In Euclidean geometry, Ptolemy's theorem is a relation between the four sides and two diagonals of a cyclic quadrilateral (a quadrilateral whose vertices lie on a common circle). The theorem is named after the Greek astronomer and mathematician Ptolemy (Claudius Ptolemaeus).^[1] Ptolemy used the theorem as an aid to creating his table of chords, a trigonometric table that he applied to astronomy.

If the vertices of the cyclic quadrilateral are A, B, C, and D in order, then the theorem states that:

${\displaystyle AC\cdot BD=AB\cdot CD+BC\cdot AD}$

This relation may be verbally expressed as follows:

If a quadrilateral is cyclic then the product of the lengths of its diagonals is equal to the sum of the products of the lengths of the pairs of opposite sides.

Moreover, the converse of Ptolemy's theorem is also true:

In a quadrilateral, if the sum of the products of the lengths of its two pairs of opposite sides is equal to the product of the lengths of its diagonals, then the quadrilateral can be inscribed in a circle i.e. it is a cyclic quadrilateral.

Ptolemy's Theorem yields as a corollary a pretty theorem^[2] regarding an equilateral triangle inscribed in a circle.

Given An equilateral triangle inscribed on a circle and a point on the circle.

The distance from the point to the most distant vertex of the triangle is the sum of the distances from the point to the two nearer vertices.

Proof: Follows immediately from Ptolemy's theorem:

${\displaystyle qs=ps+rs\Rightarrow q=p+r.}$

Any square can be inscribed in a circle whose center is the center of the square. If the common length of its four sides is equal to ${\displaystyle a}$ then the length of the diagonal is equal to ${\displaystyle a{\sqrt {2}}}$ according to the Pythagorean theorem, and Ptolemy's relation obviously holds.

More generally, if the quadrilateral is a rectangle with sides a and b and diagonal d then Ptolemy's theorem reduces to the Pythagorean theorem. In this case the center of the circle coincides with the point of intersection of the diagonals. The product of the diagonals is then d², the right hand side of Ptolemy's relation is the sum a² + b².

Copernicus – who used Ptolemy's theorem extensively in his trigonometrical work – refers to this result as a 'Porism' or self-evident corollary:

Furthermore it is clear (manifestum est) that when the chord subtending an arc has been given, that chord too can be found which subtends the rest of the semicircle.^[3]

A more interesting example is the relation between the length a of the side and the (common) length b of the 5 chords in a regular pentagon. By completing the square, the relation yields the golden ratio:^[4]

${\displaystyle {\begin{array}{rl}b\cdot b\,\;\;\qquad \quad \qquad =&\!\!\!\!a\!\cdot \!a+a\!\cdot \!b\\b^{2}\;\;-ab\quad \qquad =&\!\!a^{2}\\{\frac {b^{2}}{a^{2}}}\;\;-{\frac {ab}{a^{2}}}\;\;\;\qquad =&\!\!\!{\frac {a^{2}}{a^{2}}}\\\left({\frac {b}{a}}\right)^{2}-{\frac {b}{a}}+\left({\frac {1}{2}}\right)^{2}=&\!\!1+\left({\frac {1}{2}}\right)^{2}\\\left({\frac {b}{a}}-{\frac {1}{2}}\right)^{2}=&\!\!\quad {\frac {5}{4}}\\{\frac {b}{a}}-{\frac {1}{2}}\;\;\;=&\!\!\!\!\pm {\frac {\sqrt {5}}{2}}\\{\frac {b}{a}}>0\,\Rightarrow \,\varphi ={\frac {b}{a}}=&\!\!\!\!{\frac {1+{\sqrt {5}}}{2}}\end{array}}}$

If now diameter AF is drawn bisecting DC so that DF and CF are sides c of an inscribed decagon, Ptolemy's Theorem can again be applied – this time to cyclic quadrilateral ADFC with diameter d as one of its diagonals:

${\displaystyle ad=2bc}$

${\displaystyle \Rightarrow ad=2\varphi ac}$ where ${\displaystyle \varphi }$ is the golden ratio.

