3.4: Möbius Transformations

Theorem $\PageIndex{1}$

The function

is a transformation of $\mathbb{C}^+$ if and only if $ad - bc \neq 0\text{.}$

Proof

First, suppose $T(z) = \dfrac{(az+b)}{(cz+d)}$ and $ad - bc \neq 0\text{.}$ We must show that $T$ is a transformation. To show $T$ is one-to-one, assume $T(z_1) = T(z_2)\text{.}$ Then

$$\dfrac{az_1 + b}{cz_1 + d} = \dfrac{az_2 + b}{cz_2 + d}\text{.}$$

Cross multiply this expression and simplify to obtain

$$(ad - bc)z_1 = (ad - bc)z_2\text{.}$$

Since $ad - bc \neq 0$ we may divide this term out of the expression to see $z_1 = z_2\text{,}$ so $T$ is 1-1 and it remains to show that $T$ is onto.

Suppose $w$ in $\mathbb{C}^+$ is given. We must find $z \in \mathbb{C}^+$ such that $T(z) = w\text{.}$ If $w = \infty\text{,}$ then $z = \dfrac{-d}{c}$ (which is $\infty$ if $c = 0$) does the trick, so assume $w \neq \infty\text{.}$ To find $z$ such that $T(z) = w$ we solve the equation

$$\dfrac{az + b}{cz+d} = w$$

for $z\text{,}$ which is possible so long as $a$ and $c$ are not both 0 (causing the $z$ terms to vanish). Since $ad-bc \neq 0\text{,}$ we can be assured that this is the case, and solving for $z$ we obtain

$$z = \dfrac{-dw + b}{cw-a}\text{.}$$

Thus $T$ is onto, and $T$ is a transformation.

To prove the converse we show the contrapositive. We suppose $ad-bc=0$ and show $T(z)=\dfrac{(az+b)}{(cz+d)}$ is not a transformation by tackling two cases.

Case 1: $ad = 0\text{.}$ In this case, $bc = 0$ as well, so $a$ or $d$ is zero, and $b$ or $c$ is zero. In all four scenarios, one can check immediately that $T$ is not a transformation of $\mathbb{C}^+\text{.}$ For instance, if $a = c = 0$ then $T(z) = \dfrac{b}{d}$ is neither 1-1 nor onto $\mathbb{C}^+\text{.}$

Case 2: $ad \neq 0\text{.}$ In this case, all four constants are non-zero, and $\dfrac{a}{c} = \dfrac{b}{d}\text{.}$ Since $T(0)=\dfrac{b}{d}$ and $T(\infty)= \dfrac{a}{c}\text{,}$ $T$ is not 1-1, and hence not a transformation of $\mathbb{C}^+\text{.}$

Theorem $\PageIndex{2}$

The Möbius transformation

has the inverse transformation

In particular, the inverse of a Möbius transformation is itself a Möbius transformation.

Theorem $\PageIndex{3}$

The composition of two Möbius transformations is again a Möbius transformation.

Theorem $\PageIndex{4}$

A transformation of $\mathbb{C}^+$ is a Möbius transformation if and only if it is the composition of an even number of inversions.

Proof

We first observe that any general linear transformation $T(z)=az+b$ is the composition of an even number of inversions. Indeed, such a map is a dilation and rotation followed by a translation. Rotations and translations are each compositions of two reflections (Theorem $3.1.4$), and a dilation is the composition of two inversions about concentric circles (Exericise $3.2.4$). So, in total, we have that $T(z) = az+ b$ is the composition of an even number of inversions.

Now suppose $T$ is the Möbius transformation $T(z) = \dfrac{(az+b)}{(cz+d)}\text{.}$ If $c = 0$ then $T$ is a general linear transformation of the form $T(z) = \dfrac{a}{d}z + \dfrac{b}{d}\text{,}$ and we have nothing to show.

So we assume $c \neq 0\text{.}$ By doing some long division, the Möbius transformation can be rewritten as

$$T(z) = \dfrac{az+b}{cz+d} = \dfrac{a}{c} + \dfrac{\dfrac{(bc-ad)}{c}}{cz+d}\text{,}$$

which can be viewed as the composition $T_3 \circ T_2 \circ T_1(z)\text{,}$ where $T_1(z) = cz + d\text{,}$ $T_2(z) = \dfrac{1}{z}$ and $T_3(z) = \dfrac{bc-ad}{c}z + \dfrac{a}{c}\text{.}$ Note that $T_1$ and $T_3$ are general linear transformations, and

$$T_2(z) = \dfrac{1}{z} = \overline{\bigg[\dfrac{1}{\overline{z}}\bigg]}$$

is inversion in the unit circle followed by reflection about the real axis. Thus, each $T_i$ is the composition of an even number of inversions, and the general Möbius transformation $T$ is as well.

