# Is the area of a polygonal linkage maximized by having all vertices on a circle?

Consider a (non-stellated) polygon in the plane. Imagine that the edges are rigid, but that the vertices consist of flexible joints. That is, one is allowed to move the polygon around in such a way that the vertices stay a fixed distance from their adjacent neighbors. Such a system is called a polygonal linkage.

As the linkage varies in its embedding in the plane, the area of the interior varies. The question is, When is the area maximized?

I have a specific answer I suspect is correct, but I am having trouble showing. I believe it is true that every polygonal linkage has as embedding where all the vertices lie on one circle (this isn't hard to show in the case when the linkage starts non-stellated). My claim is that the area is maximized exactly when all the vertices lie on a circle.

I can show this for a 4-sided polygon, but with techniques that do not generalize.

Also, my requirement that the polygon be non-stellated was only so that it was clear that there was a way to flex it to have all vertices on a circle. This question extends to the stellated case, but the question there is whether every stellated linkage can be flexed to one which is non-stellated.

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Could you sketch your argument in the quadrilateral case? – Steven Gubkin Apr 27 '10 at 19:58
Since this question has been answered positively, the following one is natural: How does one compute the radius of the circle with an inscribed maximal solution? This radius is clearly a symmetric function of the lengths. Equivalently, given n strictly positive real numbers $l_1,...,l_n$ such that $2\max(l_1,...,l_n)<l_1+...+l_n$, compute the radius $\rho$ such that one can inscribe a polygon with $n$ sides of length $l_1,\dots,l_n$ inside a circle of radius $\rho$. – Roland Bacher Apr 28 '10 at 8:02
From a computational point of view, the following sequence converges fairly quickly to the correct value $\rho$ of the radius of the circle with maximal inscribed solution. Set $\rho_0=1/(2\pi)\sum_{i=1}^n l_i$ (where $l_1,\dots,l_n$ are the lengths) and define $\rho_1,\rho_2$ recursively by $\rho_{m+1}=1/\pi\sum_{i=1}^n\mathop{arcsin}(l_i/(2\rho_m))$. – Roland Bacher Apr 28 '10 at 11:39

This is a theorem of Cramer. See here

For the quadrilateral case the quickest proof is using Brahmagupta's formula

$$Area=\sqrt{(s-a)(s-b)(s-c)(s-d)-abcd\cos^2 \theta}$$ where $a,b,c,d$ are the sides, $s$ is the half perimeter and $\theta$ is half the sum of opposite angles.

Edit: I wonder if this argument works: Pick four consecutive vertices and move the linkage made of these four vertices till it's cyclic. There will be a subsequence of the polygons we get after such operations which converges, by the Weierstrass theorem. In the limit the polygon will be cyclic otherwise you can find four consecutive vertices not on a circle and increase the area again.

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If you can show it for a quadrilateral, then it is true in general.

Proof Sketch: by induction on the number of sides. The base case is $n=4$, which you say you have done. Let $X$ be the set of joints. By a compactness argument, the maximum is achieved; pick a particular placement which achieves the maximum.

Consider a new linkage $X'$ with $n-1$ vertices. The distance between $x'_i$ and $x'_{i+1}$ is the same as that between $x_i$ and $x_{i+1}$; the distance between $x'_1$ and $x'_{n-1}$ is the same as the distance between $x_1$ and $x_{n-1}$ in the chosen optimal placement. Then the chosen placement of the $x_i$'s must also be an optimal placement of the $x'_i$'s; if not, we could keep $(x_1, x_{n-1}, x_n)$ in the same place and move the other $x_j$'s to a better placement for linkage $X'$, obtaining a better placement of $X$.

By induction, we see that $\{ x_1, x_2, \ldots, x_{n-1} \}$ lie on a circle. But the same applies to any index, so $X \setminus \{ x_i \}$ lies on a circle $C_i$ for any $i$. We see that $C_i$ and $C_j$ have $n-2$ points in common so (for $n>4$) they must be the same circle. So all the points lie on a circle.

As regards your other question, as to whether every closed linkage to be unfolded to lie on a circle, I believe the answer is also yes. Let $d_1$, $d_2$, ..., $d_n$ be the lengths of the sides. Without loss of generality, let $d_n = \max(d_i)$. Since your linkage closes, we have $d_n < \sum_{i <n} d_i$ by the triangle inequality.

Consider the function $f(R) = \sum 2 \sin^{-1}(d_i/(2R))$. When $R=d_n/2$, all the inverse sines are defined, and we have $$f(R) > \pi + 2 \sin^{-1} (\sum_{i<n} d_i/d_n) \geq 2 \pi,$$ where we have used the inequality $\sin^{-1}(x) + \sin^{-1}(y) \geq \sin^{-1}(x+y)$, following from the convexity of $\sin^{-1}$.

As $R$ goes to infinity, $f(R)$ goes to $0$. By the intermediate value theorem, $f(R)$ is $2 \pi$ somewhere; your linkage can be unfolded onto a circle of this radus $R$.

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+1, you beat me to the induction proof :) – Gjergji Zaimi Apr 27 '10 at 20:35
I just realized that I may have misunderstood the question in the second part: I prove that there is a way to place the points on a circle so they are at the requisite distances, but I don't show that, from some other placement, you can get to the circular placement by a continuous motion. I have a nagging suspicion that the intent was to ask about the latter question, to which I don't know the answer. – David Speyer Apr 27 '10 at 20:51
Well from the work of Conelly, Demaine and Rote mentioned below one can always convexify a linkage. Why not use induction to place all vertices but one on a circle and then "push" the remaining vertex towards the circle? (this is really sketchy..) – Gjergji Zaimi Apr 27 '10 at 21:11

A theorem of Connelly, Demaine, and Rote shows that a variety of plane linkages can be convexified or straightened:

Here is a general way to think about these kind of problems. The Minkowski theorem says that a polytope is uniquely determined by its normals and volumes of the facets. You can loose some of these conditions and ask for the optimum isoperimetric ratio. In this case, in $\Bbb R^2$ you forget normals and conclude that inscribed polygon with given side lengths is optimal. A classical Lindelöf theorem does the opposite: in $\Bbb R^d$, it says that the optimal polytope with prescribed normals are circumscribed around the sphere (see e.g. here, Section 18.3).
There's a simple argument showing that from the quadrilateral case we can easily deduce the $n$-vertex case (at least in the convex case). We claim that in any configuration locally maximizing the area the vertices are concyclic. Take any four consectutive vertices $A$, $B$, $C$ and $D$. Then in at a local maximum of area $A$, $B$, $C$ and $D$ are concyclic lest we could raise the area by moving the edges $AB$, $BC$ and $CD$ (by the quadrilateral case). Hence the circumcircles of $ABC$ and $BCD$ coincide. So all the circumcircles of three consecutive vertices are the same circle: the vertices are concyclic.