Difference between revisions of "Geometric sequence"

m
m (added 1965 ahsme #36)
 
(52 intermediate revisions by 15 users not shown)
Line 1: Line 1:
==Definition==
+
In [[algebra]], a '''geometric sequence''', sometimes called a '''geometric progression''', is a [[sequence]] of numbers such that the ratio between any two consecutive terms is constant. This constant is called the '''common ratio''' of the sequence.
  
A geometric sequence is a sequence of numbers where the nth term of the sequence is a multiple of the previous term.  For example: 1, 2, 4, 8, 16, 32, ...  is a geometric sequence because each term is twice the previous term.  In this case, 2 is called the common ratio of the sequence.
+
For example, <math>1, 2, 4, 8</math> is a geometric sequence with common ratio <math>2</math> and <math>100, -50, 25, -25/2</math> is a geometric sequence with common ratio <math>-1/2</math>; however, <math>1, 3, 9, -27</math> and <math>-3, 1, 5, 9, \ldots</math> are not geometric sequences, as the ratio between consecutive terms varies.
  
==Summing a Geometric Sequence==
+
More formally, the sequence <math>a_1, a_2, \ldots , a_n</math> is a geometric progression if and only if <math>a_2 / a_1 = a_3 / a_2 = \cdots = a_n / a_{n-1}</math>. A similar definition holds for infinite geometric sequences. It appears most frequently in its three-term form: namely, that constants <math>a</math>, <math>b</math>, and <math>c</math> are in geometric progression if and only if <math>b / a = c / b</math>.
  
The sum of the first <math>n</math> terms of a geometric sequence is given by
+
== Properties ==
 +
Because each term is a common multiple of the one before it, every term of a geometric sequence can be expressed as the sum of the first term and a multiple of the common ratio. Let <math>a_1</math> be the first term, <math>a_n</math> be the <math>n</math>th term, and <math>r</math> be the common ratio of any geometric sequence; then, <math>a_n = a_1 r^{n-1}</math>.
  
<math>S_n = \frac{a_1(r^{n+1}-1)}{r-1}</math>
+
A common lemma is that a sequence is in geometric progression if and only if <math>a_n</math> is the [[geometric mean]] of <math>a_{n-1}</math> and <math>a_{n+1}</math> for any consecutive terms <math>a_{n-1}, a_n, a_{n+1}</math>. In symbols, <math>a_n^2 = a_{n-1}a_{n+1}</math>. This is mostly used to perform substitutions, though it occasionally serves as a definition of geometric sequences.
  
where <math>a_1</math> is the first term in the sequence, and <math>r</math> is the common ratio.
+
== Sum ==
 +
A '''geometric series''' is the sum of all the terms of a geometric sequence. They come in two varieties, both of which have their own formulas: finitely or infinitely many terms.
  
==Infinate Geometric Sequences==
+
=== Finite ===
 +
A finite geometric series with first term <math>a_1</math>, common ratio <math>r</math> not equal to one, and <math>n</math> total terms has a value equal to <math>\frac{a_1(r^n-1)}{r-1}</math>.
  
An infinate geometric sequence is a geometric sequence with an infinate number of terms. These sequences can have sums, sometimes called limits, if <math>|r|<1</math>.
+
'''Proof''': Let the geometric series have value <math>S</math>. Then <cmath>S = a_1 + a_1r + a_1r^2 + \cdots + a_1r^{n-1}.</cmath> Factoring out <math>a_1</math>, mulltiplying both sides by <math>(r-1)</math>, and using the [[Sum and difference of powers | difference of powers]] factorization yields <cmath>S(r-1) = a_1(r-1)(1 + r + r^2 + \cdots + r^{n-1}) = a_1(r^n-1).</cmath> Dividing both sides by <math>r-1</math> yields <math>S=\frac{a_1(r^n-1)}{r-1}</math>, as desired. <math>\square</math>
  
For instance, the series <math>1 + \frac12 + \frac14 + \frac18 + ...</math>, sums to 2. The general fromula for the sum of such a sequence is:
+
=== Infinite ===
 +
An infinite geometric series converges if and only if <math>|r|<1</math>; if this condition is satisfied, the series [[Convergent | converges]] to <math>\frac{a_1}{1-r}</math>.
  