${\displaystyle \Rightarrow c={\frac {d}{2\varphi }}.}$^[5]

whence the side of the inscribed decagon is obtained in terms of the circle diameter. Pythagoras's theorem applied to right triangle AFD then yields "b" in terms of the diameter and "a" the side of the pentagon ^[6] is thereafter calculated as

${\displaystyle a={\frac {b}{\varphi }}=b\left(\varphi -1\right).}$

As Copernicus (following Ptolemy) wrote,

"The diameter of a circle being given, the sides of the triangle, tetragon, pentagon, hexagon and decagon, which the same circle circumscribes, are also given."^[7]

The animation here shows a visual demonstration of Ptolemy's theorem, based on Derrick & Herstein (2012).^[8]

Let ABCD be a cyclic quadrilateral. On the chord BC, the inscribed angles ∠BAC = ∠BDC, and on AB, ∠ADB = ∠ACB. Construct K on AC such that ∠ABK = ∠CBD; since ∠ABK + ∠CBK = ∠ABC = ∠CBD + ∠ABD, ∠CBK = ∠ABD.

Now, by common angles △ABK is similar to △DBC, and likewise △ABD is similar to △KBC. Thus AK/AB = CD/BD, and CK/BC = DA/BD; equivalently, AK⋅BD = AB⋅CD, and CK⋅BD = BC⋅DA. By adding two equalities we have AK⋅BD + CK⋅BD = AB⋅CD + BC⋅DA, and factorizing this gives (AK+CK)·BD = AB⋅CD + BC⋅DA. But AK+CK = AC, so AC⋅BD = AB⋅CD + BC⋅DA, Q.E.D.^[9]

The proof as written is only valid for simple cyclic quadrilaterals. If the quadrilateral is self-crossing then K will be located outside the line segment AC. But in this case, AK−CK = ±AC, giving the expected result.

Let the inscribed angles subtended by ${\displaystyle AB}$, ${\displaystyle BC}$ and ${\displaystyle CD}$ be, respectively, ${\displaystyle \alpha }$, ${\displaystyle \beta }$ and ${\displaystyle \gamma }$, and the radius of the circle be ${\displaystyle R}$, then we have ${\displaystyle AB=2R\sin \alpha }$, ${\displaystyle BC=2R\sin \beta }$, ${\displaystyle CD=2R\sin \gamma }$, ${\displaystyle AD=2R\sin(180^{\circ }-(\alpha +\beta +\gamma ))}$, ${\displaystyle AC=2R\sin(\alpha +\beta )}$ and ${\displaystyle BD=2R\sin(\beta +\gamma )}$, and the original equality to be proved is transformed to

${\displaystyle \sin(\alpha +\beta )\sin(\beta +\gamma )=\sin \alpha \sin \gamma +\sin \beta \sin(\alpha +\beta +\gamma )}$

from which the factor ${\displaystyle 4R^{2}}$ has disappeared by dividing both sides of the equation by it.

Now by using the sum formulae, ${\displaystyle \sin(x+y)=\sin {x}\cos y+\cos x\sin y}$ and ${\displaystyle \cos(x+y)=\cos x\cos y-\sin x\sin y}$, it is trivial to show that both sides of the above equation are equal to

${\displaystyle {\begin{aligned}&\sin \alpha \sin \beta \cos \beta \cos \gamma +\sin \alpha \cos ^{2}\beta \sin \gamma \\+{}&\cos \alpha \sin ^{2}\beta \cos \gamma +\cos \alpha \sin \beta \cos \beta \sin \gamma .\end{aligned}}}$

Q.E.D.

Here is another, perhaps more transparent, proof using rudimentary trigonometry. Define a new quadrilateral ${\displaystyle ABCD'}$ inscribed in the same circle, where ${\displaystyle A,B,C}$ are the same as in ${\displaystyle ABCD}$, and ${\displaystyle D'}$ located at a new point on the same circle, defined by ${\displaystyle |{\overline {AD'}}|=|{\overline {CD}}|}$, ${\displaystyle |{\overline {CD'}}|=|{\overline {AD}}|}$. (Picture triangle ${\displaystyle ACD}$ flipped, so that vertex ${\displaystyle C}$ moves to vertex ${\displaystyle A}$ and vertex ${\displaystyle A}$ moves to vertex ${\displaystyle C}$. Vertex ${\displaystyle D}$ will now be located at a new point D’ on the circle.) Then, ${\displaystyle ABCD'}$ has the same edges lengths, and consequently the same inscribed angles subtended by the corresponding edges, as ${\displaystyle ABCD}$, only in a different order. That is, ${\displaystyle \alpha }$, ${\displaystyle \beta }$ and ${\displaystyle \gamma }$, for, respectively, ${\displaystyle AB,BC}$ and ${\displaystyle AD'}$. Also, ${\displaystyle ABCD}$ and ${\displaystyle ABCD'}$ have the same area. Then,