To prove the other direction, we show that if $T$ is the composition of two inversions then it is a Möbius transformation. Then, if $T$ is the composition of any even number of inversions, it is the composition of half as many Möbius transformations and is itself a Möbius transformation by Theorem $3.4.3$.

Case 1: $T$ is the composition of two circle inversions. Suppose $T = i_{C_1} \circ i_{C_2}$ where $C_1$ is the circle $|z - z_1| = r_1$ and $C_2$ is the circle $|z-z_2| = r_2\text{.}$ For $i = 1, 2$ the inversion may be described by

$$i_{C_i} = \dfrac{r_i^2}{\overline{z-z_i}}+z_i\text{,}$$

and if we compose these two inversions we do in fact obtain a Möbius transformation. We leave the details of this computation to the reader but note that the determinant of the resulting Möbius transformation is $r_1^2r_2^2\text{.}$

Case 2: $T$ is the composition of one circle inversion and one line reflection. Reflection in the line can be given by $r_L(z) = e^{i\theta}\overline{z}+b$ and inversion in the circle $C$ is given by $i_{C} = \dfrac{r^2}{\overline{z-z_o}}+z_o$ where $z_0$ and $r$ are the center and radius of the circle, as usual. Work out the composition and you'll see that we have a Möbius transformation with determinant $e^{i\theta}r^2$ (which is non-zero). Its inverse, the composition $i_C \circ r_L\text{,}$ is also a Möbius transformation.

Case 3: $T$ is the composition of two reflections. Either the two lines of reflection are parallel, in which case the composition gives a translation, or they intersect, in which case we have a rotation about the point of intersection (Theorem $3.1.4$). In either case we have a Möbius transformation.

It follows that the composition of any even number of inversions yields a Möbius transformation.

Theorem $\PageIndex{5}$

Möbius transformations take clines to clines and preserves angles.

Theorem $\PageIndex{6}$

Any Möbius transformation $T: \mathbb{C}^+ \to \mathbb{C}^+$ fixes $1$, $2$, or all points of $\mathbb{C}^+\text{.}$

Proof

To find fixed points of $T(z) = \dfrac{(az+b)}{(cz + d)}$ we want to solve

$$\dfrac{az + b}{cz + d} = z$$

for $z\text{,}$ which gives the quadratic equation

$$cz^2 + (d-a)z - b = 0 \text{.} \label{3.4.1}$$

If $c \neq 0$ then, as discussed in Example $2.4.2$, equation ($\ref{3.4.1}$) must have $1$ or $2$ solutions, and there are $1$ or $2$ fixed points in this case.

If $c = 0$ and $a \neq d\text{,}$ then the transformation has the form $T(z) = \dfrac{(az + b)}{d}$, which fixes $\infty\text{.}$ From equation (1), $z = \dfrac{b}{(d-a)} \neq \infty$ is a fixed point as well. So we have $2$ fixed points in this case.

If $c = 0$ and $a = d\text{,}$ then equation ($\ref{3.4.1}$) reduces to $0 = -b\text{,}$ so $b = 0$ too, and the transformation is the identity transformation $T(z) = \dfrac{(az+0)}{(0z + a)} = z\text{.}$ This transformation fixes every point.

Theorem $\PageIndex{7}$

There is a unique Möbius transformation taking any three distinct points of $\mathbb{C}^+$ to any three distinct points of $\mathbb{C}^+\text{.}$

Proof

Suppose $z_1, z_2,$ and $z_3$ are distinct points in $\mathbb{C}^+\text{,}$ and $w_1, w_2\text{,}$ and $w_3$ are distinct points in $\mathbb{C}^+\text{.}$ We show there exists a unique Möbius transformation that maps $z_i \mapsto w_i$ for $i = 1,2,3\text{.}$ To start, we show there exists a map, built from inversions, that maps $z_1 \mapsto 1\text{,}$ $z_2 \mapsto 0$ and $z_3 \mapsto \infty\text{.}$ We do so in the case that $z_3 \neq \infty\text{.}$ This special case is left to the exercises.

