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In mathematics, the Fibonacci numbers form a sequence defined by the following recurrence relation:

${\displaystyle F_{n}:={\begin{cases}0&{\mbox{if }}n=0;\\1&{\mbox{if }}n=1;\\F_{n-1}+F_{n-2}&{\mbox{if }}n>1.\\\end{cases}}}$

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 ${\displaystyle \ a,b,c,}$  satisfy equality ${\displaystyle \ c=a+b,}$  then

${\displaystyle \ \gcd(a,b)\ =\ \gcd(a,c)=\gcd(b,c).}$

• ${\displaystyle \gcd \left(F_{n},F_{n+1}\right)\ =\ \gcd \left(F_{n},F_{n+2}\right)\ =\ 1}$

Indeed,

${\displaystyle \gcd \left(F_{0},F_{1}\right)\ =\ \gcd \left(F_{0},F_{2}\right)\ =\ 1}$

and the rest is an easy induction.

• ${\displaystyle F_{n}\ =\ F_{k+1}\cdot F_{n-k}+F_{k}\cdot F_{n-k-1}}$

for all integers ${\displaystyle \ k,n,}$  such that ${\displaystyle \ 0\leq k<n.}$

Indeed, the equality holds for ${\displaystyle \ k=0,}$  and the rest is a routine induction on ${\displaystyle \ k.}$

Next, since ${\displaystyle \gcd \left(F_{k},F_{k+1}\right)=1}$,  the above equality implies:

${\displaystyle \gcd \left(F_{k},F_{n}\right)\ =\ \gcd \left(F_{k},F_{n-k}\right)}$

which, via Euclid algorithm, leads to:

• ${\displaystyle \gcd(F_{m},F_{n})\ =\ F_{\gcd(m,n)}}$

Let's note the two instant corollaries of the above statement:

• If ${\displaystyle \ m}$  divides ${\displaystyle \ n\ }$ then ${\displaystyle \ F_{m}\ }$ divides ${\displaystyle \ F_{n}\ }$

• If ${\displaystyle \ F_{p}\ }$  is a prime number then ${\displaystyle \ p}$  is prime. (The converse is false.)

• ${\displaystyle \sum _{i=0}^{n}F_{i}^{2}=F_{n}\cdot F_{n+1}}$

Direct formula and the golden ratio

We have

${\displaystyle F_{n}\ =\ {\frac {1}{\sqrt {5}}}\cdot \left(\left({\frac {1+{\sqrt {5}}}{2}}\right)^{n}-\left({\frac {1-{\sqrt {5}}}{2}}\right)^{n}\right)}$

for every ${\displaystyle \ n=0,1,\dots }$ .

Indeed, let  ${\displaystyle A:={\frac {1+{\sqrt {5}}}{2}}}$  and  ${\displaystyle a:={\frac {1-{\sqrt {5}}}{2}}}$ .  Let

${\displaystyle f_{n}\ :=\ {\frac {1}{\sqrt {5}}}\cdot (A^{n}-a^{n})}$

Then:

• ${\displaystyle f_{0}=0\ }$     and     ${\displaystyle \ f_{1}=1}$
• ${\displaystyle A^{2}=A+1\ }$     hence     ${\displaystyle \ A^{n+2}=A^{n+1}+A^{n}}$
• ${\displaystyle a^{2}=a+1\ }$     hence     ${\displaystyle a^{n+2}=a^{n+1}+a^{n}\ }$
• ${\displaystyle f_{n+2}\ =\ f_{n+1}+f_{n}}$

for every ${\displaystyle \ n=0,1,\dots }$. Thus ${\displaystyle \ f_{n}=F_{n}}$  for every ${\displaystyle \ n=0,1,\dots ,}$ and the formula is proved.

Furthermore, we have:

• ${\displaystyle A\cdot a=-1\ }$
• ${\displaystyle A>1\ }$
• ${\displaystyle -1<a<0\ }$
• ${\displaystyle {\frac {1}{2}}\ >\ \left|{\frac {1}{\sqrt {5}}}\cdot a^{n}\right|\quad \rightarrow \quad 0}$

It follows that

${\displaystyle F_{n}\ }$  is the nearest integer to  ${\displaystyle {\frac {1}{\sqrt {5}}}\cdot \left({\frac {1+{\sqrt {5}}}{2}}\right)^{n}}$

for every ${\displaystyle \ n=0,1,\dots }$ . The above constant ${\displaystyle \ A}$  is known as the famous golden ratio ${\displaystyle \ \Phi .}$  Thus:

${\displaystyle \Phi \ =\ \lim _{n\to \infty }{\frac {F(n+1)}{F(n)}}\ =\ {\frac {1+{\sqrt {5}}}{2}}}$

Further reading

• John H. Conway und Richard K. Guy, The Book of Numbers, ISBN 0-387-97993-X