${\displaystyle {\begin{aligned}\mathrm {Area} (ABCD)&={\frac {1}{2}}AC\cdot BD\cdot \sin(\alpha +\gamma );\\\mathrm {Area} (ABCD')&={\frac {1}{2}}AB\cdot AD'\cdot \sin(180^{\circ }-\alpha -\gamma )+{\frac {1}{2}}BC\cdot CD'\cdot \sin(\alpha +\gamma )\\&={\frac {1}{2}}(AB\cdot CD+BC\cdot AD)\cdot \sin(\alpha +\gamma ).\end{aligned}}}$

Q.E.D.

Choose an auxiliary circle ${\displaystyle \Gamma }$ of radius ${\displaystyle r}$ centered at D with respect to which the circumcircle of ABCD is inverted into a line (see figure). Then ${\displaystyle A'B'+B'C'=A'C'.}$ Then ${\displaystyle A'B',B'C'}$ and ${\displaystyle A'C'}$ can be expressed as ${\textstyle {\frac {AB\cdot DB'}{DA}}}$, ${\textstyle {\frac {BC\cdot DB'}{DC}}}$ and ${\textstyle {\frac {AC\cdot DC'}{DA}}}$ respectively. Multiplying each term by ${\textstyle {\frac {DA\cdot DC}{DB'}}}$ and using ${\textstyle {\frac {DC'}{DB'}}={\frac {DB}{DC}}}$ yields Ptolemy's equality.

Q.E.D.

Note that if the quadrilateral is not cyclic then A', B' and C' form a triangle and hence A'B'+B'C' > A'C', giving us a very simple proof of Ptolemy's Inequality which is presented below.

Embed ABCD in the complex plane ${\displaystyle \mathbb {C} }$ by identifying ${\displaystyle A\mapsto z_{A},\ldots ,D\mapsto z_{D}}$ as four distinct complex numbers ${\displaystyle z_{A},\ldots ,z_{D}\in \mathbb {C} }$. Define the cross-ratio

${\displaystyle \zeta :={\frac {(z_{A}-z_{B})(z_{C}-z_{D})}{(z_{A}-z_{D})(z_{B}-z_{C})}}\in \mathbb {C} _{\neq 0}}$.

Then

${\displaystyle {\begin{aligned}{\overline {AB}}\cdot {\overline {CD}}+{\overline {AD}}\cdot {\overline {BC}}&=\left|z_{A}-z_{B}\right|\left|z_{C}-z_{D}\right|+\left|z_{A}-z_{D}\right|\left|z_{B}-z_{C}\right|\\&=\left|(z_{A}-z_{B})(z_{C}-z_{D})\right|+\left|(z_{A}-z_{D})(z_{B}-z_{C})\right|\\&=\left(\left|{\frac {(z_{A}-z_{B})(z_{C}-z_{D})}{(z_{A}-z_{D})(z_{B}-z_{C})}}\right|+1\right)\left|(z_{A}-z_{D})(z_{B}-z_{C})\right|\\&=\left(\left|\zeta \right|+1\right)\left|(z_{A}-z_{D})(z_{B}-z_{C})\right|\\&\geq \left|(\zeta +1)(z_{A}-z_{D})(z_{B}-z_{C})\right|\\&=\left|(z_{A}-z_{B})(z_{C}-z_{D})+(z_{A}-z_{D})(z_{B}-z_{C})\right|\\&=\left|(z_{A}-z_{C})(z_{B}-z_{D})\right|\\&=\left|z_{A}-z_{C}\right|\left|z_{B}-z_{D}\right|\\&={\overline {AC}}\cdot {\overline {BD}}\end{aligned}}}$

with equality if and only if the cross-ratio ${\displaystyle \zeta }$ is a positive real number. This proves Ptolemy's inequality generally, as it remains only to show that ${\displaystyle z_{A},\ldots ,z_{D}}$ lie consecutively arranged on a circle (possibly of infinite radius, i.e. a line) in ${\displaystyle \mathbb {C} }$ if and only if ${\displaystyle \zeta \in \mathbb {R} _{>0}}$.

