1.6 The geometric progression and the binomial theorem

There are two special algebraic identities that hold in $R$ (in fact in any field $F$ whatsoever) that we emphasize. They are bothproved by mathematical induction. The first is the formula for the sum of a geometric progression.

Geometric progression

Let $x$ be a real number, and let $n$ be a natural number. Then,

1. If $x\ne 1,$ then
   $$\sum _{j=0}^n{x}^j=\frac{1-x^{n+1}}{1-x}.$$
2. If $x=1,$ then
   $$\sum _{j=0}^n{x}^j=n+1.$$

The second claim is clear, since there are $n+1$ summands and each is equal to 1.

We prove the first claim by induction. Thus, if $n=1,$ then the assertion is true, since

Now, supposing that the assertion is true for the natural number $k,$ i.e., that

let us show that the assertion holds for the natural number $k+1.$ Thus

which completes the proof.

The second algebraic formula we wish to emphasize is the Binomial Theorem. Before stating it, we must introduce some useful notation.

Let $n$ be a natural number. As earlier in this chapter, we define $n!$ as follows:

$$n!=n\times (n-1)\times (n-2)\times ...\times 2\times 1.$$

For later notational convenience, we also define $0!$ to be 1.

If $k$ is any integer for which $0\le k\le n,$ we define the binomial coefficient $\left(\genfrac{}{}{0pt}{}{n}{k}\right)$ by

$$\left(\genfrac{}{}{0pt}{}{n}{k}\right)=\frac{n!}{k!(n-k)!}=\frac{n\times (n-1)\times (n-2)\times ...\times (n-k+1)}{k!}.$$

If $x,y\in R$ and $n$ is a natural number, then

We shall prove this theorem by induction. If $n=1,$ then the assertion is true, for ${(x+y)}^1=x+y$ and

Now, assume that the assertion holds for the natural number $j;$ i.e.,

and let us prove that the assertion holds for the natural number $j+1.$ We will make use of part (c) of [link] . We have that

which shows that the assertion of the theorem holds for the natural number $j+1.$ This completes the proof.

The next exercise is valid in any ordered field, but, since we are mainly interested in the order field $R,$ we state everything in terms of that field.

There is one more important algebraic identity, which again can be proved by induction.It is actually just a corollary of the geometric progression formula.

If $x,y\in R$ and $n$ is a natural number, then

If $n=1$ the theorem is clear. Suppose it holds for a natural number $k,$ and let us prove the identity for the natural number $k+1.$ We have

, which shows that the assertion holds for the natural number $k+1.$ So, by induction, the theorem is proved.

Using the Binomial Theorem together with the preceding theorem, we may now investigate the existence of $n$ th roots of real numbers. This next theorem is definitely not valid in any ordered field, forit again depends on the completeness property.

Let $n$ be a natural number and let $x$ be a positive real number. Then there exists a unique positive real number $y$ such that $y^n=x;$ i.e., $x$ has a unique positive $n$ th root.

Note first that if $0\le t<s,$ then $t^n<s^n.$ (To see this, argue by induction, and use part (e) of [link] .) Using this, we mimic the proof of [link] . Thus, let $S$ be the set of all positive real numbers $t$ for which $t^n\le x.$ Then $S$ is nonempty and bounded above. Indeed, if $x\ge 1,$ then $1\in S,$ while if $x<1,$ then $x$ itself is in $S.$ Therefore, $S$ is nonempty. Also, using part (b) of [link] , we see that $1+(x/n)$ is an upper bound for $S.$ For, if $t>1+x/n,$ then

Now let $y=supS,$ and let us show that $y^n=x.$ We rule out the other two possibilities. First, if $y^n>x,$ let $ϵ$ be the positive number $y^n-x,$ and define ${ϵ}^{\text{'}}$ to be the positive number $ϵ/\left(n{y}^{n-1}\right).$ Then, using [link] , choose $t\in S$ so that $y-{ϵ}^{\text{'}}<t\le y.$ ( [link] is where the completeness of the ordered field $R$ is crucial.) We have

and this is a contradiction. Therefore, $y^n$ is not greater than $x.$

Now, if $y^n<x,$ let $ϵ$ be the positive number $x-y^n,$ and choose a $\delta >0$ such that $\delta <1$ and $\delta <ϵ/{(y+1)}^n.$ Then, using the Binomial Theorem, we have that

implying that $y+\delta \in S.$ But this is a contradiction, since $y=supS.$ Therefore, $y^n$ is not less than $x,$ and so $y^n=x.$

We have shown the existence of a positive $n$ th root of $x.$ To see the uniqueness, suppose $y$ and $y^{\text{'}}$ are two positive $n$ th roots of $x.$ Then

which implies that either $y-y^{\text{'}}=0$ or ${\sum }_{j=0}^{n-1}{y}^j{y^{\text{'}}}^{n-j-1}=0.$ Since this latter sum consists of positive terms, it cannot be 0, whence $y=y^{\text{'}}.$ This shows that there is but one positive $n$ th root of $x,$ and the theorem is proved.