Algebra homomorphism

From Wikipedia, the free encyclopedia

A homomorphism between two algebras over a field K, A and B, is a map $F:A\rightarrow B$ such that for all k in K and x,y in A,

F(kx) = kF(x)

F(x + y) = F(x) + F(y)

F(xy) = F(x)F(y)

If F is bijective then F is said to be an isomorphism between A and B.

[edit] Examples

Let A = K[x] be the set of all polynomials over a field K and B be the set of all polynomial functions over K. Both A and B are algebras over K given by the standard multiplication and addition of polynomials and functions, respectively. We can map each $f\,$ in A to $\hat{f}\,$ in B by the rule $\hat{f}(t) = f(t) \,$ . A routine check shows that the mapping $f \rightarrow \hat{f}\,$ is a homomorphism of the algebras A and B. If K is a finite field then let

$p(x) = \Pi_{t \in K} (x-t).\,$

p is a nonzero polynomial in K[x], however $p(t) = 0\,$ for all t in K, so $\hat{p} = 0\,$ is the zero function and the algebras are not isomorphic.

If K is infinite then let $\hat{f} = 0\,$ . We want to show this implies that $f = 0\,$ . Let $\deg f = n\,$ and let $t_0,t_1,\dots,t_n\,$ be n + 1 distinct elements of K. Then $f(t_i) = 0\,$ for $0 \le i \le n$ and by Lagrange interpolation we have $f = 0\,$ . Hence the mapping $f \rightarrow \hat{f}\,$ is injective. Since the mapping is clearly surjective, F is bijective and thus an algebra isomorphism of A and B.

If A is a subalgebra of B, then for every invertible b in B the function which takes a in A to b^-1 a b is an algebra homomorphism, called an inner automorphism of B. If A is also simple and B is a central simple algebra, then every homomorphism from A to B is given in this way by some b in B; this is the Skolem-Noether theorem.

Categories: Algebra | Ring theory

Algebra homomorphism

From Wikipedia, the free encyclopedia

[edit] Examples

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