On finite dimensional regular gradings

Abstract

Let A be an associative algebra over an algebraically closed field K of characteristic 0. A decomposition A=A1·s Ar of A into a direct sum of r vector subspaces is called a regular decomposition if, for every n and every 1 ij r, there exist aij∈ Aij such that ai1·s ain 0, and moreover, for every 1 i,j r there exists a constant β(i,j)∈ K* such that aiaj=β(i,j)ajai for every ai∈ Ai, aj∈ Aj. We work with decompositions determined by gradings on A by a finite abelian group G. In this case, the function β G× G K* ought to be a bicharacter. A regular decomposition is minimal whenever for every g, h∈ G, the equalities β(x,g)=β(x,h) for every x∈ G imply g=h. In this paper we describe completely the structure of the finite dimensional algebras A (with unit) admitting a G-regular grading. Moreover, we compute the graded codimension sequence for a class of such algebras assuming complete support and minimal regular decomposition. It turns out that, for these algebras, the graded PI-exponent coincides with the ordinary (ungraded) PI-exponent. Finally, we show that the regular decomposition of a finite-dimensional algebra A with a regular G-grading is minimal if and only if (A)=|G|.