Cassini and Catalan identities: Difference between revisions

Template:Short description Cassini's identity (sometimes called Simson's identity) and Catalan's identity are mathematical identities for the Fibonacci numbers. Cassini's identity, a special case of Catalan's identity, states that for the nth Fibonacci number,

${\displaystyle F_{n-1}{F}_{n+1}-F_n^2=(-1{)}^n.}$

Note here ${\displaystyle F_0}$ is taken to be 0, and ${\displaystyle F_1}$ is taken to be 1.

Catalan's identity generalizes this:

${\displaystyle F_n^2-F_{n-r}{F}_{n+r}=(-1{)}^{n-r}{F}_r^2.}$

Vajda's identity generalizes this:

${\displaystyle F_{n+i}{F}_{n+j}-F_n{F}_{n+i+j}=(-1{)}^n{F}_i{F}_j.}$

Cassini's formula was discovered in 1680 by Giovanni Domenico Cassini, then director of the Paris Observatory, and independently proven by Robert Simson (1753).^[1] However Johannes Kepler presumably knew the identity already in 1608.^[2]

Catalan's identity is named after Eugène Catalan (1814–1894). It can be found in one of his private research notes, entitled "Sur la série de Lamé" and dated October 1879. However, the identity did not appear in print until December 1886 as part of his collected works Template:Harv. This explains why some give 1879 and others 1886 as the date for Catalan's identity Template:Harv.

The Hungarian-British mathematician Steven Vajda (1901–95) published a book on Fibonacci numbers (Fibonacci and Lucas Numbers, and the Golden Section: Theory and Applications, 1989) which contains the identity carrying his name.^[3][4] However, the identity had been published earlier in 1960 by Dustan Everman as problem 1396 in The American Mathematical Monthly,^[1] and in 1901 by Alberto Tagiuri in Periodico di Matematica.^[5]

A quick proof of Cassini's identity may be given Template:Harv by recognising the left side of the equation as a determinant of a 2×2 matrix of Fibonacci numbers. The result is almost immediate when the matrix is seen to be the Template:Mathth power of a matrix with determinant −1:

${\displaystyle F_{n-1}{F}_{n+1}-F_n^2=\det \left[\begin{array}{cc}{F}_{n+1}& F_n\\ F_n& F_{n-1}\end{array}\right]=\det {\left[\begin{array}{cc}1& 1\\ 1& 0\end{array}\right]}^n={(\det \left[\begin{array}{cc}1& 1\\ 1& 0\end{array}\right])}^n=(-1{)}^n.}$

Consider the induction statement:

${\displaystyle F_{n-1}{F}_{n+1}-F_n^2=(-1{)}^n}$

The base case ${\displaystyle n=1}$ is true.

Assume the statement is true for ${\displaystyle n}$. Then:

${\displaystyle F_{n-1}{F}_{n+1}-F_n^2+F_n{F}_{n+1}-F_n{F}_{n+1}=(-1{)}^n}$

${\displaystyle F_{n-1}{F}_{n+1}+F_n{F}_{n+1}-F_n^2-F_n{F}_{n+1}=(-1{)}^n}$

${\displaystyle F_{n+1}(F_{n-1}+F_n)-F_n(F_n+F_{n+1})=(-1{)}^n}$

${\displaystyle F_{n+1}^2-F_n{F}_{n+2}=(-1{)}^n}$

${\displaystyle F_n{F}_{n+2}-F_{n+1}^2=(-1{)}^{n+1}}$

so the statement is true for all integers ${\displaystyle n>0}$.

We use Binet's formula, that ${\displaystyle F_n=\frac{{\varphi }^n-{\psi }^n}{\sqrt{5}}}$, where ${\displaystyle \varphi =\frac{1+\sqrt{5}}{2}}$ and ${\displaystyle \psi =\frac{1-\sqrt{5}}{2}}$.

Hence, ${\displaystyle \varphi +\psi =1}$ and ${\displaystyle \varphi \psi =-1}$.

So,

${\displaystyle 5(F_n^2-F_{n-r}{F}_{n+r})}$

${\displaystyle =({\varphi }^n-{\psi }^n{)}^2-({\varphi }^{n-r}-{\psi }^{n-r})({\varphi }^{n+r}-{\psi }^{n+r})}$

${\displaystyle =({\varphi }^{2n}-2{\varphi }^n{\psi }^n+{\psi }^{2n})-({\varphi }^{2n}-{\varphi }^n{\psi }^n({\varphi }^{-r}{\psi }^r+{\varphi }^r{\psi }^{-r})+{\psi }^{2n})}$

${\displaystyle =-2{\varphi }^n{\psi }^n+{\varphi }^n{\psi }^n({\varphi }^{-r}{\psi }^r+{\varphi }^r{\psi }^{-r})}$

Using ${\displaystyle \varphi \psi =-1}$,

${\displaystyle =-(-1{)}^{n}2+(-1{)}^n({\varphi }^{-r}{\psi }^r+{\varphi }^r{\psi }^{-r})}$

and again as ${\displaystyle \varphi =\frac{-1}{\psi }}$,

${\displaystyle =-(-1{)}^{n}2+(-1{)}^{n-r}({\psi }^{2r}+{\varphi }^{2r})}$

The Lucas number ${\displaystyle L_n}$ is defined as ${\displaystyle L_n={\varphi }^n+{\psi }^n}$, so

${\displaystyle =-(-1{)}^{n}2+(-1{)}^{n-r}{L}_{2r}}$

Because ${\displaystyle L_{2n}=5F_n^2+2(-1{)}^n}$

${\displaystyle =-(-1{)}^{n}2+(-1{)}^{n-r}(5F_r^2+2(-1{)}^r)}$

${\displaystyle =-(-1{)}^{n}2+(-1{)}^{n-r}2(-1{)}^r+(-1{)}^{n-r}5F_r^2}$

${\displaystyle =-(-1{)}^{n}2+(-1{)}^{n}2+(-1{)}^{n-r}5F_r^2}$

${\displaystyle =(-1{)}^{n-r}5F_r^2}$

Cancelling the ${\displaystyle 5}$'s gives the result.

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• Proof of Cassini's identity
• Proof of Catalan's Identity
• Cassini formula for Fibonacci numbers
• Fibonacci and Phi Formulae