First, invert about any circle centered at $z_3\text{.}$ This takes $z_3$ to $\infty$ as desired. Points $z_1$ and $z_2$ no doubt get moved, say to $z_1^\prime$ and $z_2^\prime\text{,}$ respectively, neither of which is $\infty\text{.}$ Second, do a translation that takes $z_2^\prime$ to 0. Such a translation will keep $\infty$ fixed, and take $z_1^\prime$ to some new spot $z_1^{\prime\prime}$ in $\mathbb{C}\text{.}$ Third, rotate and dilate about the origin, (which keeps 0 and $\infty$ fixed) so that $z_1^{\prime\prime}$ moves to 1. This process yields a composition of inversions that maps $z_1 \mapsto 1\text{,}$ $z_2 \mapsto 0\text{,}$ and $z_3 \mapsto \infty\text{.}$ However, this composition actually involves an odd number of inversions, so it's not a Möbius transformation. To make a Möbius transformation out of this composition, we do one last inversion: reflect across the real axis. This keeps 1, 0, and $\infty$ fixed. Thus, there is a Möbius transformation taking any three distinct points to the points $1, 0,$ and $\infty\text{.}$ For now, we let $T$ denote the Möbius transformation that maps $z_1 \mapsto 1\text{,}$ $z_2 \mapsto 0$ and $z_3 \mapsto \infty\text{.}$

One can similarly construct a Möbius transformation, call it $S\text{,}$ that takes $w_1 \mapsto 1\text{,}$ $w_2 \mapsto 0\text{,}$ and $w_3 \mapsto \infty\text{.}$

If we let $S^{-1}$ denote the inverse transformation of $S\text{,}$ then the composition $S^{-1} \circ T$ is a Möbius transformation, and this transformation does what we set out to accomplish as suggested by Figure $3.4.2$. In particular,

$$\begin{align*} S^{-1} \circ T(z_1) & = S^{-1}(1) = w_1\\ S^{-1} \circ T(z_2) & = S^{-1}(0) = w_2\\ S^{-1} \circ T(z_3) & = S^{-1}(\infty) = w_3\text{.} \end{align*}$$

Finally, to prove that this Möbius transformation is unique, assume that there are two Möbius transformations $U$ and $V$ that map $z_1 \mapsto w_1\text{,}$ $z_2 \mapsto w_2$ and $z_3 \mapsto w_3\text{.}$ Then $V^{-1} \circ U$ is a Möbius transformation that fixes $z_1, z_2\text{,}$ and $z_3\text{.}$ According to Theorem $3.4.6$ there is only one Möbius transformation that fixes more than two points, and this is the identity transformation. Thus $V^{-1} \circ U(z) = z$ for all $z \in \mathbb{C}^+\text{.}$ Similarly, $U \circ V^{-1}(z) = z\text{,}$ and it follows that $U(z) = V(z)$ for all $z \in \mathbb{C}^+\text{.}$ That is, $U$ and $V$ are the same map.

Theorem $\PageIndex{8}$: Invariance of Cross Ratio

The probabilities assigned to events by a distribution function on a sample space are given by.

Proof

Suppose $z_0, z_1, z_2,$ and $z_3$ are four distinct points in $\mathbb{C}^+\text{,}$ and $T$ is any Möbius transformation. Then

$$(z_0,z_1;z_2,z_3) = (T(z_0), T(z_1); T(z_2), T(z_3))\text{.}$$

Corollary $\PageIndex{1}$

If $z$ and $z^*$ are symmetric with respect to the cline $C\text{,}$ and $T$ is any Möbius transformation, then $T(z)$ and $T(z^*)$ are symmetric with respect to the cline $T(C)\text{.}$

Theorem $\PageIndex{9}$

Given any two clines $C_1$ and $C_2\text{,}$ there exists a Möbius transformation $T$ that maps $C_1$ onto $C_2\text{.}$ That is, $T(C_1) = C_2\text{.}$

Proof

Let $p_1$ be a point on $C_1$ and $q_1$ and $q_1^*$ symmetric with respect to $C_1\text{.}$ Similarly, let $p_2$ be a point on $C_2$ and $q_2$ and $q_2^*$ be symmetric with respect to $C_2\text{.}$ Build the Möbius transformation that sends $p_1 \mapsto p_2\text{,}$ $q_1 \mapsto q_2$ and $q_1^* \mapsto q_2^*\text{.}$ Then $T(C_1)=C_2\text{.}$