Generic matrix ring

In algebra, a generic matrix ring of size n with variables $X_{1},\dots X_{m}$ , denoted by $F_{n}$ , is a sort of a universal matrix ring. It is universal in the sense that, given a commutative ring R and n-by-n matrices $A_{1},\dots ,A_{m}$ over R, any mapping $X_{i}\mapsto A_{i}$ extends to the ring homomorphism (called evaluation) $F_{n}\to M_{n}(R)$ . For example, a central polynomial is an element of the ring $F_{n}$ .

Explicitly, it is the subalgebra $F_{n}$ of the matrix ring $M_{n}(k[(X_{l})_{ij}|1\leq l\leq m,1\leq i,j\leq n])$ generated by n-by-n matrices $X_{1},\dots ,X_{m}$ , where $(X_{l})_{ij}$ are matrix entries and commute by definition. For example, if m = 1, then $F_{1}$ is a polynomial ring in one variable.

By definition, $F_{n}$ is a quotient of the free ring $k\langle t_{1},\dots ,t_{m}\rangle$ with $t_{i}\to X_{i}$ . This has a following geometric meaning. In algebraic geometry, the polynomial ring $k[t,\dots ,t_{m}]$ is the coordinate ring of the affine space $k^{m}$ and to give a point of $k^{m}$ is to give a ring homomorphism (evaluation) $k[t,\dots ,t_{m}]\to k$ (either by the Hilbert nullstellensatz or by the scheme theory). A free ring $k\langle t_{1},\dots ,t_{m}\rangle$ plays the role of the affine space in the noncommutative algebraic geometry (i.e., we don't demand free variables to commute) and thus a generic matrix ring is then the coordinate ring of a noncommutative affine variety whose points are the Spec of matrix rings.

The maximum spectrum of the generic matrix ring

References

Artin, Michael (1999). "Noncommutative Rings" (PDF).
Cohn, Paul M. (2003). Further algebra and applications (Revised ed. of Algebra, 2nd ed.). London: Springer-Verlag. ISBN 1-85233-667-6. Zbl 1006.00001.

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