Casey's theorem

In mathematics, Casey's theorem, also known as the generalized Ptolemy's theorem, is a theorem in Euclidean geometry named after the Irish mathematician John Casey.

Note that in the degenerate case, where all four circles reduce to points, this is exactly Ptolemy's theorem.

${\displaystyle t_{12}\cdot t_{34}+t_{14}\cdot t_{23}=t_{13}\cdot t_{24}.}$

The following proof is attributable^[1] to Zacharias.^[2] Denote the radius of circle ${\displaystyle O_i}$ by ${\displaystyle R_i}$ and its tangency point with the circle ${\displaystyle O}$ by ${\displaystyle K_i}$. We will use the notation ${\displaystyle O,O_i}$ for the centers of the circles. Note that from Pythagorean theorem,

${\displaystyle t_{ij}^2=\stackrel{2}{\stackrel{‾}{O_i{O}_j}}-(R_i-R_j{)}^2.}$

${\displaystyle \stackrel{2}{\stackrel{‾}{O_i{O}_j}}=\stackrel{2}{\stackrel{‾}{O{O}_i}}+\stackrel{2}{\stackrel{‾}{O{O}_j}}-2\overline{O{O}_i}\cdot \overline{O{O}_j}\cdot \cos \mathrm{\angle }{O}_{i}O{O}_j}$

Since the circles ${\displaystyle O,O_i}$ tangent to each other:

${\displaystyle \overline{O{O}_i}=R-R_i,\mathrm{\angle }{O}_{i}O{O}_j=\mathrm{\angle }{K}_{i}O{K}_j}$

Let ${\displaystyle C}$ be a point on the circle ${\displaystyle O}$. According to the law of sines in triangle ${\displaystyle K_{i}C{K}_j}$:

${\displaystyle \overline{K_i{K}_j}=2R\cdot \sin \mathrm{\angle }{K}_{i}C{K}_j=2R\cdot \sin \frac{\mathrm{\angle }{K}_{i}O{K}_j}{2}}$

Therefore,

${\displaystyle \cos \mathrm{\angle }{K}_{i}O{K}_j=1-2{\sin }^2\frac{\mathrm{\angle }{K}_{i}O{K}_j}{2}=1-2\cdot {\left(\frac{\overline{K_i{K}_j}}{2R}\right)}^2=1-\frac{\stackrel{2}{\stackrel{‾}{K_i{K}_j}}}{2R^2}}$

and substituting these in the formula above:

${\displaystyle \stackrel{2}{\stackrel{‾}{O_i{O}_j}}=(R-R_i{)}^2+(R-R_j{)}^2-2(R-R_i)(R-R_j)(1-\frac{\stackrel{2}{\stackrel{‾}{K_i{K}_j}}}{2R^2})}$

${\displaystyle \stackrel{2}{\stackrel{‾}{O_i{O}_j}}=(R-R_i{)}^2+(R-R_j{)}^2-2(R-R_i)(R-R_j)+(R-R_i)(R-R_j)\cdot \frac{\stackrel{2}{\stackrel{‾}{K_i{K}_j}}}{R^2}}$

${\displaystyle \stackrel{2}{\stackrel{‾}{O_i{O}_j}}=((R-R_i)-(R-R_j){)}^2+(R-R_i)(R-R_j)\cdot \frac{\stackrel{2}{\stackrel{‾}{K_i{K}_j}}}{R^2}}$

And finally, the length we seek is

${\displaystyle t_{ij}=\sqrt{\stackrel{2}{\stackrel{‾}{O_i{O}_j}}-(R_i-R_j{)}^2}=\frac{\sqrt{R-R_i}\cdot \sqrt{R-R_j}\cdot \overline{K_i{K}_j}}{R}}$

We can now evaluate the left hand side, with the help of the original Ptolemy's theorem applied to the inscribed quadrilateral ${\displaystyle K_1{K}_2{K}_3{K}_4}$:

${\displaystyle \begin{array}{cc}& t_{12}{t}_{34}+t_{14}{t}_{23}\\ =& \frac{1}{R^2}\cdot \sqrt{R-R_1}\sqrt{R-R_2}\sqrt{R-R_3}\sqrt{R-R_4}(\overline{K_1{K}_2}\cdot \overline{K_3{K}_4}+\overline{K_1{K}_4}\cdot \overline{K_2{K}_3})\\ =& \frac{1}{R^2}\cdot \sqrt{R-R_1}\sqrt{R-R_2}\sqrt{R-R_3}\sqrt{R-R_4}(\overline{K_1{K}_3}\cdot \overline{K_2{K}_4})\\ =& t_{13}{t}_{24}\end{array}}$

It can be seen that the four circles need not lie inside the big circle. In fact, they may be tangent to it from the outside as well. In that case, the following change should be made:^[3]

If ${\displaystyle O_i,O_j}$ are both tangent from the same side of ${\displaystyle O}$ (both in or both out), ${\displaystyle t_{ij}}$ is the length of the exterior common tangent.

If ${\displaystyle O_i,O_j}$ are tangent from different sides of ${\displaystyle O}$ (one in and one out), ${\displaystyle t_{ij}}$ is the length of the interior common tangent.

The converse of Casey's theorem is also true.^[3] That is, if equality holds, the circles are tangent to a common circle.

Casey's theorem and its converse can be used to prove a variety of statements in Euclidean geometry. For example, the shortest known proof^[4]: 411 of Feuerbach's theorem uses the converse theorem.

• Lua error in Module:Citation/CS1/Configuration at line 2172: attempt to index field '?' (a nil value).
• Shailesh Shirali: "'On a generalized Ptolemy Theorem'". In: Crux Mathematicorum, Vol. 22, No. 2, pp. 49-53