Precalculus Distance Sun-Earth-Moon Problem

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In summary: Angle = 32' (arc minutes) and subtended angle = 0.54 degrees.Use the law of cosines to solve for the diameter of the sun. This will give you the answer in kilometers.Remember that cosines are just a relationship between two angles and so the answer will be in radians. So just divide by two to get the answer in miles.Is that what you were looking for?In summary, this problem asks for the distance from the Earth to the sun and the moon. The student has been trying to solve it for hours and is now asking for help. They have drawn a picture and calculated the answer. It appears that they are finding the distance to the moon from the Earth.
  • #1
katrina007
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Hi,

I have this homework problem and need help. if anyone can help me please send me a message or email me at gettrinatak007@yahoo.com

This is the the Precalculus word problem!


At a certain point in the Earth's orbit around the Sun, its distance from the sun is 92.69 x 10^6 miles. At this point the angle subtended by the sun when observed from the Earth is [Angle = 32' (arc minutes)]



a) Considering the Earth's radius to be negligible and making any other reasonable simplifying assumptions, use the law of cosines to find the diameter of the sun giving your answer to the nearest 1000 miles.

b) using any assumptions and reasonable method, find the distance to the moon when its subtended angle is 32' arc minutes (0.54 degrees) assuming its diameter is 2160miles


Let me know if you can help me with this. Any help is appreciaited
 
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  • #2
Sure we can help you.. BUT..

You need to show that you have made some effort to complete the problem.

Can you draw a picture, labing the given quanities, then apply trig to get a answer?
 
  • #3
If you've been assigned this problem, you must know a little trigonometry. If so, then draw a triangle and start filling in angles and distances and if you have a specific problem, someone can help you. If not, then you've been assigned the wrong problem.
 
  • #4
Hi thanks for your quick reply.

This is due tomrrow and I've been trying so much for past 2-3hrs. i know its too much. and srry i don't have picture to show but anyways, i thought of using the law of cosine formula to solve part a.

c2 = a2 + b2 - 2abCos Y

The distance from the Earth to sun is 92.69 x 10^6 and i input this into a2 and b2 as well as (2)(a)(b) and for the CosY the angle is 32' (arc minutues which is 0.54 degrees)

Then I take the sqaure root and find C = 862794.8527

Is this correct or am I doing something wrong?
thanks for taking your time looking at this. Hope you can help me with this today. thanks again.
 
  • #5
You are, in fact, doing it correctly. I would put the distance to the sun at the perpendicular bisector of your triangle and solve it as a right triangle problem. But with such a small angle it wouldn't make much difference in the answer.
 
  • #6
I think the formula i used it correct but the answer I'm getting: I don't think it sounds reasonable and that's why I was confused and wanted help with it.

Found this image on another site...This is same on my homework paper.
moonsun.gif


How would I use what you are talking about? "The perpendicular bisector" ?
 
  • #7
I know you are right because I know the diameter of the sun is about 10^6 miles. So it's very reasonable. I would have drawn a vertical diameter through the sun and split your isoceles triangle into two right triangles. But now I realize that's an approximation too. Thanks for posting the picture. But I think either approach will give you an answer within 1000 miles. Either one could be considered a 'reasonable simplifying assumption'.
 
  • #8
I had doubts with the answer, but I guess since more people (you) agree with the answer and process of solution I think it is right. Thanks for your help for part (a)...

Would I be solving the part (b) the same way as I did for part (a)?
Am I finding the distance to the moon from the Sun or the Earth? Thats what is confusing me because it really doesn't specify. But assuming the solution to part (a) I think it is from the sun? Please let me know what you think and how I would go about solving it...

Thanks again for your help.
 
  • #9
Yes, it's pretty much the same problem. And you are finding the distance from the moon to the earth. All that changes is that you used to know a and b and want to find c. Now you know c and want to find a and b (and a=b).
 
  • #10
but how would i find a and b when the only information i have available is that the diameter of the moon is 2160 miles and the angle is 32' arc minutes?

a and b was 92.69 x 10^6 for the distance from Earth to sun, but now i need to find distance from Earth to moon? i don't know how to do this? what formula do i use?
 
  • #11
Now the diameter of the moon is c. Set b=a and solve for a. There is still only one unknown.
 
  • #12
Well there are two approaches, at least, and in passing must mention what a curious situation we enjoy currently when the moon and the sun subtend the same angular size in the sky. It allows for a just so often total eclipse where the Earth falls into the shadow of the moon.

So you could solve this by similar triangles, that is the ratio of the suns diameter to the distance is the same as the moon to the earth. Or just use

tan(angle/2)=radius/distance.
 
  • #13
Dick said:
Now the diameter of the moon is c. Set b=a and solve for a. There is still only one unknown.

i guess I am missing something here. I still don't understand...because
in part (b) the diameter of the moon is given: 2160 miles. I can't use the diameter of the sun. (I don't know if you meant the same as me...) but anyways, still I don't have enough information to use any of the laws formulas to solve the problem.

when you say set b=a, what are these values? I don't know them.

Well there are two approaches, at least, and in passing must mention what a curious situation we enjoy currently when the moon and the sun subtend the same angular size in the sky. It allows for a just so often total eclipse where the Earth falls into the shadow of the moon.

So you could solve this by similar triangles, that is the ratio of the suns diameter to the distance is the same as the moon to the earth. Or just use

tan(angle/2)=radius/distance.

I tried the tan(angle/2) formula but that only gives me a distance in decimal. is that possible?
 
  • #14
Hey doc, How are ya? BTW if you note the diagram that katrina007 thoughtfully provided you will see that tan(angle/2)=radius/distance is subtly wrong. If the angle subtended is very large, it's very wrong. Funny, I hadn't thought of that. BTW also what's with this curious coincidence of the moon's angular size and the sun's? Anthropic? Sorry to the OP for disgressing on the post.
 
