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Please imagine that we have a circular segment with some arc length 's' and chord length 'a' (using notation from http://mathworld.wolfram.com/CircularSegment.html).

Provided only 'a' and 's', and placing the left-hand-side point of the chord at the origin of the Euclidean plane (or a more convenient point), is there sufficient information to write an expression for the height of the circular segment (i.e. the y-axis/"vertical" distance between the chord on the x-axis and the circular arc) as a function of a position on the chord?

It's a simple matter to express the chord length in terms of the arc length and theta: $a = (s) * 2\frac{\sin(\frac{\theta}{2})}{\theta}$, or an expression for the arc length in terms of the chord length and theta: $s = \frac{a\theta}{2\sin\frac{\theta}{2}}$. And one can write an express for the maximum height as: $h = R - \frac{1}{2}\sqrt{(-a)^2+4R^2}$, where the radius of the circle, 'R' is related to theta as: $R = \frac{1}{2} \sqrt{\frac{a^2}{\cos^2\frac{\theta}{2}-1}}$.

If there is insufficient information to accomplish the above, I would love to have an intuitive explanation for why this is so.

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    J.M., the constant curvature point was$a$point about intuition not intended as a further restriction...2010-11-01

1 Answers 1

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Using the notation of the figure you have linked to, we have

\begin{equation} R \sin \frac{\theta}{2} = \frac{a}{2} \end{equation}

we can also write

\begin{equation} \theta = \frac{s}{R} = \frac{2 s \sin \theta/2}{a} \end{equation}

From this equation, you can solve for $\theta$.

Once you have solved for $\theta$, you have

\begin{equation} h = R - R \cos(\theta/2) \end{equation}

Since $R = a/(2 \sin \theta/2)$, we have

\begin{equation} h = \frac{a}{2 \sin \theta/2} \left( 1 - \cos\left(\frac{s \sin\theta/2}{a}\right)\right) \end{equation}

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    @rumtscho - You would have to solve for $\theta$ using the equation $\theta = \frac{2s \sin \theta/2}{a}$. $s$ and $a$ are known. You would solve for $\theta$ numerically in general.2011-02-09