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Line 1: {{Short description\|Sub-field of mathematics}} In [[mathematics]], a '''modular invariant''' of a [[group (mathematics)\|group]] is an invariant of a [[finite group]] [[~~group~~Group action (mathematics)\|acting]] on a [[vector space]] of positive characteristic (usually dividing the [[order (group theory)\|order]] of the group). The study of modular invariants was originated in about 1914 by {{harvtxt\|Dickson\|2004}}. ==Dickson invariant== When ''G'' is the finite [[general linear group]] GL<sub>''n''</sub>('''F'''<sub>''q''</sub>) over the [[finite field]] '''F'''<sub>''q''</sub> of order a [[prime power]] ''q'' acting on the [[ring (mathematics)\|ring]] '''F'''<sub>''q''</sub>[''X''<sub>1</sub>, ...,''X''<sub>''n''</sub>] in the natural way, {{harvtxt\|Dickson\|1911}} found a complete set of invariants as follows. Write [''e''<sub>1</sub>, ..., ''e''<sub>''n''</sub>] for the [[determinant]] of the [[matrix (mathematics)\|matrix]] whose entries are ''X''{{su\|b=''i''\|p=''q''<sup>''e''<sub>''j''</sub></sup>}}, where ''e''<sub>1</sub>, ..., ''e''<sub>''n''</sub> are non-negative ~~integers~~[[integer]]s. For example, the [[Moore determinant over a finite field\|Moore determinant]] [0,1,2] of order 3 is :<math>\begin{vmatrix} x_1 & x_1^q & x_1^{q^2}\\x_2 & x_2^q & x_2^{q^2}\\x_3 & x_3^q & x_3^{q^2} \end{vmatrix}</math> Then under the action of an element ''g'' of GL<sub>''n''</sub>('''F'''<sub>''q''</sub>) these determinants are all multiplied by det(''g''), so they are all invariants of SL<sub>''n''</sub>('''F'''<sub>''q''</sub>) and the ratios [''e''<sub>1</sub>, ...,''e''<sub>''n''</sub>] / [0, 1, ..., ''n'' −&~~minus;&nbsp~~thinsp;1] are invariants of GL<sub>''n''</sub>('''F'''<sub>''q''</sub>), called '''Dickson invariants'''. Dickson proved that the full ring of invariants '''F'''<sub>''q''</sub>[''X''<sub>1</sub>, ...,''X''<sub>''n''</sub>]<sup>GL<sub>''n''</sub>('''F'''<sub>''q''</sub>)</sup> is a polynomial algebra over the ''n'' Dickson invariants [0, 1, ..., ''i'' ~~−~~− 1, ''i'' + 1, ..., ''n''] / [0, 1, ..., ''n''&~~minus~~nbsp;− 1] for ''i'' = 0, 1, ..., ''n'' ~~−~~− 1. {{harvtxt\|Steinberg\|1987}} gave a shorter proof of Dickson's theorem. The matrices [''e''<sub>1</sub>, ..., ''e''<sub>''n''</sub>] are divisible by all non-zero linear forms in the variables ''X''<sub>''i''</sub> with coefficients in the finite field '''F'''<sub>''q''</sub>. In particular the [[Moore determinant over a finite field\|Moore determinant]] [0, 1, ..., ''n'' −&~~minus;&nbsp~~thinsp;1] is a product of such linear forms, taken over 1 + ''q'' + ''q''<sup>2</sup> + ... + ''q''<sup>''n'' – 1</sup> representatives of (''n'' –&~~nbsp~~thinsp;1)-dimensional [[projective space]] over the field. This factorization is similar to the factorization of the [[Vandermonde determinant]] into linear factors. ==See also== [[~~Miss~~ Sanderson's theorem]] ==References== {{Citation \| last1=Dickson \| first1=Leonard Eugene \| author1-link=Leonard Eugene Dickson \| title=A Fundamental System of Invariants of the General Modular Linear Group with a Solution of the Form Problem \| jstor=1988736 ~~\| publisher=[[American Mathematical Society]] \| ___location=Providence, R.I.~~ \| year=1911 \| journal=[[Transactions of the American Mathematical Society]] \| issn=0002-9947 \| volume=12 \| issue=1 \| pages=75–98 \| doi=10.2307/1988736\| doi-access=free }} {{Citation \| last1=Dickson \| first1=Leonard Eugene \| author1-link=Leonard Eugene Dickson \| title=On invariants and the theory of numbers \| ~~origyear~~orig-date=1914 \| url=~~http~~https://books.google.com/books?isbn=0486438287 \| publisher=[[Dover Publications]] \| ___location=New York \| series=Dover Phoenix editions \| isbn=978-0-486-43828-3 \| mr=0201389 \| year=2004}} {{Citation \| last1=Rutherford \| first1=Daniel Edwin \| authorlink=Daniel Edwin Rutherford \| title=Modular invariants \| ~~origyear~~orig-date=1932 \| url=~~http~~https://~~www.~~archive.org/details/modularinvariant033204mbp \| publisher=Ramsay Press \| series=Cambridge Tracts in Mathematics and Mathematical Physics, No. 27 \| isbn=978-1-4067-3850-6 \| mr=0186665 \| year=2007}} {{Citation \| last1=Sanderson \| first1=Mildred \| authorlink=Mildred Sanderson \| title=Formal Modular Invariants with Application to Binary Modular Covariants \| jstor=1988702 ~~\| publisher=[[American Mathematical Society]] \| ___location=Providence, R.I.~~ \| year=1913 \| journal=[[Transactions of the American Mathematical Society]] \| issn=0002-9947 \| volume=14 \| issue=4 \| pages=489–500 \| doi=10.2307/1988702\| doi-access=free }} {{Citation \| last1=Steinberg \| first1=Robert \| authorlink=Robert Steinberg \| title=On Dickson's theorem on invariants \| url=http://repository.dl.itc.u-tokyo.ac.jp/dspace/bitstream/2261/1682/1/jfs340309.pdf \| mr=927606 \| year=1987 \| journal=Journal of the Faculty of Science. University of Tokyo. Section IA. Mathematics \| issn=0040-8980 \| volume=34 \| issue=3 \| pages=699–707 \| access-date=2010-12-02 \| archive-url=https://web.archive.org/web/20120305205421/http://repository.dl.itc.u-tokyo.ac.jp/dspace/bitstream/2261/1682/1/jfs340309.pdf \| archive-date=2012-03-05 \| url-status=dead }} {{DEFAULTSORT:Modular Invariant Of A Group}}