From the polar form of a complex number ${\displaystyle z=\vert z\vert e^{i\arg(z)}}$, it follows

${\displaystyle {\begin{aligned}\arg(\zeta )&=\arg {\frac {(z_{A}-z_{B})(z_{C}-z_{D})}{(z_{A}-z_{D})(z_{B}-z_{C})}}\\&=\arg(z_{A}-z_{B})+\arg(z_{C}-z_{D})-\arg(z_{A}-z_{D})-\arg(z_{B}-z_{C}){\pmod {2\pi }}\\&=\arg(z_{A}-z_{B})+\arg(z_{C}-z_{D})-\arg(z_{A}-z_{D})-\arg(z_{C}-z_{B})-\arg(-1){\pmod {2\pi }}\\&=-\left[\arg(z_{C}-z_{B})-\arg(z_{A}-z_{B})\right]-\left[\arg(z_{A}-z_{D})-\arg(z_{C}-z_{D})\right]-\arg(-1){\pmod {2\pi }}\\&=-\angle ABC-\angle CDA-\pi {\pmod {2\pi }}\\&=0\end{aligned}}}$

with the last equality holding if and only if ABCD is cyclic, since a quadrilateral is cyclic if and only if opposite angles sum to ${\displaystyle \pi }$.

Q.E.D.

Note that this proof is equivalently made by observing that the cyclicity of ABCD, i.e. the supplementarity ${\displaystyle \angle ABC}$ and ${\displaystyle \angle CDA}$, is equivalent to the condition

${\displaystyle \arg \left[(z_{A}-z_{B})(z_{C}-z_{D})\right]=\arg \left[(z_{A}-z_{D})(z_{B}-z_{C})\right]=\arg \left[(z_{A}-z_{C})(z_{B}-z_{D})\right]{\pmod {2\pi }}}$;

in particular there is a rotation of ${\displaystyle \mathbb {C} }$ in which this ${\displaystyle \arg }$ is 0 (i.e. all three products are positive real numbers), and by which Ptolemy's theorem

${\displaystyle {\overline {AB}}\cdot {\overline {CD}}+{\overline {AD}}\cdot {\overline {BC}}={\overline {AC}}\cdot {\overline {BD}}}$

is then directly established from the simple algebraic identity

${\displaystyle (z_{A}-z_{B})(z_{C}-z_{D})+(z_{A}-z_{D})(z_{B}-z_{C})=(z_{A}-z_{C})(z_{B}-z_{D}).}$

In the case of a circle of unit diameter the sides ${\displaystyle S_{1},S_{2},S_{3},S_{4}}$ of any cyclic quadrilateral ABCD are numerically equal to the sines of the angles ${\displaystyle \theta _{1},\theta _{2},\theta _{3}}$ and ${\displaystyle \theta _{4}}$ which they subtend. Similarly the diagonals are equal to the sine of the sum of whichever pair of angles they subtend. We may then write Ptolemy's Theorem in the following trigonometric form:

${\displaystyle \sin \theta _{1}\sin \theta _{3}+\sin \theta _{2}\sin \theta _{4}=\sin(\theta _{1}+\theta _{2})\sin(\theta _{1}+\theta _{4})}$

Applying certain conditions to the subtended angles ${\displaystyle \theta _{1},\theta _{2},\theta _{3}}$ and ${\displaystyle \theta _{4}}$ it is possible to derive a number of important corollaries using the above as our starting point. In what follows it is important to bear in mind that the sum of angles ${\displaystyle \theta _{1}+\theta _{2}+\theta _{3}+\theta _{4}=180^{\circ }}$.

Let ${\displaystyle \theta _{1}=\theta _{3}}$ and ${\displaystyle \theta _{2}=\theta _{4}}$. Then ${\displaystyle \theta _{1}+\theta _{2}=\theta _{3}+\theta _{4}=90^{\circ }}$ (since opposite angles of a cyclic quadrilateral are supplementary). Then:^[10]

${\displaystyle \sin \theta _{1}\sin \theta _{3}+\sin \theta _{2}\sin \theta _{4}=\sin(\theta _{1}+\theta _{2})\sin(\theta _{1}+\theta _{4})}$

${\displaystyle \sin ^{2}\theta _{1}+\sin ^{2}\theta _{2}=\sin ^{2}(\theta _{1}+\theta _{2})}$

