%% boi-6r.tex %% Tables of rootsystems %% Input file for Chapter 6 of the Book of Involutions \subsection{Classification of irreducible root systems} \label{gr.classroot} % There are four infinite families $A_n$, $B_n$, $C_n$,~$D_n$ and five exceptional irreducible root systems $E_6$, $E_7$, $E_8$, $F_4$,~$G_2$. We refer to Bourbaki~\cite{Bourbaki3} for the following datas about root systems. % \nopagebreak % \begin{roottable}{Type $A_n$, $n \geq 1$} % {\index{B}{a1n@{$A_n$ (root system)}}% Let $V = \LR^{n+1}/(e_1 + e_2 + \dots +e_{n+1})\LR$ where $\{e_1,\dots, e_{n+1}\}$ is the canonical basis of $\LR^{n+1}$. We denote by~$\overline{e}_i$ the class of~$e_i$ in~$V$.} % {$\Phi = \bmidb{\overline{e}_i-\overline{e}_j}{i\neq j}$,\quad $n(n+1)$ roots.\\} % {$\Lambda_r = \bmidb{\sum a_i\overline{e}_i}{\sum a_i = 0}$.\\} % {$\Lambda = \sum\overline{e}_i\LZ$,\quad $\Lambda/\Lambda_r \simeq \LZ / (n+1) \LZ$.\\} % {$ \Pi = \{\overline{e}_1 - \overline{e}_2, \overline{e}_2 - \overline{e}_3, \dots, \overline{e}_n - \overline{e}_{n+1} \}$.\\[1ex]} % {$\kern1.5\unitlength % \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}}% \put(0,-5){\hcenter{$\scriptstyle 1$}} \put(1,0){\line(1,0){10}}% \put(12,0){\circle{2}}% \put(12,-5){\hcenter{$\scriptstyle 2$}}% \put(13,0){\line(1,0){5}}% \put(22,0){\circle*{0}}% \put(25,0){\circle*{0}}% \put(28,0){\circle*{0}}% \put(37,0){\line(-1,0){5}}% \put(38,0){\circle{2}}% \put(38,-5){\hcenter{$\scriptstyle n$}}% \end{picture}}}$\\[2ex]} % {$\{1\}$ if $n= 1$,\quad $\{1,\tau\}$ if $n\geq 2$.\\} % {$ \Lambda_+ = \bmidb{ \sum a_i \cdot \overline{e}_i \in \Lambda} {a_1 \geq a_2 \geq \dots\geq a_{n+1} }$.\\} % {$\overline{e}_1 + \overline{e}_2 + \dots + \overline{e}_i$,\quad $i = 1$, $2$, \dots, $n+1$.\\} % \end{roottable} % \begin{roottable}{Type $B_n$, $n \geq 1$} % {\index{B}{b1n@{$B_n$ (root system)}}% Let $V = \LR^n$ with canonical basis $\{e_i\}$.} % {$\Phi=\bmidb{\pm e_i,\pm e_i\pm e_j}{i>j}$,\quad $2n^2$ roots.\\} % {$\Lambda_r = \LZ^n$.\\} % {$ \Lambda = \Lambda_r + \frac{1}{2}(e_1 + e_2 + \dots + e_n)\LZ$, \quad $\Lambda/\Lambda_r \simeq \LZ/2 \LZ$.\\} % {$\Pi = \{ e_1 - e_2, e_2 - e_3, \dots, e_{n-1} - e_n, e_n \}$.\\[1ex]} % {$\kern1.5\unitlength % \begin{picture}(0,0)\put(44,0){\hcenter{${>}$}} \end{picture} \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}}% \put(0,-5){\hcenter{$\scriptstyle 1$}} \put(1,0){\line(1,0){10}}% \put(12,0){\circle{2}}% \put(12,-5){\hcenter{$\scriptstyle 2$}}% \put(13,0){\line(1,0){5}}% \put(22,0){\circle*{0}}% \put(25,0){\circle*{0}}% \put(28,0){\circle*{0}}% \put(37,0){\line(-1,0){5}}% \put(38,0){\circle{2}}% \put(38,-5){\hcenter{$\scriptstyle n-1$}}% \put(39,0.5){\line(1,0){10}}% \put(39,-0.5){\line(1,0){10}}% \put(50,0){\circle{2}}% \put(50,-5){\hcenter{$\scriptstyle n$}}% \end{picture}}}$\\[2ex]} % {$\{1\}$.