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Not really. You're coarse graining either way, it's just a matter of feature selection and atomicity. But more relevantly, my point was that the only reason we don't experience things like the "chaos" of celestial bodies smashing into one another on earth is because, well...it's earth. There's only one celestial body here, and that's earth.
That's sort of the point. The collisions referred to (asteroids) only seem chaotic because they are big and because the truly chaotic behavior of systems occurs at smaller (human) scales. You can of course look inside stellar structures and so forth and talk about the many-body problem for solids in general or the subatomic constituents of asteroids and again find that you need trillions upon trillions of equations, but that's unnecessary. We can obtain great accuracy when it comes to celestial bodies if we treat them as point particles (often simply by using the center of mass as the "point"). Doing the same with liquids or gases fails completely and thus we can only ever hope to approximate the behavior of such systems using statistical mechanics.
There are in general infinitely many solutions to most systems of equations that have a solution (a golden rule in linear algebra, if you recall, is that if there is a solution then either there is only one or there are infinitely many; things mostly stay the same with differential equations except that the nature of the solution spaces changes dramatically as do the characteristics of the systems). In general, none of the n-body problems have solutions when n is greater than 2. However, this is because the equations don't have closed for analytical solutions in that you can't simply take antiderivatives (indefinite integrals) and solve for arbitrary constants- you need initial conditions and a picture of the system in order to determine how to solve it (or to approximate a solution) by e.g., exploiting symmetries. The three-body problem is special because it is easy to visualize and because there aren't really any mathematical difficulties encountered in e.g., 60-body problems or 100-body problems that aren't already present in the three-body problem. The difference as N increases is that the complexity becomes so great that the approximation schemes (numerical solutions) which work in the three-body case begin to fail and better methods are required. Also, celestial mechanics present special cases precisely because the interactions among bodies are all related to the gravitational force when more generally you have to take into account e.g., electromagnetic forces and in particular collisions. Orbits are relatively easy. Sand, dust, water, gas, cells, etc., are hard or impossible on an entirely different level.
You can't apply laws which are intended for idealized isolated systems to the universe, which is neither closed nor isolated in the sense used in thermodynamics and physics more generally (no matter what popular science/pseudoscience sources say on the matter). Also, note that these conservation laws are actually used more like principles. They are violated constantly in particle physics (and thus for every system) but in ways that we allow for because we speak of such violations in terms of virtual particles and relate them inversely to the time periods over which mass or energy conservation is violated. When this doesn't work either, we infer the existence of particles we can't detect but that should be there because mass or energy conservation was violated. Finally, even well-informed writers will often make claims about what must be true about e.g., consciousness or the mind or the universe as a whole based upon conservation of energy when in fact this is incorrect. Energy conservation is a consequence of Noether's theorem and certain symmetries and thus is conserved in any system in which it is well-defined and (correspondingly) cannot be used in principle where it is not well-defined.
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I was addressing the claim that the universe is some how chaotic because of things like asteroid collisions and so forth and thus somehow also chaotic in a manner that we don't find on human scales. We do. We're enveloped by massive numbers of higher energy collisions in the most complex, chaotic systems we've ever found. They just don't look as impressive to you.
I AM talking on a human scale, and having worked on modeling chaotic systems for most of my career it isn't easy in the slightest. A memorable quote from the first text I used devoted to the kind of complexities found in ordinary sand and similar materials:
We have to simplify models of sandpiles and similar media under the influence of wind and/or water in order to make them simple enough for the "complexities" of systems of celestial bodies. We can't simplify most of the phenomena we experience daily enough to make them simple enough to apply to the simplicities of planetary trajectories, asteroids, and whatnot. If you mean we don't experience the "chaos" of asteroids other celestial bodies because they are too big, then naturally they are not noticeable on a human scale without telescopes and other technology. If you mean, however, that such things are complex and/or chaotic compared to what we do experience on a human scale, then again there isn't really anything to bear this out. We haven't encountered anything in astrophysics that would compare to the complexities and chaos of systems you experience daily.
The universe in early times had a high degree of order and is currently moving towards a more chaotic state.