We now pass on to a generalization of the idea of a series, which mathematics, true to its method, makes by use of the variable. Hitherto, we have only contemplated series in which each definite term was a definite number. But equally well we can generalize, and make each term to be some mathematical expression containing a variable . Thus we may consider the series , , , , , , , and the series
In order to symbolize the general idea of any such function, conceive of a function of , say, which involves in its formation a variable integer , then, by giving the
values , , , etc., in succession, we get the series Such a series may be convergent for some values of and divergent for others. It is, in fact, rather rare to find a series involving a variable which is convergent for all values of ,–-at least in any particular instance it is very unsafe to assume that this is the case. For example, let us examine the simplest of all instances, namely, the "geometrical"
series The sum of terms is given by
Now multiply both sides by and we get Now subtract the last line from the upper line and we get and hence (if be not equal to ) Now if be numerically less than , for sufficiently large values of , is always numerically
less than , however be chosen. Thus, if be numerically less than , the series , , , , , is convergent, and is its limit. This statement is symbolized by But if is numerically greater than , or numerically equal to , the series is divergent. In other words, if lie between and , the series is convergent; but if be equal to or , or if lie outside the interval to , then the series is divergent. Thus the series is convergent at all "points" within the interval to , exclusive of the end points.
At this stage of our enquiry another question arises. Suppose that the series is convergent for all values of lying within the interval to , i.e. the series is convergent for any value of which is greater than and less than . Also, suppose we want to be sure that in approximating to the limit we add together enough terms to come within some standard of approximation . Can we always state some number of terms, say , such that, if we take or more terms to form the sum, then whatever value has
within the interval we have satisfied the desired standard of approximation?
Sometimes we can and sometimes we cannot
do this for each value of . When we can, the series is called uniformly convergent throughout the interval, and when we cannot do so, the series is called non-uniformly convergent throughout the interval. It makes a great difference to the properties of a series whether it is or is not uniformly convergent through an interval. Let us illustrate the matter by the simplest example and the simplest numbers.