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When solving the brachistochrone problem (path of least time for a mass sliding on the path, with the path having no friction, from point A to point B), the solution curves are solved from the following equation (see for example https://www.youtube.com/watch?v=zYOAUG8PxyM&t=587s):

$$ x - x_0 = \int_{y_0}^y \sqrt{\frac{y_0 - y}{C - (y_0 - y)}} dy $$

Here $ (x_0, y_0) $ is the starting position of the mass and $C$ is a constant which satisfies the end position $ (x_1, y_1) $. Typically this equation is solved analytically by the help of new variable $\theta$, but I'm interested in solving it numerically, as I'm trying to later solve harder versions of the brachistochrone problem which are not solvable analytically and I'm practising on this easier case first.

The brachistochrone curve is one that not only goes down but also comes up. This seems like a problem for me, because when you look at the equation above, the right-hand side always gets same value for any given value of $\textbf{y}$. If we take two points of brachistochrone curve which have the same y-value but different x-values (figure below), then for these points the right-hand side of the equation is the same but left-hand side isn't, which is a contradiction. Where am I making a mistake?

enter image description here

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  • $\begingroup$ Why do you expect different values of y to give the same value for x? You need to change C for that to be true. $\endgroup$
    – Boba Fit
    Commented Jan 3, 2023 at 13:34
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    $\begingroup$ You got x and y mixed up, but anyways as you can see in the picture above, points for which y is the same and x is different exist. And if I have understood correctly, C is a constant that I cannot change for different points $\endgroup$ Commented Jan 3, 2023 at 13:55
  • $\begingroup$ Related : What is the position as a function of time for a mass falling down a cycloid curve?. $\endgroup$
    – Voulkos
    Commented Jan 3, 2023 at 14:38

2 Answers 2

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I would leave a comment if I could, but I have to answer since I don't have enough reputation.

I didn't look closely into the calculations, but it seems to me like this might be the kind of problem you could encounter if you happen to treat integrals too lightheartedly: the problem of the brachistochrone is formulated in terms of the arch length, and you have to change variables in order to get a relation between $x$ and $y$. We don't usually worry much about changing variables, since we usually use the following formula: $$ \int_a^bf(\varphi(x))\varphi'(x)dx=\int_{\varphi(a)}^{\varphi(b)}f(t)dt, $$ but we might want to force a substitution this way: $$ \int_c^df(t)dt=\int_{\varphi^{-1}(c)}^{\varphi^{-1}(d)}f(\varphi(x))\varphi'(x)dx, $$ in which case, you can see that it becomes important whether $\varphi$ is injective or not: $\varphi^{-1}$ might not be a well defined function! I believe the video you saw might have skipped this consideration for the sake of simplicity (the search for a general solution paradoxically leaves you more freedom in taking assumptions on the details of your problem than the specific problem itself).

Hope this helps! Cheers! :)

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    $\begingroup$ I think this solves my problem, I just have to look into how this applies in my specific case (I remember that we had that equation in multvariable calc, but I'm bit rusty on that :D). If anyone wants to help me by transforming the integral at hand, it would be appriciated! $\endgroup$ Commented Jan 3, 2023 at 16:01
  • $\begingroup$ Wonderful! If this actually turns out to solve your problem, feel free to mark the answer as accepted and give it an upvote! I'd love to help you out with the calculations, but that wouldn't be soon since I'm pretty busy in this period $\endgroup$ Commented Jan 3, 2023 at 22:12
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As the previous answer suggests, the problem lies with the fact that the y isn't an injection and thus integrating over it gives rise to the problem. I solved this by splitting the integral to two parts (from $y_0$ to $y_{min}$ and from $y_{min}$ to $y$). I found the lowest y-value $y_{min}$ numerically. Credit goes to the previous answer, as he helped me realize the right way to treat this problem.

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