Lucas sequence: Difference between revisions

Lucas sequences are the particular generalisation of sequences like Fibonacci numbers, Lucas numbers, Pell numbers or Jacobsthal numbers. Every of this sequences has one common factor. They could be generatet over quadratic Equations of the form: ${\displaystyle x^{2}-Px+Q=0\ }$.

There exists kinds of Lucas sequences:

• Sequence ${\displaystyle U(P,Q)=(U_{n}(P,Q))_{n\geq 1}}$ with ${\displaystyle U_{n}(P,Q)={\frac {a^{n}-b^{n}}{a-b}}}$
• Sequence ${\displaystyle V(P,Q)=(V_{n}(P,Q))_{n\geq 1}}$ with ${\displaystyle U_{n}(P,Q)=a^{n}+b^{n}\ }$

${\displaystyle a\ }$ and ${\displaystyle b\ }$ are the solutions ${\displaystyle a={\frac {P+{\sqrt {P^{2}-4Q}}}{2}}}$ and ${\displaystyle b={\frac {P-{\sqrt {P^{2}-4Q}}}{2}}}$ of the quadratic equation ${\displaystyle x^{2}-Px+Q=0\ }$.

Properties

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

For every Lucas sequence is true that

• ${\displaystyle U_{2n}=U_{n}\cdot V_{n}\ }$
• ${\displaystyle V_{n}=U_{n+1}-QU_{n-1}\ }$
• ${\displaystyle V_{2n}=V_{n}^{2}-2Q^{n}\ }$
• ${\displaystyle \operatorname {ggT} (U_{m},U_{n})=U_{\operatorname {ggT} (m,n)}}$
• ${\displaystyle m\mid n\implies U_{m}\mid U_{n}}$; für alle ${\displaystyle U_{m}\neq 1}$

Fibonacci numbers and Lucas numbers

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

Lucas sequences and the Prime numbers

Is the natural number ${\displaystyle p\ }$ a Prime number, then it is true, that

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

Fermat's little theorem you can see as a special case of ${\displaystyle p\ }$ divides ${\displaystyle (V_{n}(P,Q)-P)\ }$ because ${\displaystyle a^{p}\equiv a\mod p}$ is äquivalent to ${\displaystyle V_{p}(a+1,a)\equiv V_{1}(a+1,a)\mod p}$

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

Further reading

• The new Book of Primenumber Records, Paolo Ribenboim, ISBN 0-387-94457-5
• My Numbers, my Friends, Paolo Ribenboim, ISBN 0-387-98911-0