  • #15
yea i thought so that the tangent formula isn't going to work...
can you please explain to me how to work this problem using your way?
 
  • #16
Ooops. Thought you were gone. What do you mean, an distance in decimal? Sure you can use it. If you check it gives you almost the same result as the law of cosines approach.
 
  • #17
Both approaches work quite accurately. And neither approach works completely. The difference is the difference between drawing a vertical diameter through the sun and a vertical line between your two tangent points. The aren't quite the same, right? But for small angles the difference can be ignored.
 
  • #18
I was using what the Doc suggested, using the tan(angle/2) formula. I tried this and got a decimal value which I believe is not correct or maybe I've missed something... Idk.

But you were talking about letting b=a and solving? The value for C (moon's diameter) is given and its 2160miles. And I know that the angle is 32' arc minutes (0.54 degrees). I'm trying to solve for the distance between Earth and moon... What formula do I use to solve this?

I don't think I can use law of cosine or sine
 
  • #19
Well that mastermind Dick, has us us both in the dark. I can see where it fails to account for the distance to the center of the earth, but the problem tells us to ignore that.
 
  • #20
I have to go now. past midnight here. need my rest and need a big break from all this calculus stuff.

Thanks to all that helped me with this homework request. I will check it again tomorrow morning for replies, other hints/tips... will appreciate it if someone can solve the 2nd part of the question.

Thanks again. Goodnight (if it is night over there...) :D
Katrina
 
  • #21
Dick, OT, I hadn't given the moon much thought until I saw a great science channel show on the issue, where strong arguments were presented that the origin of life depends on such. Now I am no believer in lunacy and have been on the frontlines in many ER's during a full moon. Thats urban myth. Yet the menstrual cycle is 28 days!? Current theories suggest that in the early days of the moons formation via impact would have tides ten times any recent tsunami on a regular basis. May have had a hand into life going from ocean to land?
 
  • #22
"that mastermind Dick"? Well, I NEVER. What ARROGANCE! What I've been trying to say is that anyway you do it you will get almost the same answer because the angle is so small. I was afraid the OP would see through the subterfuge and see that we are both lying. Fine. FINE. I DON'T CARE. What I was trying to do was work through the answer all ways and post the differences for comparison.
 
  • #23
Ok Katrina, it's night alright. You can do it anyway you want. If the answer is somewhere around 240000 miles, consider yourself right. Because I'll be busy. I have to meet doc someplace, in a dark alley!
 
  • #24
What I meant by that is that, aside from all private joking with doc, simply turn in your homework with an answer anywhere like that. All approaches we have discussed are equivalent within 1000 miles or much less.
 
  • #25
Ok, the really correct answer is distance*sin(angle/2)=radius. Can you figure out why? Let's compare how this does vs various 'incorrect' answers (like the one doc and I were proposing and the 'law of cosines' (at least as I was interpreting it)). I'm using the .54 degree angle. 34' is a few percent different.

sin formula (correct): 862794.5830208
tan formula (incorrect): 862803.927896
'law of cosines' (incorrect): 862794.5830212

I guess the moral of the story is that nature is pretty forgiving of sloppiness for small angles.
 
  • #26
Hi,

Thanks again for all your help. I checked the homework part (a) with my teacher and said it is correct. He gave us few more questions and gave more time for the homework. So that's a relief. I stayed up almost all night for nothing lol... Anyways thanks again.
 
  • #27
given your law of cosines equation:

[tex] c^2 = a^2 + b^2 - 2abcos Y [/tex]

you are given c (diameter of the moon) then set a=b to get:

[tex] c^2 = 2a^2 + 2a^2 cos Y [/tex]

[tex] c^2 = 2a^2 (1 + cos Y) [/tex]

Can you solve for a?
 

1. How is the distance between the Sun, Earth, and Moon calculated in precalculus?

In precalculus, the distance between the Sun, Earth, and Moon is calculated using the Pythagorean theorem, which states that in a right triangle, the square of the length of the hypotenuse (the side opposite the right angle) is equal to the sum of the squares of the other two sides. This formula is used to calculate the distance between any two points in 3-dimensional space, including the Sun, Earth, and Moon.

2. Why is the distance between the Sun, Earth, and Moon important in precalculus?

The distance between the Sun, Earth, and Moon is important in precalculus because it is a fundamental component in understanding the geometry and motion of these celestial bodies. It is also a key factor in calculating other important quantities such as gravitational forces and orbital paths.

3. How does the distance between the Sun, Earth, and Moon affect the tides on Earth?

The distance between the Sun, Earth, and Moon plays a significant role in the tides on Earth. The gravitational pull of the Moon on the Earth's oceans causes the tides, and this force is stronger when the Moon is closer to the Earth. The Sun also has a smaller but still noticeable effect on tides due to its gravitational pull. When the Sun, Earth, and Moon are aligned, the combined gravitational forces of the Sun and Moon result in higher tides, known as spring tides. When they are at right angles to each other, the gravitational forces partially cancel out, resulting in lower tides, known as neap tides.

4. Can precalculus be used to calculate the distance between the Sun, Earth, and other planets?

Yes, precalculus can be used to calculate the distance between the Sun, Earth, and other planets. The same principles and formulas used to calculate the distance between the Sun, Earth, and Moon can be applied to calculate the distance between any two points in space, including the Sun and other planets.

5. How accurate are precalculus calculations of the distance between the Sun, Earth, and Moon?

Precalculus calculations of the distance between the Sun, Earth, and Moon are generally very accurate. However, there may be slight variations due to the constantly changing positions of the celestial bodies and other factors such as gravitational interactions with other objects in space. These variations are often taken into account and adjusted for in more advanced calculations.

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