| Summary: | We consider the following discrete Sobolev inner product involving the Gegenbauer weight
$$(f,g)_S:=\int_{-1}^1f(x)g(x)(1-x^2)^{\alpha}dx+M\big[f^{(j)}(-1)g^{(j)}(-1)+f^{(j)}(1)g^{(j)}(1)\big],$$
where $\alpha>-1,$ $j\in \mathbb{N}\cup \{0\},$ and $M>0.$ Our main objective is to calculate the exact value
$$r_0 = \lim_{n\rightarrow \infty}\frac{\log \left(\max_{x\in [-1,1]} |\widetilde{Q}_n^{(\alpha,M,j)}(x)|\right)}{\log \widetilde{\lambda}_n}, \quad \alpha\ge -1/2,$$
where $\{\widetilde{Q}_n^{(\alpha,M,j)}\}_{n\geq0}$ is the sequence of orthonormal polynomials with respect to this Sobolev inner product. These polynomials are eigenfunctions of a differential operator and the obtaining of the asymptotic behavior of the corresponding eigenvalues, $\widetilde{\lambda}_n$ , is the principal key to get the result. This value $r_0$ is related to the convergence of a series in a left--definite space. In addition, to complete the asymptotic study of this family of nonstandard polynomials we give the Mehler--Heine formulae for the corresponding orthogonal polynomials.
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