imported>Karsten Meyer |
imported>Aleksander Stos |
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| *If <math>\ m</math> divides <math>\ n\ </math> then <math>\ F_m\ </math> divides <math>\ F_n\ </math> | | *If <math>\ m</math> divides <math>\ n\ </math> then <math>\ F_m\ </math> divides <math>\ F_n\ </math> |
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| *If <math>\ F_p\ </math> is a prime number, greater 3, then <math>\ p</math> is prime. (The converse is false.) | | *If <math>\ F_p\ </math> is a prime number greater than 3, then <math>\ p</math> is prime. (The converse is false.) |
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Revision as of 07:53, 30 December 2007
In mathematics, the Fibonacci numbers form a sequence defined by the following recurrence relation:
The sequence of fibonacci numbers start: 0, 1, 1, 2, 3, 5, 8, 13, 21, 34, 55, 89, 144, 233, ...
The sequence of Fibonacci numbers was first used to represent the growth of a colony of rabbits, starting with a single pair of rabbits.
Properties
We will apply the following simple observation to Fibonacci numbers:
if three integers satisfy equality then
Indeed,
and the rest is an easy induction.
- for all integers such that
Indeed, the equality holds for and the rest is a routine induction on
Next, since , the above equality implies:
which, via Euclid algorithm, leads to:
Let's note the two instant corollaries of the above statement:
- If divides then divides
- If is a prime number greater than 3, then is prime. (The converse is false.)
We have
for every .
Indeed, let and . Let
Then:
- and
- hence
- hence
for every . Thus for every and the formula is proved.
Furthermore, we have:
It follows that
- is the nearest integer to
for every . The above constant is known as the famous golden ratio Thus:
Further reading