${\displaystyle \sin ^{2}\theta _{1}+\cos ^{2}\theta _{1}=1}$

Let ${\displaystyle \theta _{2}=\theta _{4}}$. The rectangle of corollary 1 is now a symmetrical trapezium with equal diagonals and a pair of equal sides. The parallel sides differ in length by ${\displaystyle 2x}$ units where:

${\displaystyle x=S_{2}\cos(\theta _{2}+\theta _{3})}$

It will be easier in this case to revert to the standard statement of Ptolemy's theorem:

${\displaystyle {\begin{array}{lcl}S_{1}S_{3}+S_{2}S_{4}={\overline {AC}}\cdot {\overline {BD}}\\\Rightarrow S_{1}S_{3}+{S_{2}}^{2}={\overline {AC}}^{2}\\\Rightarrow S_{1}[S_{1}-2S_{2}\cos(\theta _{2}+\theta _{3})]+{S_{2}}^{2}={\overline {AC}}^{2}\\\Rightarrow {S_{1}}^{2}+{S_{2}}^{2}-2S_{1}S_{2}\cos(\theta _{2}+\theta _{3})={\overline {AC}}^{2}\\\end{array}}}$

The cosine rule for triangle ABC.

Let

${\displaystyle \theta _{1}+\theta _{2}=\theta _{3}+\theta _{4}=90^{\circ }.}$

Then

${\displaystyle \sin \theta _{1}\sin \theta _{3}+\sin \theta _{2}\sin \theta _{4}=\sin(\theta _{3}+\theta _{2})\sin(\theta _{3}+\theta _{4})}$

Therefore,

${\displaystyle \cos \theta _{2}\sin \theta _{3}+\sin \theta _{2}\cos \theta _{3}=\sin(\theta _{3}+\theta _{2})\times 1}$

Formula for compound angle sine (+).^[11]

Let ${\displaystyle \theta _{1}=90^{\circ }}$. Then ${\displaystyle \theta _{2}+(\theta _{3}+\theta _{4})=90^{\circ }}$. Hence,

${\displaystyle \sin \theta _{1}\sin \theta _{3}+\sin \theta _{2}\sin \theta _{4}=\sin(\theta _{3}+\theta _{2})\sin(\theta _{3}+\theta _{4})}$

${\displaystyle \sin \theta _{3}+\sin \theta _{2}\cos(\theta _{2}+\theta _{3})=\sin(\theta _{3}+\theta _{2})\cos \theta _{2}}$

${\displaystyle \sin \theta _{3}=\sin(\theta _{3}+\theta _{2})\cos \theta _{2}-\cos(\theta _{2}+\theta _{3})\sin \theta _{2}}$

Formula for compound angle sine (−).^[11]

This derivation corresponds to the Third Theorem as chronicled by Copernicus following Ptolemy in Almagest. In particular if the sides of a pentagon (subtending 36° at the circumference) and of a hexagon (subtending 30° at the circumference) are given, a chord subtending 6° may be calculated. This was a critical step in the ancient method of calculating tables of chords.^[12]

This corollary is the core of the Fifth Theorem as chronicled by Copernicus following Ptolemy in Almagest.

Let ${\displaystyle \theta _{3}=90^{\circ }}$. Then ${\displaystyle \theta _{1}+(\theta _{2}+\theta _{4})=90^{\circ }}$. Hence

${\displaystyle \sin \theta _{1}\sin \theta _{3}+\sin \theta _{2}\sin \theta _{4}=\sin(\theta _{3}+\theta _{2})\sin(\theta _{3}+\theta _{4})}$

${\displaystyle \cos(\theta _{2}+\theta _{4})+\sin \theta _{2}\sin \theta _{4}=\cos \theta _{2}\cos \theta _{4}}$

${\displaystyle \cos(\theta _{2}+\theta _{4})=\cos \theta _{2}\cos \theta _{4}-\sin \theta _{2}\sin \theta _{4}}$

Formula for compound angle cosine (+)

Despite lacking the dexterity of our modern trigonometric notation, it should be clear from the above corollaries that in Ptolemy's theorem (or more simply the Second Theorem) the ancient world had at its disposal an extremely flexible and powerful trigonometric tool which enabled the cognoscenti of those times to draw up accurate tables of chords (corresponding to tables of sines) and to use these in their attempts to understand and map the cosmos as they saw it. Since tables of chords were drawn up by Hipparchus three centuries before Ptolemy, we must assume he knew of the 'Second Theorem' and its derivatives. Following the trail of ancient astronomers, history records the star catalogue of Timocharis of Alexandria. If, as seems likely, the compilation of such catalogues required an understanding of the 'Second Theorem' then the true origins of the latter disappear thereafter into the mists of antiquity but it cannot be unreasonable to presume that the astronomers, architects and construction engineers of ancient Egypt may have had some knowledge of it.