\\} % {$ \Lambda_+ = \bmidb{ \sum a_i e_i \in \Lambda }{a_1 \geq a_2 \geq \dots \geq a_n \geq 0 }$.\\} % {$0$, $\frac{1}{2}(e_1 + e_2 + \dots + e_n)$.\\} % \end{roottable} % \begin{roottable}{Type $C_n$, $n \geq 1$} % {\index{B}{c1n@{$C_n$ (root system)}}% Let $V = \LR^n$ with canonical basis $\{e_i\}$.} % {$\Phi=\bmidb{\pm2e_i,\pm e_i\pm e_j}{i>j}$,\quad $2n^2$ roots.\\} % {$\Lambda_r = \bmidb{ \sum a_i e_i }{a_i \in \LZ,\,\sum a_i \in 2 \LZ}$.\\} % {$\Lambda = \LZ^n$, \quad $\Lambda/\Lambda_r \simeq \LZ/2 \LZ$.\\} % {$\Pi = \{ e_1 - e_2, e_2 - e_3, \dots, e_{n-1} - e_n, 2 e_n \}$.\\[1ex]} % {$\kern1.5\unitlength \begin{picture}(0,0)\put(44,0){\hcenter{${<}$}} \end{picture} \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}}% \put(0,-5){\hcenter{$\scriptstyle 1$}} \put(1,0){\line(1,0){10}}% \put(12,0){\circle{2}}% \put(12,-5){\hcenter{$\scriptstyle 2$}}% \put(13,0){\line(1,0){5}}% \put(22,0){\circle*{0}}% \put(25,0){\circle*{0}}% \put(28,0){\circle*{0}}% \put(37,0){\line(-1,0){5}}% \put(38,0){\circle{2}}% \put(38,-5){\hcenter{$\scriptstyle n-1$}}% \put(39,0.5){\line(1,0){10}}% \put(39,-0.5){\line(1,0){10}}% \put(50,0){\circle{2}}% \put(50,-5){\hcenter{$\scriptstyle n$}}% \end{picture}}}$\\[2ex]} % {$\{1\}$.\\} % {$\Lambda_+ = \bmidb{ \sum a_i e_i \in \Lambda }{a_1 \geq a_2 \geq \dots \geq a_n \geq 0 }$.\\} % {$0$, $e_1$.\\} % \end{roottable} % \begin{roottable}{Type $D_n$, $n \geq 3$} % {\index{B}{d1n@{$D_n$ (root system)}}% (For $n = 2$ the definition works but yields $A_1 + A_1$.) Let $V = \LR^n$ with canonical basis $\{e_i\}$.} % {$\Phi = \bmidb{\pm e_i \pm e_j}{i > j}$, \quad $2n (n-1)$ roots.\\} % {$ \Lambda_r = \bmidb{\sum a_i e_i}{a_i \in\LZ,\, \sum a_i \in 2 \LZ}$.\\} % {$ \Lambda = \LZ^n + \frac{1}{2} (e_1 + e_2 + \dots + e_n)\LZ$,\\[1ex] % && $\Lambda/\Lambda_r \simeq \begin{cases} \LZ/2 \LZ \oplus \LZ/2 \LZ & \text{if $n$ is even},\\ \LZ/4 \LZ & \text{if $n$ is odd}. \end{cases}$\\[1ex]} % {$\Pi = \{ e_1 - e_2, \dots, e_{n-1} - e_n, e_{n-1} + e_n\}$.\\[4ex]} % {$\kern1.5\unitlength % \begin{picture}(0,0)% \put(47,7){$\vcenter{\hbox{$\scriptstyle n-1$}}$}% \put(47,-7){$\vcenter{\hbox{$\scriptstyle n \phantom{\scriptstyle -1}$}}$}% \end{picture}% \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}}% \put(0,-5){\hcenter{$\scriptstyle 1$}} \put(1,0){\line(1,0){10}}% \put(12,0){\circle{2}}% \put(12,-5){\hcenter{$\scriptstyle 2$}}% \put(13,0){\line(1,0){5}}% \put(22,0){\circle*{0}}% \put(25,0){\circle*{0}}% \put(28,0){\circle*{0}}% \put(37,0){\line(-1,0){5}}% \put(38,0){\circle{2}}% \put(38,-5){\llap{$\scriptstyle n-2$}}% \put(45,7){\circle{2}}% \put(45,-7){\circle{2}}% \put(38.71,0.71){\line(1,1){5.58}} \put(38.71,-0.71){\line(1,-1){5.58}} \end{picture}}}$\\[4ex]} % {$S_3$ if $n=4$,\quad $\{1,\tau\}$ if $n=3$ or $n>4$.