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enter image description here

If this is a posible periodic solution for a three-body problem, can anybody tell me where is the center of mass of the system? As we know, in a n-body problem the bodies orbit around their center of mass, but here I don't know where it is. Can anybody help me? Thanks.

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  • $\begingroup$ I don't know what you mean by the bodies orbit around their centre of mass. Since in the general n-body problem the bodies don't orbit at all, their motions are chaotic. The centre of mass in the diagram is at the middle of the figure of 8. $\endgroup$
    – James K
    Commented Sep 1, 2016 at 22:45
  • $\begingroup$ Ok so, in a n body problem, the motion of the bodies doesnt have to be around the center of mass. Is this what youve saying? $\endgroup$ Commented Sep 1, 2016 at 23:22
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    $\begingroup$ You might want to add a link to show where the image is from, and better yet, where that solution is from! $\endgroup$
    – uhoh
    Commented Sep 2, 2016 at 1:40
  • $\begingroup$ Although part of the premise may not be 100% correct, this part of the question (the sentence ending with a question mark) is clear: "If this is a possible periodic solution for a three-body problem, can anybody tell me where is the center of mass of the system?" It has a clear answer, posted below. $\endgroup$
    – uhoh
    Commented Sep 2, 2016 at 1:45

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There may be some three-body periodic solutions that orbit around a common point, but in general they get a little crazy-looking and may not always contain an immediately obvious center of mass from casual observation. But of course it will always exist.

If you watch closely, you'll see that whenever one body reaches the intersection point, all three are on a straight line with the other two equidistant (symmetric). If you look where this orbit was originally described mathematically, they probably defined the initial conditions with the green one in the middle - so that the y coordinates of all there were zero and the line at that point is horizontal.

At those moments (all six permutations are present) the center of mass is at the intersection point since the masses are equal.

Since there are no external forces, the center of mass doesn't change in between those moments, so the center of mass is always at the intersection point.

enter image description here

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If this is a possible periodic solution for a three-body problem?

What you've posted here is the classic "figure 8" orbit for a 3 body system. Originally the 3-body system was an unsolvable mathematics problem, until people started using computers to do the math for us. Recently, a set of 13 "stable" 3-body orbits have been found which were published in this paper. A diagram illustrating these orbits (with the accompanying caption) is shown below.

enter image description here

FIG. 1: The (translucent) shape-space sphere, with its backside also visible here. Three two-body collision points (bold red circles) - punctures in the sphere - lie on the equator. (a) The solid black line encircling the shape sphere twice is the figure-8 orbit. (b) Class I.A butterfly I orbit (I.A.1). Note the two reflection symmetry axes. (c) Class I.B moth I orbit (I.B.1) on the shape-space sphere. Note the two reflection symmetry axes. (d) Class II.B yarn orbit (II.B.1) on the shape-space sphere. Note the single-point reflection symmetry. (e) Class II.C yin-yang I orbit (II.C.2) on the shape-space sphere. Note the single-point reflection symmetry. (f) An illustration of a real space orbit, the “yin-yang II” orbit (II.C.3a).

It is hard to tell, but the gif you've posted is represented by (a) above. So I suppose the answer to your question is, yes, the figure 8 is a possible solution for the 3-body problem. However, I should caution that there is no possible 3-body system which is stable for long periods, especially if those three bodies have nearly equal masses. Our Sun/Earth/Moon system is only so stable because $M_{Sun}>>M_{Earth}>>M_{Moon}$ and they all effectively have binary orbits. For three, roughly equal mass stars, your system gets wildly unstable very quickly. Pretty much any perturbation will knock your system out.

Can anybody tell me where is the center of mass of the system?

As uhoh very nicely reasons out, the center of mass is in the center of the figure 8. Note however, that your system appears to show all bodies orbiting in a single plane. Obviously the real universe is 3 dimensions and very likely these objects would be orbiting in 3 dimensions, making the location of the center of mass more complicated. In the image above, you can see that the orbits oscillate up and down periodically, but they will do so in such a way that the center of mass is in the midplane of this oscillation, as well as the center of the figure 8.

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  • $\begingroup$ The green "shape-space spheres" are not representations of orbits in real space. Shape space is a mathematical tool used to classify various solutions. Those pics look very cool, but that's not what the orbits look like. All of the solutions in that paper are coplanar - flat 2D orbits only. $\endgroup$
    – uhoh
    Commented Sep 5, 2016 at 18:31
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As we know, in a n-body problem the bodies orbit around their center of mass, but here I don't know where it is. Can anybody help me? Thanks.

All orbits are n-body systems. There's essentially no perfect 2 body systems anywhere in the universe. Our solar-system is an N-body, not a 2 body, but nearly all the orbits in our solar system approximate 2 body orbits.

Long term stable N-body systems are very similar to 2-body systems. Unstable or chaotic N-body systems like this one on Wikipedia, don't last very long. They turn into stable systems and in the process, usually eject some objects.

enter image description here

Source.

While I would be hesitant to try to prove this mathematically, the figure 8 orbit reminds me of balancing a pencil on it's tip. Slight variations tend to grow over time and it destabilizes quickly. (cool video on Pencil-balancing)

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  • $\begingroup$ I think you should separate your discussion about "real world orbits" in the universe, and mathematical problems. Your first paragraph seems to mix the two together. 2-body, 3-body, n-body problems are mathematical problems and have mathematical solutions, and orbits that are mathematically unstable can still be periodic and not chaotic. "Unstable" refers to what would happen if the system were pertubed in a defined way, not what would happen if you just watch it for a long time. In the real world however, gravity is a long range force and orbits are always perturbed, and approximated. $\endgroup$
    – uhoh
    Commented Sep 2, 2016 at 4:10
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    $\begingroup$ @uhoh I'll think about how to do that, but I'm not sure I can. Real orbits with n bodys even in stable systems like our solar system gets complicated. Newton couldn't work it out. Lapace worked it out, at least, partially, but not completely about a century later. It's probably over my pay grade to try to explain it. Intuitively I can work it out that within a sphere of influence, orbits are basically Keplerian, but explaining it in the way you ask, I'm not sure I can. But I'll give it some thought on how to reword. $\endgroup$
    – userLTK
    Commented Sep 2, 2016 at 4:27
  • $\begingroup$ I like your answer, but it looks like this question is about the mathematical 3-body problem, not one in the "real world" were everything is pulling on everything, and you have to attach a timescale when talking about how stable or unstable an orbit is. Just look at the solar system. No orbit is exactly periodic, even though on the time scale of say one million years, many of them are quite reliably stable. $\endgroup$
    – uhoh
    Commented Sep 2, 2016 at 4:40
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    $\begingroup$ The figure eight orbit depicted in the question appears to be KAM-stable. See scholarpedia.org/article/N-body_choreographies . $\endgroup$ Commented Sep 2, 2016 at 14:03

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