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It is really a very nice solution Orodruin! Thanks to you and to Haruspex. And I agree that the problem was not intended to be so hard.
ehild
ehild
Orodruin said:I agree this was probably not what the problem maker had in mind, but as stated it is what comes out of the problem.
As a curiosity, projected onto a plane with constant z, the path taken by any of the ants is going to be a logarithmic spiral with a 45 degree angle to the radius at any point.
@Satvik: Where was this problem taken from?
It is natural to try to extend such into three dimensions, but I cannot think of a set up in which the full symmetry will be preserved. Seems to me that the initial circuit will always tend to flatten out.Satvik Pandey said:I have solved questions in which particles moves towards each other located at the vertices of equilateral triangle,hexagon and other 2D shapes.
ehild said:The radius of the triangle gets shorter by vcos(30)dt , and it turns by the angle dψ = (vsin(30) dt )/r .
ehild
Orodruin said:No, r also gets smaller by an infinitesimal amount. It is the corresponding equations in three dimensions that need to be solved to find the solution to your original problem. The difference is that the shape of the original object will change in 3D.
Orodruin said:Yes, the velocity is v sinθ. So the distance (in the tangential direction) traveled in a short time dt is going to be v sinθ dt. However, this distance can also be written r dψ as this is the distance you move if you change the polar coordinate ψ by dψ. Thus
r dψ = v sinθ dt
dψ = v sinθ dt/r
This is what you wrote earlier, but it does not imply that r is constant.
Orodruin said:Why do you think we are treating it as constant? The equation states the relation between an infinitesimal change in time and an infinitesimal change in ψ. In a similar way you can write down the corresponding equation for dr and you will end up with a set of two coupled differential equations.