\\} % {$\Lambda_+ = \bmidb{ \sum a_i e_i \in \Lambda }{ a_1 \geq a_2 \geq \dots \geq a_n,\, a_{n-1} + a_n \geq 0} $.\\} % {$0$, $e_1$, $\frac{1}{2}(e_1 + e_2 + \dots + e_{n-1} \pm e_n)$.\\} % \end{roottable} % \begin{roottableEXC}{Exceptional types} % \begin{tabular}{@{}l@{}l@{\quad}l}% $E_6$&:&$\Aut\bigl(\Dyn(\Phi)\bigr)=\{1,\tau\}$,\quad {\index{B}{E6@{$E_6$ (root system)}}% }% $\Lambda/\Lambda_r\simeq \LZ/3 \LZ$.\\[1ex]&& % \kern1.5\unitlength % \begin{picture}(0,0) \put(0,0){\circle{2}} \put(12,0){\circle{2}} \put(24,0){\circle{2}} \put(36,0){\circle{2}} \put(48,0){\circle{2}} % \put(1,0){\line(1,0){10}} \put(13,0){\line(1,0){10}} \put(25,0){\line(1,0){10}} \put(37,0){\line(1,0){10}} % \put(24,-8){\circle{2}} \put(24,-7){\line(0,1){6}} \end{picture}\\[6ex] % $E_7$&:&$\Aut\bigl(\Dyn(\Phi)\bigr)=\{1\}$,\quad {\index{B}{E7@{$E_7$ (root system)}}% }% $\Lambda/\Lambda_r\simeq \LZ/2 \LZ$.\\[1ex]&& % \kern1.5\unitlength % \begin{picture}(0,0) \put(0,0){\circle{2}} \put(12,0){\circle{2}} \put(24,0){\circle{2}} \put(36,0){\circle{2}} \put(48,0){\circle{2}} \put(60,0){\circle{2}} % \put(1,0){\line(1,0){10}} \put(13,0){\line(1,0){10}} \put(25,0){\line(1,0){10}} \put(37,0){\line(1,0){10}} \put(49,0){\line(1,0){10}} % \put(24,-8){\circle{2}} \put(24,-7){\line(0,1){6}} \end{picture}\\[6ex] % $E_8$&:&$\Aut\bigl(\Dyn(\Phi)\bigr)=\{1\}$,\quad {\index{B}{E8@{$E_8$ (root system)}}% }% $\Lambda/\Lambda_r=0$.\\[1ex]&& % \kern1.5\unitlength % \begin{picture}(0,0) \put(0,0){\circle{2}} \put(12,0){\circle{2}} \put(24,0){\circle{2}} \put(36,0){\circle{2}} \put(48,0){\circle{2}} \put(60,0){\circle{2}} \put(72,0){\circle{2}} % \put(1,0){\line(1,0){10}} \put(13,0){\line(1,0){10}} \put(25,0){\line(1,0){10}} \put(37,0){\line(1,0){10}} \put(49,0){\line(1,0){10}} \put(61,0){\line(1,0){10}} % \put(24,-8){\circle{2}} \put(24,-7){\line(0,1){6}} \end{picture}\\[6ex] % $F_4$&:&$\Aut\bigl(\Dyn(\Phi)\bigr)=\{1\}$,\quad {\index{B}{F15@{$F_4$ (root system)}}% }% $\Lambda/\Lambda_r=0$. {$\kern10\unitlength % \begin{picture}(0,0)\put(18,0){\hcenter{${>}$}} \end{picture} \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}} \put(12,0){\circle{2}} \put(24,0){\circle{2}} \put(36,0){\circle{2}} % \put(1,0){\line(1,0){10}} \put(13,0.4){\line(1,0){10}} \put(13,-0.6){\line(1,0){10}} \put(25,0){\line(1,0){10}} \end{picture}}}$}\\[2ex] % $G_2$&:&$\Aut\bigl(\Dyn(\Phi)\bigr)=\{1\}$,\quad {\index{B}{G2r@{$G_2$ (root system)}}% }% $\Lambda/\Lambda_r=0$. % {$\kern10\unitlength % \begin{picture}(0,0)\put(6,0){\hcenter{${<}$}} \end{picture} \vcenter{\hbox{\begin{picture}(0,0)% \put(0,0){\circle{2}} \put(12,0){\circle{2}} % \put(1,0){\line(1,0){10}} \put(1,0.7){\line(1,0){10}} \put(1,-0.7){\line(1,0){10}} \end{picture}}}$}\\[2ex] \end{tabular} \end{roottableEXC} %% end of boi-6r.tex %%% Local Variables: %%% mode: latex %%% TeX-master: "boi" %%% End: