Geometric sequence: Difference between revisions

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imported>Peter Schmitt
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imported>Peter Schmitt
(→‎Sum: wrong i changed to n in formula)
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The sum (of the elements) of a finite geometric sequence is
The sum (of the elements) of a finite geometric sequence is
: <math> a_1 + a_2 +\cdots+ a_n = \sum_{i=1}^n a_i
: <math> a_1 + a_2 +\cdots+ a_n = \sum_{i=1}^n a_i
       = a_1 ( 1+q+q^2+ \cdots +q^{i-1} )
       = a_1 ( 1+q+q^2+ \cdots +q^{n-1} )
       = a_1 { 1-q^i \over 1-q }
       = a_1 { 1-q^n \over 1-q }
</math>
</math>



Revision as of 12:38, 9 January 2010

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A geometric sequence is a (finite or infinite) sequence of (real or complex) numbers such that the quotient of consecutive elements is the same for every pair.

Examples for geometric sequences are

  • (finite, length 6: 6 elements, quotient 2)
  • (finite, length 4: 4 elements, quotient −2)
  • (infinite, quotient )

Mathematical notation

A finite sequence

or an infinite sequence

is called geometric sequence if

for all indices i. (The indices need not start at 0 or 1.)

General form

Thus, the elements of a geometric sequence can be written as

Sum

The sum (of the elements) of a finite geometric sequence is

The sum of an infinite geometric sequence is a geometric series: