# Matrix algebra

(diff) ← Older revision | Latest revision (diff) | Newer revision → (diff)

algebra of matrices

A subalgebra of the full matrix algebra $F _ {n}$ of all $( n \times n)$- dimensional matrices over a field $F$. The operations in $F _ {n}$ are defined as follows:

$$\lambda a = \| \lambda a _ {ij} \| ,\ \ a + b = \| a _ {ij} + b _ {ij} \| ,$$

$$ab = c = \| c _ {ij} \| ,\ c _ {ij} = \ \sum _ {\nu = 1 } ^ { n } a _ {i \nu } b _ {\nu j }$$

where $\lambda \in F$, and $a = \| a _ {ij} \| , b = \| b _ {ij} \| \in F _ {n}$. The algebra $F _ {n}$ is isomorphic to the algebra of all endomorphisms of an $n$- dimensional vector space over $F$. The dimension of $F _ {n}$ over $F$ equals $n ^ {2}$. Every associative algebra with an identity (cf. Associative rings and algebras) and of dimension over $F$ at most $n$ is isomorphic to some subalgebra of $F _ {n}$. An associative algebra without an identity and with dimension over $F$ less than $n$ can also be isomorphically imbedded in $F _ {n}$. By Wedderburn's theorem, the algebra $F _ {n}$ is simple, i.e. it has only trivial two-sided ideals. The centre of the algebra $F _ {n}$ consists of all scalar $( n \times n)$- dimensional matrices over $F$. The group of invertible elements of $F _ {n}$ is the general linear group $\mathop{\rm GL} ( n, F )$. Every automorphism $h$ of $F _ {n}$ is inner:

$$h( x) = txt ^ {-} 1 ,\ \ x \in F _ {n} ,\ \ t \in \mathop{\rm GL} ( n, F ).$$

Every irreducible matrix algebra (cf. also Irreducible matrix group) is simple. If a matrix algebra $A$ is absolutely reducible (for example, if the field $F$ is algebraically closed), then $A = F _ {n}$ for $n > 1$( Burnside's theorem). A matrix algebra is semi-simple if and only if it is completely reducible (cf. also Completely-reducible matrix group).

Up to conjugation, $F _ {n}$ contains a unique maximal nilpotent subalgebra — the algebra of all upper-triangular matrices with zero diagonal entries. In $F _ {n}$ there is an $r$- dimensional commutative subalgebra if and only if

$$r \leq \left [ \frac{n ^ {2} }{4} \right ] + 1$$

(Schur's theorem). Over the complex field $\mathbf C$ the set of conjugacy classes of maximal commutative subalgebras of $\mathbf C _ {n}$ is finite for $n < 6$ and infinite for $n > 6$.

In $F _ {n}$ one has the standard identity of degree $2n$:

$$\sum _ {\sigma \in S _ {2 n } } ( \mathop{\rm sgn} \sigma ) x _ {\sigma ( 1) } \dots x _ {\sigma ( 2n) } = 0,$$

where $S _ {2n}$ denotes the symmetric group and $\mathop{\rm sgn} \sigma$ the sign of the permutation $\sigma$, but no identity of lower degree (cf. Amitsur–Levitzki theorem).

#### References

 [1] H. Weyl, "The classical groups, their invariants and representations" , Princeton Univ. Press (1946) MR0000255 Zbl 1024.20502 [2] N. Jacobson, "Structure of rings" , Amer. Math. Soc. (1956) MR0081264 Zbl 0073.02002 [3] I.N. Herstein, "Noncommutative rings" , Math. Assoc. Amer. (1968) MR1535024 MR0227205 Zbl 0177.05801 [4] B.L. van der Waerden, "Algebra" , 1–2 , Springer (1967–1971) (Translated from German) MR1541390 Zbl 1032.00002 Zbl 1032.00001 Zbl 0903.01009 Zbl 0781.12003 Zbl 0781.12002 Zbl 0724.12002 Zbl 0724.12001 Zbl 0569.01001 Zbl 0534.01001 Zbl 0997.00502 Zbl 0997.00501 Zbl 0316.22001 Zbl 0297.01014 Zbl 0221.12001 Zbl 0192.33002 Zbl 0137.25403 Zbl 0136.24505 Zbl 0087.25903 Zbl 0192.33001 Zbl 0067.00502 [5] D.A. Suprunenko, R.I. Tyshkevich, "Commutable matrices" , Minsk (1966) (In Russian)

A frequently used notation for $F _ {n}$ is $M _ {n} ( F )$.
Wedderburn's theorem on the structure of semi-simple rings says that any semi-simple ring $R$ is a finite direct product of full matrix rings $M _ {n _ {i} } ( F _ {i} )$ over skew-fields $F _ {i}$, and conversely every ring of this form is semi-simple. Further, the $F _ {i}$ and $n _ {i}$ are uniquely determined by $R$.