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Spiral similarity is a plane transformation in mathematics composed of a rotation and a dilation.^[1] It is used widely in Euclidean geometry to facilitate the proofs of many theorems and other results in geometry, especially in mathematical competitions and Olympiads. Though the origin of this idea is not known, it was documented in 1967 by Coxeter in his book Geometry Revisited.^[2]

A spiral similarity taking triangle ABC to triangle A'B'C'.

Definition

A spiral similarity ${\displaystyle S}$ is composed of a rotation of the plane followed a dilation about a center ${\displaystyle O}$ with coordinates ${\displaystyle c}$ in the plane.^[3] Expressing the rotation by a linear transformation ${\displaystyle T(x)}$ and the dilation as multiplying by a scale factor ${\displaystyle d}$, we find that a point ${\displaystyle p}$ gets mapped to

$${\displaystyle S(p)=d(T(p-c))+c.}$$

Relationship to Complex Numbers

On the complex plane, any spiral similarity can be expressed in the form ${\displaystyle T(x)=x_{0}+\alpha (x-x_{0})}$, where ${\displaystyle \alpha }$ is a complex number. The magnitude ${\displaystyle |\alpha |}$ is the dilation factor of the spiral similarity, and the argument ${\displaystyle {\text{arg}}(\alpha )}$ is the angle of rotation. ^[4]

Properties

Center of a Spiral Similarity for Two Line Segments

Through a dilation of a line, rotation, and translation, any line segment can be mapped into any other through the series of plane transformations. We can find the center of the spiral similarity through the following construction: ^[1]

• Draw lines ${\displaystyle {\overline {AC}}}$ and ${\displaystyle {\overline {BD}}}$, and let ${\displaystyle P}$ be the intersection of the two lines.
• Draw the circumcircles of triangles ${\displaystyle \triangle PAB}$ and ${\displaystyle \triangle PCD}$.
• The circumcircles intersect at a second point ${\displaystyle X\neq P}$. Then ${\displaystyle X}$ is the spiral center mapping ${\displaystyle {\overline {AB}}}$ to ${\displaystyle {\overline {CD}}.}$

Proof: Note that ${\displaystyle ABPX}$ and ${\displaystyle XPCD}$ are cyclic quadrilaterals. Thus, ${\displaystyle \angle XAB=180^{\circ }-\angle BPX=\angle XPD=\angle XCD}$. Similarly, ${\displaystyle \angle ABX=\angle APX=180^{\circ }-\angle XPC=\angle XDC}$. Therefore, by AA similarity, triangles ${\displaystyle XAB}$ and ${\displaystyle XCD}$ are similar. Thus, ${\displaystyle \angle AXB=\angle CXD,}$ so a rotation angle mapping ${\displaystyle A}$ to ${\displaystyle B}$ also maps ${\displaystyle C}$ to ${\displaystyle D}$. The dilation factor is then just the ratio of side lengths ${\displaystyle {\overline {CD}}}$ to ${\displaystyle {\overline {AB}}}$.^[3]

Solution with Complex Numbers

If we express ${\displaystyle A,B,C,}$ and ${\displaystyle D}$ as points on the complex plane with corresponding complex numbers ${\displaystyle a,b,c,}$ and ${\displaystyle d}$, we can solve for the expression of the spiral similarity which takes ${\displaystyle A}$ to ${\displaystyle C}$ and ${\displaystyle B}$ to ${\displaystyle D}$. Note that ${\displaystyle T(a)=x_{0}+\alpha (a-x_{0})}$ and ${\displaystyle T(b)=x_{0}+\alpha (b-x_{0})}$, so ${\displaystyle {\frac {T(b)-T(a)}{b-a}}=\alpha }$. Since ${\displaystyle T(a)=c}$ and ${\displaystyle T(b)=d}$, we plug in to obtain ${\displaystyle \alpha ={\frac {d-c}{b-a}}}$, from which we obtain ${\displaystyle x_{0}={\frac {ad-bc}{a+d-b-c}}}$.^[3]

Pairs of Spiral Similarities

For any points ${\displaystyle A,B,C,}$ and ${\displaystyle D}$, the center of the spiral similarity taking ${\displaystyle {\overline {AB}}}$ to ${\displaystyle {\overline {CD}}}$ is also the center of a spiral similarity taking ${\displaystyle {\overline {AC}}}$ to ${\displaystyle {\overline {BD}}}$.

