Moore determinant: Difference between revisions

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In [[linear algebra]], a '''Moore matrix''', named after [[E. H. Moore]], is a [[determinant]] defined over a [[finite field]] from a square '''Moore [[matrix (math)|matrix]]'''.  A Moore matrix has successive powers of the [[Frobenius]] automorphism applied to the first column, i.e., an ''m'' × ''n'' matrix
In [[linear algebra]], a '''Moore matrix''', named after [[E. H. Moore]], is a [[determinant]] defined over a [[finite field]] from a square '''Moore [[matrix (math)|matrix]]'''.  A Moore matrix has successive powers of the [[Frobenius automorphism]] applied to the first column, i.e., an ''m'' × ''n'' matrix


:<math>M=\begin{bmatrix}
:<math>M=\begin{bmatrix}
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==References==
==References==
* {{cite book | author=David Goss | title=Basic Structures of Function Field Arithmetic | date=1996 | publisher=[[Springer Verlag]] | isbn=3-540-63541-6}}  Chapter 1.
* {{cite book | author=David Goss | title=Basic Structures of Function Field Arithmetic | date=1996 | publisher=[[Springer Verlag]] | isbn=3-540-63541-6}}  Chapter 1.[[Category:Suggestion Bot Tag]]

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In linear algebra, a Moore matrix, named after E. H. Moore, is a determinant defined over a finite field from a square Moore matrix. A Moore matrix has successive powers of the Frobenius automorphism applied to the first column, i.e., an m × n matrix

or

for all indices i and j. (Some authors use the transpose of the above matrix.)

The Moore determinant of a square Moore matrix (so m=n) can be expressed as:

where c runs over a complete set of direction vectors, made specific by having the last non-zero entry equal to 1.

See also

References