Lucas sequence

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In mathematics, a Lucas sequence is a particular generalisation of sequences like the Fibonacci numbers, Lucas numbers, Pell numbers or Jacobsthal numbers. Lucas sequences have one common characteristic: they can be generated over quadratic equations of the form: $\scriptstyle x^{2}-Px+Q=0\$ with $\scriptstyle P^{2}-4Q\neq 0$ .

There exist two kinds of Lucas sequences:

Sequences $\scriptstyle U(P,Q)=(U_{n}(P,Q))_{n\geq 0}$ with $\scriptstyle U_{n}(P,Q)={\frac {a^{n}-b^{n}}{a-b}}$ ,
Sequences $\scriptstyle V(P,Q)=(V_{n}(P,Q))_{n\geq 0}$ with $\scriptstyle V_{n}(P,Q)=a^{n}+b^{n}\$ ,

where $\scriptstyle a\$ and $b\$ are the solutions

a={\frac {P+{\sqrt {P^{2}-4Q}}}{2}}

and

b={\frac {P-{\sqrt {P^{2}-4Q}}}{2}}

of the quadratic equation $\scriptstyle x^{2}-Px+Q=0$ .

Properties

The variables $\scriptstyle a\$ and $\scriptstyle b\$ , and the parameter $\scriptstyle P\$ and $\scriptstyle Q\$ are interdependent. In particular, $\scriptstyle P=a+b\$ and $\scriptstyle Q=a\cdot b.$ .
For every sequence $\scriptstyle U(P,Q)=(U_{n}(P,Q))_{n\geq 0}$ it holds that $\scriptstyle U_{0}=0\$ and $U_{1}=1$ .
For every sequence $\scriptstyle V(P,Q)=(V_{n}(P,Q))_{n\geq 0}$ is holds that $\scriptstyle V_{0}=2\$ and $V_{1}=P$ .

For every Lucas sequence the following are true:

$\scriptstyle U_{2n}=U_{n}\cdot V_{n}\$
$\scriptstyle V_{n}=U_{n+1}-QU_{n-1}\$
$\scriptstyle V_{2n}=V_{n}^{2}-2Q^{n}\$
$\scriptstyle \operatorname {gcd} (U_{m},U_{n})=U_{\operatorname {gcd} (m,n)}$
$\scriptstyle m\mid n\implies U_{m}\mid U_{n}$ for all $\scriptstyle U_{m}\neq 1$

Recurrence relation

The Lucas sequences U(P,Q) and V(P,Q) are defined by the recurrence relations

U_{0}(P,Q)=0\,

U_{1}(P,Q)=1\,

U_{n}(P,Q)=PU_{n-1}(P,Q)-QU_{n-2}(P,Q){\mbox{  for }}n>1\,

and

V_{0}(P,Q)=2\,

V_{1}(P,Q)=P\,

V_{n}(P,Q)=PV_{n-1}(P,Q)-QV_{n-2}(P,Q){\mbox{  for }}n>1\,

Fibonacci numbers and Lucas numbers

The two best known Lucas sequences are the Fibonacci numbers $\scriptstyle U(1,-1)\$ and the Lucas numbers $\scriptstyle V(1,-1)\$ with $\scriptstyle a={\frac {1+{\sqrt {5}}}{2}}$ and $\scriptstyle b={\frac {1-{\sqrt {5}}}{2}}$ .

Lucas sequences and the prime numbers

If the natural number $\scriptstyle p\$ is a prime number then it holds that

$\scriptstyle p\$ divides $\scriptstyle U_{p}(P,Q)-\left({\frac {D}{p}}\right)$
$\scriptstyle p\$ divides $\scriptstyle V_{p}(P,Q)-P\$

Fermat's Little Theorem can then be seen as a special case of $\scriptstyle p\$ divides $\scriptstyle (V_{n}(P,Q)-P)\$ because $\scriptstyle a^{p}\equiv a{\pmod {p}}$ is equivalent to $\scriptstyle V_{p}(a+1,a)\equiv V_{1}(a+1,a){\pmod {p}}$ .

The converse pair of statements that if $\scriptstyle n\$ divides $\scriptstyle U_{n}(P,Q)-\left({\frac {D}{n}}\right)$ then is $\scriptstyle n\$ a prime number and if $m\$ divides $\scriptstyle V_{m}(P,Q)-P\$ then is $m\$ a prime number) are individually false and lead to Fibonacci pseudoprimes and Lucas pseudoprimes, respectively.

Lucas sequence

Contents

Properties

Recurrence relation

Fibonacci numbers and Lucas numbers

Lucas sequences and the prime numbers

Further reading

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Lucas sequence

Properties

Recurrence relation

Fibonacci numbers and Lucas numbers

Lucas sequences and the prime numbers

Further reading

Navigation menu

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