cardinality of monomials

Theorem 1.

If $S$ is a finite set of variable symbols, then the number of monomials of degree $n$ constructed from these symbols is ${n+m-1\choose n}$ , where $m$ is the cardinality of $S$ .

Proof.

The proof proceeds by inducion on the cardinality of $S$ . If $S$ has but one element, then there is but one monomial of degree $n$ , namely the sole element of $S$ raised to the $n$ -th power. Since ${n+1-1\choose n}=1$ , the conclusion holds when $m=1$ .

Suppose, then, that the result holds whenver $m<M$ for some $M$ . Let $S$ be a set with exactly $M$ elements and let $x$ be an element of $S$ . A monomial of degree $n$ constructed from elements of $S$ can be expressed as the product of a power of $x$ and a monomial constructed from the elements of $S\setminus\{x\}$ . By the induction hypothesis, the number of monomials of degree $k$ constructed from elements of $S\setminus\{x\}$ is ${k+M-2\choose k}$ . Summing over the possible powers to which $x$ may be raised, the number of monomials of degree $n$ constructed from the elements of $S$ is as follows:

\sum_{k=0}^{n}{k+M-2\choose k}={k+M-1\choose k}

∎

Theorem 2.

If $S$ is an infinite set of variable symbols, then the number of monomials of degree $n$ constructed from these symbols equals the cardinality of $S$ .

Title	cardinality of monomials
Canonical name	CardinalityOfMonomials
Date of creation	2013-03-22 16:34:42
Last modified on	2013-03-22 16:34:42
Owner	rspuzio (6075)
Last modified by	rspuzio (6075)
Numerical id	10
Author	rspuzio (6075)
Entry type	Theorem
Classification	msc 12-00