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For given $n,\ell\in\mathbb N_0$, I am interested in studying the following recursion relation for some $\mu\in\mathbb R$: $$\sqrt{-1} \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - \sqrt{-1} \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ for $j\ge0$, assuming $a_{-1}=0$.

The trivial solution is $a_j=0,\ \forall j\in\mathbb N_0$. The value of $a_0$ determines the entire sucesion no matter what is $\mu$.

Since this three term recurrence relation is given by matrix valued spherical functions of the symmetric pair $(\mathrm{SO }(4) ,\mathrm{SO }(3) )$ one expects to be solvable by a set of orthogonal polynomials on a finite discrete set, for some $\mu$.

Does anybody recognize this expression or know any family of polynomials solving this?

From already thank you very much.

For given $n,\ell\in\mathbb N_0$, I am interested in studying the following recursion relation for some $\mu\in\mathbb R$: $$\sqrt{-1} \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - \sqrt{-1} \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ for $j\ge0$, assuming $a_{-1}=0$.

The trivial solution is $a_j=0,\ \forall j\in\mathbb N_0$. The value of $a_0$ determines the entire sequence, no matter what is $\mu$.

Since this three term recurrence relation is given by matrix valued spherical functions of the symmetric pair $(\mathrm{SO }(4) ,\mathrm{SO }(3) )$ one expects to be solvable by a set of orthogonal polynomials on a finite discrete set, for some $\mu$.

Does anybody recognize this expression or know any family of polynomials solving this?

From already thank you very much.

For given $n,\ell\in\mathbb N_0$ and $\mu\in\mathbb R$, I am interested in studying the following recursion relation: $$i \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - i \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ for $j\ge0$, assuming $a_{-1}=0$.

The trivial solution is $a_j=0,\ \forall j\in\mathbb N_0$.

Since it is given by matrix valued spherical functions of the simmetric pair $(\mathrm{SO }(4) ,\mathrm{SO }(3) )$ one expects to be solvable by a set of orthogonal polynomials on a finite discrete set.

Does anybody recognize this expression or knows any famous family of polynomials solving this?

From already thank you very much.

For given $n,\ell\in\mathbb N_0$, I am interested in studying the following recursion relation for some $\mu\in\mathbb R$: $$\sqrt{-1} \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - \sqrt{-1} \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ for $j\ge0$, assuming $a_{-1}=0$.

The trivial solution is $a_j=0,\ \forall j\in\mathbb N_0$. The value of $a_0$ determines the entire sucesion no matter what is $\mu$.

Since this three term recurrence relation is given by matrix valued spherical functions of the symmetric pair $(\mathrm{SO }(4) ,\mathrm{SO }(3) )$ one expects to be solvable by a set of orthogonal polynomials on a finite discrete set, for some $\mu$.

Does anybody recognize this expression or know any family of polynomials solving this?

From already thank you very much.

I am interested in studying the following recursion relation: $$i \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - i \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ with $n,\ell\in\mathbb{N}_0$ and $\mu\in\mathbb{R}$.

Does anybody know any famous family of polynomials on a finite discrete set solving this?

From already thank you very much.

For given $n,\ell\in\mathbb N_0$ and $\mu\in\mathbb R$, I am interested in studying the following recursion relation: $$i \tfrac{j(\ell-j+1)(n-j+1)(n+j+1)}{2(2j-1)(2j+1)} a_{j-1} - \tfrac {j(j+1)}2 a_j - i \tfrac{(j+1)(\ell+j+2)}2 a_{j+1} = \mu a_j,$$ for $j\ge0$, assuming $a_{-1}=0$.

The trivial solution is $a_j=0,\ \forall j\in\mathbb N_0$.

Since it is given by matrix valued spherical functions of the simmetric pair $(\mathrm{SO }(4) ,\mathrm{SO }(3) )$ one expects to be solvable by a set of orthogonal polynomials on a finite discrete set.

Does anybody recognize this expression or knows any famous family of polynomials solving this?

From already thank you very much.