Invariant decomposition

The invariant decomposition is a decomposition of the elements of pin groups ${\text{Pin}}(p,q,r)$ into orthogonal commuting elements. It is also valid in their subgroups, e.g. orthogonal, pseudo-Euclidean, conformal, and classical groups. Because the elements of Pin groups are the composition of $k$ oriented reflections, the invariant decomposition theorem reads

Every $k$ -reflection can be decomposed into ${\textstyle \lceil k/2\rceil }$ commuting factors.^[1]

It is named the invariant decomposition because these factors are the invariants of the $k$ -reflection $R\in {\text{Pin}}(p,q,r)$ . A well known special case is the Chasles' theorem, which states that any rigid body motion in ${\textstyle {\text{SE}}(3)}$ can be decomposed into a rotation around, followed or preceded by a translation along, a single line. Both the rotation and the translation leave two lines invariant: the axis of rotation and the orthogonal axis of translation. Since both rotations and translations are bireflections, a more abstract statement of the theorem reads "Every quadreflection can be decomposed into commuting bireflections". In this form the statement is also valid for e.g. the spacetime algebra ${\textstyle {\text{SO}}(3,1)}$ , where any Lorentz transformation can be decomposed into a commuting rotation and boost.

Bivector decomposition edit

Any bivector $F$ in the geometric algebra $\mathbb {R} _{p,q,r}$ of total dimension $n=p+q+r$ can be decomposed into $k=\lfloor n/2\rfloor$ orthogonal commuting simple bivectors that satisfy

F=F_{1}+F_{2}\ldots +F_{k}.

Defining $\lambda _{i}:=F_{i}^{2}\in \mathbb {C}$ , their properties can be summarized as $F_{i}F_{j}=\delta _{ij}\lambda _{i}+F_{i}\wedge F_{j}$ (no sum). The $F_{i}$ are then found as solutions to the characteristic polynomial

0=(F_{1}-F_{i})(F_{2}-F_{i})\cdots (F_{k}-F_{i}).

Defining

W_{m}={\frac {1}{m!}}\langle F^{m}\rangle _{2m}={\frac {1}{m!}}\,\underbrace {F\wedge F\wedge \ldots \wedge F} _{m\ {\text{times}}}

and

r=\lfloor k/2\rfloor

, the solutions are given by

F_{i}={\begin{cases}{\dfrac {\lambda _{i}^{r}W_{0}+\lambda _{i}^{r-1}W_{2}+\ldots +W_{k}}{\lambda _{i}^{r-1}W_{1}+\lambda _{i}^{r-2}W_{3}+\ldots +W_{k-1}}}\quad &k{\text{ even}},\\[10mu]{\dfrac {\lambda _{i}^{r}W_{1}+\lambda _{i}^{r-1}W_{3}+\ldots +W_{k}}{\lambda _{i}^{r}W_{0}+\lambda _{i}^{r-1}W_{2}+\ldots +W_{k-1}}}&k{\text{ odd}}.\end{cases}}

The values of $\lambda _{i}$ are subsequently found by squaring this expression and rearranging, which yields the polynomial

{\begin{aligned}0&=\sum _{m=0}^{k}\langle W_{m}^{2}\rangle _{0}(-\lambda _{i})^{k-m}\\[5mu]&=(F_{1}^{2}-\lambda _{i})(F_{2}^{2}-\lambda _{i})\cdots (F_{k}^{2}-\lambda _{i}).\end{aligned}}

By allowing complex values for $\lambda _{i}$ , the counter example of Marcel Riesz can in fact be solved.^[1] This closed form solution for the invariant decomposition is only valid for eigenvalues $\lambda _{i}$ with algebraic multiplicity of 1. For degenerate $\lambda _{i}$ the invariant decomposition still exists, but cannot be found using the closed form solution.

Exponential map edit

A $2k$ -reflection $R\in {\text{Spin}}(p,q,r)$ can be written as $R=\exp(F)$ where $F\in {\mathfrak {spin}}(p,q,r)$ is a bivector, and thus permits a factorization

R=e^{F}=e^{F_{1}}e^{F_{2}}\cdots e^{F_{k}}.

The invariant decomposition therefore gives a closed form formula for exponentials, since each $F_{i}$ squares to a scalar and thus follows Euler's formula:

R_{i}=e^{F_{i}}={\cosh }{\bigl (}{\sqrt {\lambda _{i}}}{\bigr )}+{\frac {{\sinh }{\bigl (}{\sqrt {\lambda _{i}}}{\bigr )}}{\sqrt {\lambda _{i}}}}F_{i}.

Carefully evaluating the limit $\lambda _{i}\to 0$ gives

R_{i}=e^{F_{i}}=1+F_{i},

and thus translations are also included.

