% 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\tensc=cmcsc10 \font\sevensc=cmcsc10 scaled 700 \newfam\scfam \def\sc{\fam\scfam\tensc} \textfont\scfam=\tensc \scriptfont\scfam=\sevensc \font\largesc=cmcsc10 scaled \magstep1 \pageno=0 \null\vskip72pt \centerline{\Largebf ACCOUNT OF THE ICOSIAN CALCULUS} \vskip24pt \centerline{\Largebf By} \vskip24pt \centerline{\Largebf William Rowan Hamilton} \vskip24pt \centerline{\largerm (Proceedings of the Royal Irish Academy, 6 (1858), p.\ 415--416.)} \vskip36pt \vfill \centerline{\largerm Edited by David R. Wilkins} \vskip 12pt \centerline{\largerm 2000} \vskip36pt\eject \null\vskip36pt \centerline{{\largeit Account of the Icosian Calculus.}} \vskip 6pt \centerline{{\largeit By\/} {\largerm Sir} {\largesc William R. Hamilton.}} \bigskip \centerline{Communicated November~10, 1856.} \bigskip \centerline{[{\it Proceedings of the Royal Irish Academy}, vol.~6 (1858), p.\ 415--416.]} \bigskip Sir William Rowan Hamilton read a Paper on a new System of Roots of Unity, and of operations therewith connected: to which system of symbols and operations, in consequence of the geometrical character of some of their leading interpretations, he is disposed to give the name of the `{\sc Icosian Calculus}.' This Calculus {\it agrees\/} with that of the Quaternions, in three important respects: namely, 1st, that its three chief symbols, $\iota$,~$\kappa$,~$\lambda$, are (as above suggested) {\it roots\/} of {\it unity}, as $i$,~$j$,~$k$ are certain {\it fourth roots\/} thereof: 2nd, that these new roots {\it obey\/} the {\it associative\/} law of multiplication; and 3rd, that they are {\it not\/} subject to the {\it commutative\/} law, or that their {\it places\/} as {\it factors\/} must {\it not\/} in general be {\it altered\/} in a {\it product}. And it {\it differs\/} from the Quaternion Calculus, 1st, by involving roots with {\it different exponents\/}; and 2nd by {\it not requiring\/} so far as yet appears) the {\it distributive\/} property of multiplication. In fact, $+$ and $-$, in these new calculuations, enter {\it only\/} as {\it connecting exponents}, and {\it not\/} as connecting {\it terms\/}: indeed, {\it no terms}, or in other words, {\it no polynomes}, nor even binomes, have hitherto presented themselves, in these late researches of the author. As regards the {\it exponents\/} of the new roots, it may be mentioned that in the {\it principal system\/}---for the new Calculus involves a {\it family of systems\/}---there are adopted the equations, $$1 = \iota^2 = \kappa^3 = \lambda^5,\quad \lambda = \iota \kappa; \eqno ({\rm A})$$ so that we deal, in it, with a {\it new square root, cube root}, and {\it fifth root}, of {\it positive unity\/}; the latter root being the {\it product\/} of the two former, when taken in an {\it order\/} assigned, but {\it not\/} in the opposite order. From these simple assumptions~(A), a long train of consistent calculations opens itself out, for every result of which there is found a corresponding geometrical interpretation, in the theory of two of the celebrated solids of antiquity, alluded to with interest by Plato in the Timaeus; namely, the Icosaedron, and the Dodecaedron: whereof the {\it angles\/} may {\it now\/} be {\it unequal}. By making $\lambda^4 = 1$, the author obtains other symbolical results, which are interpreted by the Octahedron and the Hexahedron. The Pyramid is, in {\it this\/} theory, almost too simple to be interesting: but it is dealt with by the assumption, $\lambda^3 = 1$, the other equations~(A) being untouched. As one fundamental result of those equations~(A), which may serve as a slight specimen of the rest, it is found that if we make $\iota \kappa^2 = \mu$, we shall have $$\mu^5 = 1,\quad \mu = \lambda \iota \lambda,\quad \lambda = \mu \iota \mu;$$ so that this {\it new fifth root\/}~$\mu$ has relations of perfect {\it reciprocity\/} with the former fifth root~$\lambda$. But there exist more {\it general\/} results, {\it including\/} this, and others, on which Sir W.~R.~H. hopes to be allowed to make a future communication to the Academy: as also on some applications of the principles already stated, or alluded to, which appear to be in some degree interesting. \bye