Sequences:Limits

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diagram of a hexagon and pentagon circumscribed outside a circle
The sequence given by the perimeters of regular n-sided polygons that circumscribe the unit circle has a limit equal to the perimeter of the circle, i.e. The corresponding sequence for inscribed polygons has the same limit.
n n sin(1/n)
1 0.841471
2 0.958851
...
10 0.998334
...
100 0.999983

As the positive integer becomes larger and larger, the value becomes arbitrarily close to We say that "the limit of the sequence equals "

In mathematics, the limit of a sequence is the value that the terms of a sequence "tend to", and is often denoted using the symbol (e.g., ). If such a limit exists, the sequence is called convergent. A sequence that does not converge is said to be divergent. The limit of a sequence is said to be the fundamental notion on which the whole of mathematical analysis ultimately rests.

Limits can be defined in any metric or topological space, but are usually first encountered in the real numbers.

Real numbers

The plot of a convergent sequence {an} is shown in blue. Here, one can see that the sequence is converging to the limit 0 as n increases.

In the real numbers, a number is the limit of the sequence if the numbers in the sequence become closer and closer to —and not to any other number.

Examples

  • If for constant c, then
  • If then
  • If when is even, and when is odd, then (The fact that whenever is odd is irrelevant.)
  • Given any real number, one may easily construct a sequence that converges to that number by taking decimal approximations. For example, the sequence converges to Note that the decimal representation is the limit of the previous sequence, defined by
  • Finding the limit of a sequence is not always obvious. Two examples are (the limit of which is the number e) and the Arithmetic–geometric mean. The squeeze theorem is often useful in the establishment of such limits.

Formal definition

We call the limit of the sequence if the following condition holds:

  • For each real number there exists a natural number such that, for every natural number we have

In other words, for every measure of closeness the sequence's terms are eventually that close to the limit. The sequence is said to converge to or tend to the limit written or

Symbolically, this is:


If a sequence converges to some limit then it is convergent and is the only limit; otherwise is divergent. A sequence that has zero as its limit is sometimes called a null sequence.

Illustration

Properties

Limits of sequences behave well with respect to the usual arithmetic operations. If and then and, if neither b nor any is zero,

For any continuous function f, if then In fact, any real-valued function f is continuous if and only if it preserves the limits of sequences (though this is not necessarily true when using more general notions of continuity).

Some other important properties of limits of real sequences include the following (provided, in each equation below, that the limits on the right exist).

  • The limit of a sequence is unique.
  • provided
  • If for all greater than some then
  • (Squeeze theorem) If for all and then
  • If a sequence is bounded and monotonic, then it is convergent.
  • A sequence is convergent if and only if every subsequence is convergent.
  • If every subsequence of a sequence has its own subsequence which converges to the same point, then the original sequence converges to that point.

These properties are extensively used to prove limits, without the need to directly use the cumbersome formal definition. For example. once it is proven that it becomes easy to show—using the properties above—that (assuming that ).

Infinite limits

A sequence is said to tend to infinity, written or if for every K, there is an N such that for every ; that is, the sequence terms are eventually larger than any fixed K.

Similarly, if for every K, there is an N such that for every If a sequence tends to infinity or minus infinity, then it is divergent. However, a divergent sequence need not tend to plus or minus infinity, and the sequence provides one such example.

Metric spaces

Definition

A point of the metric space is the limit of the sequence if for all there is an such that, for every This coincides with the definition given for real numbers when and

Properties

For any continuous function f, if then In fact, a function f is continuous if and only if it preserves the limits of sequences.

Limits of sequences are unique when they exist, as distinct points are separated by some positive distance, so for less than half this distance, sequence terms cannot be within a distance of both points.

Topological spaces

Definition

A point of the topological space is a limit or limit point of the sequence if for every neighborhood of there exists some such that for every This coincides with the definition given for metric spaces, if is a metric space and is the topology generated by

A limit of a sequence of points in a topological space is a special case of a limit of a function: the domain is in the space with the induced topology of the affinely extended real number system, the range is and the function argument tends to which in this space is a limit point of

Properties

In a Hausdorff space, limits of sequences are unique whenever they exist. Note that this need not be the case in non-Hausdorff spaces; in particular, if two points and are topologically indistinguishable, then any sequence that converges to must converge to and vice versa.

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