In abstract algebra, given a module and a submodule, one can construct their quotient module.[1][2] This construction, described below, is analogous to how one obtains the ring of integers modulo an integer n, see modular arithmetic. It is the same construction used for quotient groups and quotient rings.
Given a module A over a ring R, and a submodule B of A, the quotient space A/B is defined by the equivalence relation
for any a and b in A. The elements of A/B are the equivalence classes [a] = { a + b : b in B }.
The addition operation on A/B is defined for two equivalence classes as the equivalence class of the sum of two representatives from these classes; and in the same way for multiplication by elements of R. In this way A/B becomes itself a module over R, called the quotient module. In symbols, [a] + [b] = [a+b], and r·[a] = [r·a], for all a,b in A and r in R.
Consider the ring R of real numbers, and the R-module A = R[X], that is the polynomial ring with real coefficients. Consider the submodule
of A, that is, the submodule of all polynomials divisible by X2+1. It follows that the equivalence relation determined by this module will be
Therefore, in the quotient module A/B one will have X2 + 1 be the same as 0, and such, one can view A/B as obtained from R[X] by setting X2 + 1 = 0. It is clear that this quotient module will be isomorphic to the complex numbers, viewed as a module over the real numbers R.