Rotor factorization edit

Given a $2k$ -reflection $R\in {\text{Spin}}(p,q,r)$ we would like to find the factorization into $R_{i}=\exp(F_{i})$ . Defining the simple bivector

t(F_{i}):={\frac {{\tanh }{\bigl (}{\sqrt {\lambda _{i}}}{\bigr )}}{\sqrt {\lambda _{i}}}}F_{i},

where $\lambda _{i}=F_{i}^{2}$ . These bivectors can be found directly using the above solution for bivectors by substituting^[1]

W_{m}=\langle R\rangle _{2m}{\big /}\langle R\rangle _{0}

where $\langle R\rangle _{2m}$ selects the grade $2m$ part of $R$ . After the bivectors $t(F_{i})$ have been found, $R_{i}$ is found straightforwardly as

R_{i}={\frac {1+t(F_{i})}{\sqrt {1-t(F_{i})^{2}}}}.

Principal logarithm edit

After the decomposition of $R\in {\text{Spin}}(p,q,r)$ into $R_{i}=\exp(F_{i})$ has been found, the principal logarithm of each simple rotor is given by

F_{i}={\text{Log}}(R_{i})={\begin{cases}{\dfrac {\langle R_{i}\rangle _{2}}{\textstyle {\sqrt {\langle R_{i}\rangle {\vphantom {)}}_{2}^{2}}}}}\;{\text{arccosh}}(\langle R_{i}\rangle )\quad &\lambda _{i}^{2}\neq 0,\\[5mu]\langle R_{i}\rangle _{2}&\lambda _{i}^{2}=0.\end{cases}}

and thus the logarithm of $R$ is given by

{\text{Log}}(R)=\sum _{i=1}^{k}{\text{Log}}(R_{i}).

General Pin group elements edit

So far we have only considered elements of ${\text{Spin}}(p,q,r)$ , which are $2k$ -reflections. To extend the invariant decomposition to a $(2k+1)$ -reflections $P\in {\text{Pin}}(p,q,r)$ , we use that the vector part $r=\langle P\rangle _{1}$ is a reflection which already commutes with, and is orthogonal to, the $2k$ -reflection $R=r^{-1}P=Pr^{-1}$ . The problem then reduces to finding the decomposition of $R$ using the method described above.

Invariant bivectors edit

The bivectors $F_{i}$ are invariants of the corresponding $R\in {\text{Spin}}(p,q,r)$ since they commute with it, and thus under group conjugation

RF_{i}R^{-1}=F_{i}.

Going back to the example of Chasles' theorem as given in the introduction, the screw motion in 3D leaves invariant the two lines $F_{1}$ and $F_{2}$ , which correspond to the axis of rotation and the orthogonal axis of translation on the horizon. While the entire space undergoes a screw motion, these two axes remain unchanged by it.

History edit

The invariant decomposition finds its roots in a statement made by Marcel Riesz about bivectors^[2]:

Can any bivector $F$ be decomposed into the direct sum of mutually orthogonal simple bivectors?

Mathematically, this would mean that for a given bivector $F$ in an $n$ dimensional geometric algebra, it should be possible to find a maximum of ${\textstyle k=\lfloor n/2\rfloor }$ bivectors $F_{i}$ , such that ${\textstyle F=\sum _{i=1}^{\lfloor n/2\rfloor }F_{i}}$ , where the $F_{i}$ satisfy $F_{i}\cdot F_{j}=[F_{i},F_{j}]=0$ and should square to a scalar $\lambda _{i}:=F_{i}^{2}\in \mathbb {R}$ . Marcel Riesz gave some examples which lead to this conjecture, but also one (seeming) counter example. A first more general solution to the conjecture in geometric algebras $\mathbb {R} _{n,0,0}$ was given by David Hestenes and Garret Sobczyck.^[3] However, this solution was limited to purely Euclidean spaces. In 2011 the solution in $\mathbb {R} _{4,1,0}$ (3DCGA) was published by Leo Dorst and Robert Jan Valkenburg, and was the first solution in a Lorentzian signature.^[4] Also in 2011, Charles Gunn was the first to give a solution in the degenerate metric $\mathbb {R} _{3,0,1}$ .^[5] This offered a first glimpse that the principle might be metric independent. Then, in 2021, the full metric and dimension independent closed form solution was given by Martin Roelfs in his PhD thesis.^[6] And because bivectors in a geometric algebra $\mathbb {R} _{p,q,r}$ form the Lie algebra ${\mathfrak {spin}}(p,q,r)$ , the thesis was also the first to use this to decompose elements of ${\text{Spin}}(p,q,r)$ groups into orthogonal commuting factors which each follow Euler's formula, and to present closed form exponential and logarithmic functions for these groups. Subsequently in a paper by Martin Roelfs and Steven De Keninck the invariant decomposition was extended to include elements of ${\text{Pin}}(p,q,r)$ , not just ${\text{Spin}}(p,q,r)$ , and the direct decomposition of elements of ${\text{Spin}}(p,q,r)$ without having to pass through ${\mathfrak {spin}}(p,q,r)$ was found.^[1]