On zero behavior of higher-order Sobolev-type discrete $$q-$$ Hermite I orthogonal polynomials

In this work, we investigate the sequence of monic q-Hermite I-Sobolev type orthogonal polynomials of higher-order, denoted by \(\{\mathbb {H}_{n}(x;q)\}_{n\ge 0}\), which are orthogonal with respect to the following non-standard inner product involving q-differences:

$$\begin{aligned} \langle p,q\rangle _{\lambda }=\int _{-1}^{1}f\left( x\right) g\left( x\right) (qx,-qx;q)_{\infty }d_{q}(x)+\lambda \,(\mathscr {D}_{q}^{j}f)(\alpha )(\mathscr {D}_{q}^{j}g)(\alpha ), \end{aligned}$$

where \(\lambda \) belongs to the set of positive real numbers, \(\mathscr {D}_{q}^{j}\) denotes the j-th q -discrete analogue of the derivative operator, \(q^j\alpha \in \mathbb {R}\backslash (-1,1)\), and \((qx,-qx;q)_{\infty }d_{q}(x)\) denotes the orthogonality weight with its points of increase in a geometric progression. Connection formulas between these polynomials and standard q-Hermite I polynomials are deduced. The basic hypergeometric representation of \(\mathbb {H}_{n}(x;q)\) is obtained. Moreover, for certain real values of \(\alpha \) satisfying the condition \(q^j\alpha \in \mathbb {R}\backslash (-1,1)\), we present results concerning the location of the zeros of \(\mathbb {H}_{n}(x;q)\) and perform a comprehensive analysis of their asymptotic behavior as the parameter \(\lambda \) tends to infinity.