<math>S = \frac{a_1}{1-r}</math>
+
'''Proof''': The proof that the series convergence if and only if <math>|r|<1</math> is an easy application of the ratio test from calculus; thus, such a proof is beyond the scope of this article. If one assumes convergence, there is an elementary proof of the formula that uses [[Telescoping series|telescoping]]. Using the terms defined above, <cmath>S = a_1 + a_1r + a_1r^2 + \cdots.</cmath> Multiplying both sides by <math>r</math> and adding <math>a_1</math>, we find that <cmath>rS + a_1 = a_1 + r(a_1 + a_1r + \cdots) = a_1 + a_1r + a_1r^2 + \cdots = S.</cmath> Thus, <math>rS + a_1 = S</math>, and so <math>S = \frac{a_1}{1-r}</math>. <math>\square</math>
  
Again, <math>a_1</math> is the first term in the sequence, and <math>r</math> is the common ratio.
+
== Problems ==
 +
Here are some problems with solutions that utilize geometric sequences and series.
  
==See Also==
+
=== Intermediate ===
[[arithmetic sequence|Arithmetic Sequences]]
+
* [[1965 AHSME Problems/Problem 36 | 1965 AHSME Problem 36]]
 +
* [[2005_AIME_II_Problems/Problem_3 | 2005 AIME II Problem 3]]
 +
* [[2007 AIME II Problems/Problem 12 | 2007 AIME II Problem 12]]
 +
 
 +
== See also ==
 +
* [[Arithmetic sequence]]
 +
* [[Harmonic sequence]]
 +
* [[Sequence]]
 +
* [[Series]]
 +
 
 +
[[Category:Algebra]] [[Category:Sequences and series]] [[Category:Definition]]

Latest revision as of 20:09, 19 July 2024

In algebra, a geometric sequence, sometimes called a geometric progression, is a sequence of numbers such that the ratio between any two consecutive terms is constant. This constant is called the common ratio of the sequence.

For example, $1, 2, 4, 8$ is a geometric sequence with common ratio $2$ and $100, -50, 25, -25/2$ is a geometric sequence with common ratio $-1/2$; however, $1, 3, 9, -27$ and $-3, 1, 5, 9, \ldots$ are not geometric sequences, as the ratio between consecutive terms varies.

More formally, the sequence $a_1, a_2, \ldots , a_n$ is a geometric progression if and only if $a_2 / a_1 = a_3 / a_2 = \cdots = a_n / a_{n-1}$. A similar definition holds for infinite geometric sequences. It appears most frequently in its three-term form: namely, that constants $a$, $b$, and $c$ are in geometric progression if and only if $b / a = c / b$.

Properties

Because each term is a common multiple of the one before it, every term of a geometric sequence can be expressed as the sum of the first term and a multiple of the common ratio. Let $a_1$ be the first term, $a_n$ be the $n$th term, and $r$ be the common ratio of any geometric sequence; then, $a_n = a_1 r^{n-1}$.

A common lemma is that a sequence is in geometric progression if and only if $a_n$ is the geometric mean of $a_{n-1}$ and $a_{n+1}$ for any consecutive terms $a_{n-1}, a_n, a_{n+1}$. In symbols, $a_n^2 = a_{n-1}a_{n+1}$. This is mostly used to perform substitutions, though it occasionally serves as a definition of geometric sequences.

Sum

A geometric series is the sum of all the terms of a geometric sequence. They come in two varieties, both of which have their own formulas: finitely or infinitely many terms.

Finite

A finite geometric series with first term $a_1$, common ratio $r$ not equal to one, and $n$ total terms has a value equal to $\frac{a_1(r^n-1)}{r-1}$.

Proof: Let the geometric series have value $S$. Then \[S = a_1 + a_1r + a_1r^2 + \cdots + a_1r^{n-1}.\] Factoring out $a_1$, mulltiplying both sides by $(r-1)$, and using the difference of powers factorization yields \[S(r-1) = a_1(r-1)(1 + r + r^2 + \cdots + r^{n-1}) = a_1(r^n-1).\] Dividing both sides by $r-1$ yields $S=\frac{a_1(r^n-1)}{r-1}$, as desired. $\square$

Infinite

An infinite geometric series converges if and only if $|r|<1$; if this condition is satisfied, the series converges to $\frac{a_1}{1-r}$.

Proof: The proof that the series convergence if and only if $|r|<1$ is an easy application of the ratio test from calculus; thus, such a proof is beyond the scope of this article. If one assumes convergence, there is an elementary proof of the formula that uses telescoping. Using the terms defined above, \[S = a_1 + a_1r + a_1r^2 + \cdots.\] Multiplying both sides by $r$ and adding $a_1$, we find that \[rS + a_1 = a_1 + r(a_1 + a_1r + \cdots) = a_1 + a_1r + a_1r^2 + \cdots = S.\] Thus, $rS + a_1 = S$, and so $S = \frac{a_1}{1-r}$. $\square$

Problems

Here are some problems with solutions that utilize geometric sequences and series.

Intermediate

See also