% This paper has been transcribed in Plain TeX by % David R. Wilkins % School of Mathematics, Trinity College, Dublin 2, Ireland % (dwilkins@maths.tcd.ie) % % Trinity College, 2000. \magnification=\magstep1 \vsize=227 true mm \hsize=170 true mm \voffset=-0.4 true mm \hoffset=-5.4 true mm \def\folio{\ifnum\pageno>0 \number\pageno \else\fi} \font\Largebf=cmbx10 scaled \magstep2 \font\largerm=cmr12 \font\largeit=cmti12 \font\largesc=cmcsc10 scaled \magstep1 \def\multieqalign#1{\null\,\vcenter{\openup1\jot \mathsurround=0pt \ialign{\strut\hfil$\displaystyle{##}$&$\displaystyle{{}##}$\hfil &&\quad \strut\hfil$\displaystyle{##}$&$\displaystyle{{}##}$\hfil \crcr#1\crcr}}\,} \pageno=0 \null\vskip72pt \centerline{\Largebf A THEOREM CONCERNING} \vskip12pt \centerline{\Largebf POLYGONIC SYNGRAPHY} \vskip24pt \centerline{\Largebf By} \vskip24pt \centerline{\Largebf William Rowan Hamilton} \vskip24pt \centerline{\largerm (Proceedings of the Royal Irish Academy, 5 (1853), p.\ 474--475.)} \vskip36pt \vfill \centerline{\largerm Edited by David R. Wilkins} \vskip 12pt \centerline{\largerm 2000} \vskip36pt\eject \null\vskip36pt \centerline{\largeit A Theorem concerning Polygonic Syngraphy.} \vskip 6pt \centerline{{\largeit By\/} {\largerm Sir} {\largesc William R. Hamilton.}} \bigskip \centerline{Communicated June~13, 1853.} \bigskip \centerline{[{\it Proceedings of the Royal Irish Academy}, vol.~5 (1853), p.\ 474--475.]} \bigskip Professor Sir William Rowan Hamilton exhibited the following Theorem, to which he had been conducted by that theory of geometrical {\it syngraphy} of which he had lately submitted to the Academy a verbal and hitherto unreported sketch, and on which he hopes to return in a future communication. \bigbreak {\it Theorem}. Let $A_1, A_2,\ldots \, A_n$ be any $n$ points (in number odd or even) assumed at pleasure on the $n$ successive sides of a closed polygon $B B_1 B_2 \, \ldots \, B_{n-1}$ (plane or gauche), inscribed in any given surface of the second order. Take any three points, $P$,~$Q$,~$R$, on that surface, as initial points, and draw from each a system of $n$ successive chords, passing in order through the $n$ assumed points $(A)$, and terminating in three other superficial and final points, $P'$,~$Q'$,~$R'$. Then there will be (in general) {\it another\/} inscribed and closed polygon, $C C_1 C_2 \, \ldots \, C_{n-1}$, of which the $n$ sides shall pass successively, in the same order, through the same $n$ points $(A)$; and of which the initial point~$C$ shall also be connected with the point~$B$ of the former polygon, by the relations $$ {a e l \over b c} {\beta \gamma \over \alpha \epsilon \lambda} = {a' e' l' \over b' c'} {\beta' \gamma' \over \alpha' \epsilon' \lambda'},\quad {b f m \over c a} {\gamma \alpha \over \beta \zeta \mu} = {b' f' m' \over c' a'} {\gamma' \alpha' \over \beta' \zeta' \mu'},\quad {c g n \over a b} {\alpha \beta \over \gamma \eta \nu} = {c' g' n' \over a' b'} {\alpha' \beta' \over \gamma' \eta' \nu'};$$ where $$\multieqalign{ a &= Q R, & b &= R P, & c &= P Q, \cr e &= B P, & f &= B Q, & g &= B R, \cr l &= C P, & m &= C Q, & n &= C R, \cr a' &= Q' R', & b' &= R' P', & c' &= P' Q', \cr e' &= B P', & f' &= B Q', & g' &= B R', \cr l' &= C P', & m' &= C Q', & n' &= C R'; \cr}$$ while $\alpha \, \beta \, \gamma \, \epsilon \, \zeta \, \eta \, \lambda \, \mu \, \nu$, and $\alpha' \, \beta' \, \gamma' \, \epsilon' \, \zeta' \, \eta' \, \lambda' \, \mu' \, \nu'$, denote the semidiameters of the surface, respectively parallel to the chords $a \, b \, c \, e \, f \, g \, l \, m \, n$, $a' \, b' \, c' \, e' \, f' \, g' \, l' \, m' \, n'$. As a very particular {\it case\/} of this theorem, we may suppose that $P Q' R P' Q R'$ is a plane hexagon in a conic, and $B C$ its Pascal's line. \bye