlights the need for accurate calculations and the correct interpretation of gravitational forces, ultimately pointing out that the Moon's orbital period is closer to a month, not the half-day initially calculated. Accurate understanding of gravitational principles is crucial for solving the problem effectively.
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Homework Statement


The orbit of the moon is approximately a circle of radius 60 times the equatorial radius of the earth. Calculate the time taken for the Moon to complete one orbit, neglecting the rotation of the earth.

Equatorial radius of the Earth = 6.4 *10^6m
1 day = 8.6*10^4s
Acceleration of free fall at the poles of Earth = 9.8ms^-2

Homework Equations


Newtonian law of gravity

The Attempt at a Solution


GMm/r^2 = mv^2/r and solve for v ---> v = sqrt(2GM/r)

Now it takes a period of time T fort he mion to make one full orbit. Thus it travels a distance C

C = 2*pi*r and using C = v*T --> T = C/v = 2*pi*r/sqrt(2GM/r)

Now i am told that r = 60Re where Re = radius of earth. were i go from here since I was not given the mass of the earth. And what do i use the value of pi as ?
 
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Boe Nancy said:

Homework Statement


The orbit of the moon is approximately a circle of radius 60 times the equatorial radius of the earth. Calculate the time taken for the Moon to complete one orbit, neglecting the rotation of the earth.

Equatorial radius of the Earth = 6.4 *10^6m
1 day = 8.6*10^4s
Acceleration of free fall at the poles of Earth = 9.8ms^-2

Homework Equations


Newtonian law of gravity

The Attempt at a Solution


GMm/r^2 = mv^2/r and solve for v ---> v = sqrt(2GM/r)

Now it takes a period of time T fort he mion to make one full orbit. Thus it travels a distance C

C = 2*pi*r and using C = v*T --> T = C/v = 2*pi*r/sqrt(2GM/r)

Now i am told that r = 60Re where Re = radius of earth.were i go from here since I was not given the mass of the earth. And what do i use the value of pi as ?

You can look up the mass of the Earth on this thing known as the internet.

Seriously, you don't know the value of pi (π), you know, the ratio of the circumference of a circle to its diameter? It's like a constant.
 
SteamKing said:
You can look up the mass of the Earth on this thing known as the internet.

Seriously, you don't know the value of pi (π), you know, the ratio of the circumference of a circle to its diameter? It's like a constant.
 

I wanted an alternative way to work it with the mass of the Earth since it was not given. And when i use 3.14 for pi i not getting the proper answer. Do you have any thing good to add to this question if not go ...
 
Boe Nancy said:
I wanted an alternative way to work it with the mass of the Earth since it was not given. And when i use 3.14 for pi i not getting the proper answer. Do you have any thing good to add to this question if not go ...

Thanks for your suggestion. Back at you.

If your answer isn't coming out correctly, I doubt it's because you're using an incorrect value of π.

Since you don't show any of your calculations, which is what the rules of the forum ask you to do, it's hard to tell where you might be making a mistake.
 
SteamKing said:
Thanks for your suggestion. Back at you.

If your answer isn't coming out correctly, I doubt it's because you're using an incorrect value of π.

Since you don't show any of your calculations, which is what the rules of the forum ask you to do, it's hard to tell where you might be making a mistake.

Hey are you going to answer the question yes or no its one set of small talk you pulling ?
 
Okay you two, please turn up the courtesy knob on your transmitters :)

Boe Nancy, consider that if you know the acceleration due to gravity at one Earth radius (g at the surface) then you can determine the local value of 'g' at any radius using a method of ratios. That will give you the centripetal acceleration...
 
Boe Nancy said:
Hey are you going to answer the question yes or no its one set of small talk you pulling ?
Hey if you are rude nobody will help you.
 
SteamKing said:
You can look up the mass of the Earth on this thing known as the internet.

Seriously, you don't know the value of pi (π), you know, the ratio of the circumference of a circle to its diameter? It's like a constant.

Boe Nancy said:
I wanted an alternative way to work it with the mass of the Earth since it was not given. And when i use 3.14 for pi i not getting the proper answer. Do you have any thing good to add to this question if not go ...

My interpretation is that the poster is wondering how many digits of accuracy to use for the pi constant. Since nearly every calculator these days has a ##\pi## key, just use that and all the digits provided. Other factors will determine the overall accuracy and precision of your calculated values.
 
  • #10
Your formula for v is not correct so maybe that is why you didn't get the right answer.
 
  • #11
gneill said:
Okay you two, please turn up the courtesy knob on your transmitters :)

Boe Nancy, consider that if you know the acceleration due to gravity at one Earth radius (g at the surface) then you can determine the local value of 'g' at any radius using a method of ratios. That will give you the centripetal acceleration...
LOL i will send a picture of what i did is just when I use the normal way of using the mass of the Earth i am getting the answer just the way without using the mass i am seeing trouble with i don't know if is transposing or some simple mistake i will put up a picture shortly
 
  • #12
lep11 said:
Hey if you are rude nobody will help you.
Yeah sorry i know just lost in a question an some guy was giving me a hard time
 
  • #13
this is what I did and got a period of 0.457 days, in the 2 attachment
 

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  • #14
Unfortunately your formula:
$$G \frac{M_E m_M}{r^2} = m_M g$$
is not correct. F = Mg only applies to objects located near the surface of the Earth where the acceleration due to gravity is approximated by a constant g. If the Moon happened to orbit at the Earth's surface you would be fine, and your period of about half a day might even be credible. But we know that the period of the Moon is closer to a month (hence the name "month" derived from "Moon").

I gave you a hint about finding the acceleration due to gravity at the Moon's orbital radius given the known acceleration due to gravity near the Earth's surface...
 
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  • #15
gneill said:
Unfortunately your formula:
$$G \frac{M_E m_M}{r^2} = m_M g$$
is not correct. F = Mg only applies to objects located near the surface of the Earth where the acceleration due to gravity is approximated by a constant g. If the Moon happened to orbit at the Earth's surface you would be fine, and your period of about half a day might even be credible. But we know that the period of the Moon is closer to a month (hence the name "month" derived from "Moon").

I gave you a hint about finding the acceleration due to gravity at the Moon's orbital radius given the known acceleration due to gravity near the Earth's surface...
Oh lawd this question is head ache could you give me a little more detail please
 
  • #16
Boe Nancy said:
Oh lawd this question is head ache could you give me a little more detail please
So do i have to use the value of the moon gravity
 
  • #17
What he's trying to say is that g varies depending on your distance from Earth's core. For example, think if you are at Mount Everest. You are further away from Earth's core on Mount Everest then you are at sea level. So, your acceleration due to gravity is lower (albeit very small) at Mount Everest than at sea level. Now think of how far away the moon is from the Earth's core: (3.84*108 meters).

So do i have to use the value of the moon gravity

No. You still need to place the moon in relation to Earth. But, you should know that you can't use Earth's g on the moon - Earth doesn't exert a full 9.8m/s2 on the moon. It's only the acceleration due to gravity on Earth's surface.
 
  • #18
GMm/r^2 = mv^2/r

v=ωr and T=(2π)/ω

M=5.97219 × 1024 kg

What is the problem? Is it not allowed to use the known value of M?
 
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  • #19
lep11 said:
What is the problem? Is it not allowed to use the known value of M?
That is the problem, yes. It wasn't a given in the original problem statement. But it isn't required if you know how g varies with distance.

@Boe Nancy , what is the formula for the acceleration due to gravity? (You can use Mearth here, it will disappear from the equations shortly).
 
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