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Total algebra

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In abstract algebra, the total algebra of a monoid is a generalization of the monoid ring that allows for infinite sums of elements of a ring. Suppose that S is a monoid with the property that, for all , there exist only finitely many ordered pairs for which . Let R be a ring. Then the total algebra of S over R is the set of all functions with the addition law given by the (pointwise) operation:

and with the multiplication law given by:

The sum on the right-hand side has finite support, and so is well-defined in R.

These operations turn into a ring. There is an embedding of R into , given by the constant functions, which turns into an R-algebra.

An example is the ring of formal power series, where the monoid S is the natural numbers. The product is then the Cauchy product.


References

  • Nicolas Bourbaki (1989), Algebra, Springer: §III.2