The equation in Ptolemy's theorem is never true with non-cyclic quadrilaterals. Ptolemy's inequality is an extension of this fact, and it is a more general form of Ptolemy's theorem. It states that, given a quadrilateral ABCD, then

${\displaystyle {\overline {AB}}\cdot {\overline {CD}}+{\overline {BC}}\cdot {\overline {DA}}\geq {\overline {AC}}\cdot {\overline {BD}}}$

where equality holds if and only if the quadrilateral is cyclic. This special case is equivalent to Ptolemy's theorem.

Ptolemy's theorem gives the product of the diagonals (of a cyclic quadrilateral) knowing the sides, the following theorem yields the same for the ratio of the diagonals.^[13]

${\displaystyle {\frac {AC}{BD}}={\frac {AB\cdot DA+BC\cdot CD}{AB\cdot BC+DA\cdot CD}}}$

Proof: It is known that the area of a triangle ${\displaystyle ABC}$ inscribed in a circle of radius ${\displaystyle R}$ is: ${\displaystyle {\mathcal {A}}={\frac {AB\cdot BC\cdot CA}{4R}}}$

Writing the area of the quadrilateral as sum of two triangles sharing the same circumscribing circle, we obtain two relations for each decomposition.

${\displaystyle {\mathcal {A}}_{\text{tot}}={\frac {AB\cdot BC\cdot CA}{4R}}+{\frac {CD\cdot DA\cdot AC}{4R}}={\frac {AC\cdot (AB\cdot BC+CD\cdot DA)}{4R}}}$

${\displaystyle {\mathcal {A}}_{\text{tot}}={\frac {AB\cdot BD\cdot DA}{4R}}+{\frac {BC\cdot CD\cdot DB}{4R}}={\frac {BD\cdot (AB\cdot DA+BC\cdot CD)}{4R}}}$

Equating, we obtain the announced formula.

Consequence: Knowing both the product and the ratio of the diagonals, we deduce their immediate expressions:

${\displaystyle {\begin{aligned}AC^{2}&=AC\cdot BD\cdot {\frac {AC}{BD}}=(AB\cdot CD+BC\cdot DA){\frac {AB\cdot DA+BC\cdot CD}{AB\cdot BC+DA\cdot CD}}\\[8pt]BD^{2}&={\frac {AC\cdot BD}{\frac {AC}{BD}}}=(AB\cdot CD+BC\cdot DA){\frac {AB\cdot BC+DA\cdot CD}{AB\cdot DA+BC\cdot CD}}\end{aligned}}}$

• Casey's theorem
• Greek mathematics

• Coxeter, H. S. M. and S. L. Greitzer (1967) "Ptolemy's Theorem and its Extensions." §2.6 in Geometry Revisited, Mathematical Association of America pp. 42–43.
• Copernicus (1543) De Revolutionibus Orbium Coelestium, English translation found in On the Shoulders of Giants (2002) edited by Stephen Hawking, Penguin Books ISBN 0-14-101571-3
• Amarasinghe, G. W. I. S. (2013) A Concise Elementary Proof for the Ptolemy's Theorem, Global Journal of Advanced Research on Classical and Modern Geometries (GJARCMG) 2(1): 20–25 (pdf).

• Proof of Ptolemy's Theorem for Cyclic Quadrilateral
• MathPages – On Ptolemy's Theorem
• Elert, Glenn (1994). "Ptolemy's Table of Chords". E-World.
• Ptolemy's Theorem at cut-the-knot
• Compound angle proof at cut-the-knot
• Ptolemy's Theorem Archived 2011-07-24 at the Wayback Machine on PlanetMath
• Ptolemy Inequality on MathWorld
• De Revolutionibus Orbium Coelestium at Harvard.
• Deep Secrets: The Great Pyramid, the Golden Ratio and the Royal Cubit
• Ptolemy's Theorem by Jay Warendorff, The Wolfram Demonstrations Project.
• Book XIII of Euclid's Elements
• A Miraculous Proof (Ptolemy's Theorem) by Zvezdelina Stankova, on Numberphile.