Series (mathematics): Difference between revisions
imported>Catherine Woodgold (minor changes in punctuation and wording) |
imported>Aleksander Stos m (a_n appears out of blue and is not really needed IMHO) |
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For example, given the sequence of the natural numbers 1, 2, 3, ..., the series is 1, 1 + 2, 1 + 2 + 3, ... | For example, given the sequence of the natural numbers 1, 2, 3, ..., the series is 1, 1 + 2, 1 + 2 + 3, ... | ||
According to the number of terms, the series may be finite or infinite. The former is relatively easy to deal with. In fact, the finite series is identified with the sum of all terms and — apart from the elementary algebra — there is no particular theory that applies. It turns out, however, that much care is required when manipulating infinite series. For example, some simple operations borrowed from elementary algebra — such as a change of order of the terms | According to the number of terms, the series may be finite or infinite. The former is relatively easy to deal with. In fact, the finite series is identified with the sum of all terms and — apart from the elementary algebra — there is no particular theory that applies. It turns out, however, that much care is required when manipulating infinite series. For example, some simple operations borrowed from elementary algebra — such as a change of order of the terms often lead to unexpected results. So it is sometimes tacitly understood, especially in [[mathematical analysis|analysis]], that the term "series" refers to the infinite series. In what follows we adopt this convention and concentrate on the theory of the infinite case. | ||
==Formal definition== | ==Formal definition== |
Revision as of 08:50, 30 May 2007
In mathematics, a series is the cumulative sum of a given sequence of terms. Typically, these terms are real or complex numbers, but much more generality is possible.
For example, given the sequence of the natural numbers 1, 2, 3, ..., the series is 1, 1 + 2, 1 + 2 + 3, ...
According to the number of terms, the series may be finite or infinite. The former is relatively easy to deal with. In fact, the finite series is identified with the sum of all terms and — apart from the elementary algebra — there is no particular theory that applies. It turns out, however, that much care is required when manipulating infinite series. For example, some simple operations borrowed from elementary algebra — such as a change of order of the terms often lead to unexpected results. So it is sometimes tacitly understood, especially in analysis, that the term "series" refers to the infinite series. In what follows we adopt this convention and concentrate on the theory of the infinite case.
Formal definition
Given a sequence of elements that can be added, let
Then, the series is defined as the sequence and denoted by [1] For a single n, the sum is called the partial sum of the series.
If the sequence has a finite limit, the series is said to be convergent. In this case we define the sum of the series as
Note that the sum (i.e. the numeric value of the above limit) and the series (i.e. the sequence ) are usually denoted by the same symbol. If the above limit does not exist - or is infinite - the series is said to be divergent.
References
- ↑ Other popular (equivalent) definition describes the series as a formal (ordered) list of terms combined by the addition operator