Recurrence relation: Difference between revisions
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A '''recurrence relation''' is a relation between an entry in a [[sequence]] of [[number]]s or other mathematical objects and preceding entries in the sequence. | A '''recurrence relation''' is a relation between an entry in a [[sequence]] of [[number]]s or other mathematical objects and preceding entries in the sequence. An ''explicit'' relation is one in which a term is defined in terms of preceding values, as opposed to an ''implicit'' definition. | ||
For example, assume that you put 100 dollars on a bank account and that the bank pays you 6% [[interest]] every year. After one year, you will have the original 100 dollars plus 6 dollars interest, which makes 106 dollars. After two years, you have $ 112.06 (the 106 dollars you have after one year, plus 6% of $ 106 interest). The amount you have in your account grows according to the sequence 100, 106, 112.06, 118.18, …. This sequence is defined by the rule that every year you have the same amount as the previous year plus 6% of what you had the previous year. This is a recurrence relation in words. However, recurrence relations are usually formulated as a mathematical formula. As a first step, we can rewrite the rule as: in year ''n'' + 1, you have the same amount as in year ''n'' plus 6% of what you had in year ''n''. Now, introduce the symbol ''a''<sub>''n''</sub> to stand for the amount in the account in year ''n''. Then, the recurrence relation becomes ''a''<sub>''n''+1</sub> = ''a''<sub>''n''</sub> + 0.06''a''<sub>''n''</sub>. | For example, assume that you put 100 dollars on a bank account and that the bank pays you 6% [[compound interest]] every year. After one year, you will have the original 100 dollars plus 6 dollars interest, which makes 106 dollars. After two years, you have $ 112.06 (the 106 dollars you have after one year, plus 6% of $ 106 interest). The amount you have in your account grows according to the sequence 100, 106, 112.06, 118.18, …. This sequence is defined by the rule that every year you have the same amount as the previous year plus 6% of what you had the previous year. This is a recurrence relation in words. However, recurrence relations are usually formulated as a mathematical formula. As a first step, we can rewrite the rule as: in year ''n'' + 1, you have the same amount as in year ''n'' plus 6% of what you had in year ''n''. Now, introduce the symbol ''a''<sub>''n''</sub> to stand for the amount in the account in year ''n''. Then, the recurrence relation becomes ''a''<sub>''n''+1</sub> = ''a''<sub>''n''</sub> + 0.06''a''<sub>''n''</sub>. This is an explicit relation because the next term in the sequence is given as a function of preceding terms (here in fact just one preceding term.) The solution to this relation is ''a''<sub>''n''</sub> = (1.06)<sup>''n''</sup>''a''<sub>0</sub>, where ''a''<sub>0</sub> is the initial amount, here $100. | ||
==Examples== | |||
The [[factorial]] function satisfies the relation | |||
:<math> n! = n \cdot (n-1)! \,</math> | |||
The [[Fibonacci number]]s satisfy a recurrence relation in which each term depends on the two preceding, so the first two values need to be specified to make the definition complete: | |||
:<math> | |||
F_n := | |||
\begin{cases} | |||
0 & \mbox{if } n = 0; \\ | |||
1 & \mbox{if } n = 1; \\ | |||
F_{n-1}+F_{n-2} & \mbox{if } n > 1. \\ | |||
\end{cases} | |||
</math> | |||
More generally, a [[Lucas sequence]] satisfies | |||
:<math>X_n(P,Q)=P X_{n-1}(P,Q)-Q X_{n-2}(P,Q) \,</math> | |||
for constants ''P'' and ''Q''. | |||
An example of a recurrence relation with more than one variable is given by the [[binomial coefficient]]s | |||
:<math> \binom{n}{r} = \binom{n-1}{r} + \binom{n-1}{r-1} </math> | |||
which gives the rule of formation of [[Pascal's triangle]], where the values on the ''n''-th row depend on the values on the row above, with the further conditions | |||
:<math>\binom{n}{0} = \binom{n}{n} = 1 .\,</math> | |||
The [[Somos sequence]] is defined by the implicit relation | |||
:<math>a_n a_{n-4} = a_{n-1}a_{n-3} + a_{n-2}^2 </math> | |||
which rather surprisingly generates a sequence of integers from the starting values 1,1,1,1.[[Category:Suggestion Bot Tag]] |
Latest revision as of 11:01, 10 October 2024
A recurrence relation is a relation between an entry in a sequence of numbers or other mathematical objects and preceding entries in the sequence. An explicit relation is one in which a term is defined in terms of preceding values, as opposed to an implicit definition.
For example, assume that you put 100 dollars on a bank account and that the bank pays you 6% compound interest every year. After one year, you will have the original 100 dollars plus 6 dollars interest, which makes 106 dollars. After two years, you have $ 112.06 (the 106 dollars you have after one year, plus 6% of $ 106 interest). The amount you have in your account grows according to the sequence 100, 106, 112.06, 118.18, …. This sequence is defined by the rule that every year you have the same amount as the previous year plus 6% of what you had the previous year. This is a recurrence relation in words. However, recurrence relations are usually formulated as a mathematical formula. As a first step, we can rewrite the rule as: in year n + 1, you have the same amount as in year n plus 6% of what you had in year n. Now, introduce the symbol an to stand for the amount in the account in year n. Then, the recurrence relation becomes an+1 = an + 0.06an. This is an explicit relation because the next term in the sequence is given as a function of preceding terms (here in fact just one preceding term.) The solution to this relation is an = (1.06)na0, where a0 is the initial amount, here $100.
Examples
The factorial function satisfies the relation
The Fibonacci numbers satisfy a recurrence relation in which each term depends on the two preceding, so the first two values need to be specified to make the definition complete:
More generally, a Lucas sequence satisfies
for constants P and Q.
An example of a recurrence relation with more than one variable is given by the binomial coefficients
which gives the rule of formation of Pascal's triangle, where the values on the n-th row depend on the values on the row above, with the further conditions
The Somos sequence is defined by the implicit relation
which rather surprisingly generates a sequence of integers from the starting values 1,1,1,1.