This can be seen through the above construction. If we let ${\displaystyle X}$ be the center of spiral similarity taking ${\displaystyle {\overline {AB}}}$ to ${\displaystyle {\overline {CD}}}$, then ${\displaystyle \triangle XAB\sim \triangle XCD}$. Therefore, ${\displaystyle \angle AXC=\angle AXB+\angle BXC=\angle CXD+\angle BXC=\angle CXD}$. Also, ${\displaystyle {\frac {AX}{BX}}={\frac {CX}{DX}}}$ implies that ${\displaystyle {\frac {AX}{CX}}={\frac {BX}{DX}}}$. So by AA similarity we see that ${\displaystyle \triangle AXC\sim \triangle BXD}$, thus ${\displaystyle X}$ is also the center of the spiral similarity which takes ${\displaystyle {\overline {AC}}}$ to ${\displaystyle {\overline {BD}}}$.^[3][4]

Corollaries

Proof of Miquel's Quadrilateral Theorem

Spiral similarity can be used to prove Miquel's Quadrilateral Theorem: given four noncollinear points ${\displaystyle A,B,C,}$ and ${\displaystyle D}$, the circumcircles of the four triangles ${\displaystyle \triangle PAB,\triangle PDC,\triangle QAD,}$ and ${\displaystyle \triangle QBC}$ intersect at one point, where ${\displaystyle P}$ is the intersection of ${\displaystyle AD}$ and ${\displaystyle BC}$ and ${\displaystyle Q}$ is the intersection of ${\displaystyle AB}$ and ${\displaystyle CD}$ (see diagram). ^[1]

Let ${\displaystyle M}$ be the center of the spiral similarity which takes ${\displaystyle AB}$ to ${\displaystyle DC}$. By the above construction, the circumcircles of ${\displaystyle \triangle PAB}$ and ${\displaystyle \triangle PDC}$ intersect at ${\displaystyle M}$ and ${\displaystyle P}$. Since ${\displaystyle M}$ is also the center of the spiral similarity taking ${\displaystyle DA}$ to ${\displaystyle BC}$, by similar reasoning the circumcircles of ${\displaystyle \triangle QAD}$ and ${\displaystyle \triangle QBC}$ meet at ${\displaystyle Q}$ and ${\displaystyle M}$. Thus, all four circles intersect at ${\displaystyle M}$.^[1]

Example Problem

Here is an example problem on the 2018 Japan MO Finals which can be solved using spiral similarity:

Given a scalene triangle ${\displaystyle ABC}$, let ${\displaystyle D}$ and ${\displaystyle E}$ be points on segments ${\displaystyle AB}$ and ${\displaystyle AC}$, respectively, so that ${\displaystyle CA=CD,BA=BE}$. Let ${\displaystyle \omega }$ be the circumcircle of triangle ${\displaystyle ADE}$ and ${\displaystyle P}$ the reflection of ${\displaystyle A}$ across ${\displaystyle BC}$. Lines ${\displaystyle PD}$ and ${\displaystyle PE}$ meet ${\displaystyle \omega }$ again at ${\displaystyle X}$ and ${\displaystyle Y}$, respectively. Prove that ${\displaystyle BX}$ and ${\displaystyle CY}$ intersect on ${\displaystyle \omega }$.^[3]

Proof: We first prove the following claims:

Claim 1: Quadrilateral ${\displaystyle PBEC}$ is cyclic.

Proof: Since ${\displaystyle \triangle BAE}$ is isosceles, we note that ${\displaystyle \angle BPC=\angle BAC=180^{\circ }-\angle BEC,}$ thus proving that quadrilateral ${\displaystyle PBEC}$ is cyclic, as desired. By symmetry, we can prove that quadrilateral ${\displaystyle PBDC}$ is cyclic.

Claim 2: ${\displaystyle \triangle AXY\sim \triangle ABC.}$

Proof: We have that ${\displaystyle \angle AXY=180^{\circ }-\angle AEY=\angle YEC=\angle PEC=\angle PBC=\angle ABC.}$ By similar reasoning, ${\displaystyle \angle AYX=\angle ACB,}$ so by AA similarity, ${\displaystyle \triangle AXY\sim \triangle ABC,}$ as desired.

We now note that ${\displaystyle A}$ is the spiral center that maps ${\displaystyle XY}$ to ${\displaystyle BC}$. Let ${\displaystyle F}$ be the intersection of ${\displaystyle BX}$ and ${\displaystyle CY}$. By the spiral similarity construction above, the spiral center must be the intersection of the circumcircles of ${\displaystyle \triangle FXY}$ and ${\displaystyle \triangle FBC}$. However, this point is ${\displaystyle A}$, so thus points ${\displaystyle A,F,X,Y}$ must be concyclic. Hence, ${\displaystyle F}$ must lie on ${\displaystyle \omega }$, as desired.

1. Chen, Evan (2016). Euclidean Geometry in Mathematical Olympiads. United States: MAA Press. pp. 196–200. ISBN 978-0-88385-839-4.
2. Coxeter, H.S.M. (1967). Geometry Revisited. Toronto and New York: Mathematical Association of America. pp. 95–100. ISBN 978-0-88385-619-2.
3. Baca, Jafet (2019). "On a special center of spiral similarity". Mathematical Reflections. 1: 1–9.
4. Zhao, Y. (2010). Three Lemmas in Geometry.