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1	A study of modified hermite polynomials Khan, Mumtaz Ahmad, Khan, Abdul Hakim, Ahmad, Naeem 25 September 2017 (has links) The present paper is a study of modied Hermitepolynomials Hn(x; a) which reduces to Hermite polynomialsHn(x) for a = e. Generating Functions Recurrence Relations Rodrigues Formula Integrals Gauss Transform And Orthogonality 33c45 42c05
2	A study of modified Hermite polynomials of two variables / A study of modified Hermite polynomials of two variables Ahmad Khan, Mumtaz, Hakim Khan, Abdul, Ahmad, Naeem 25 September 2017 (has links) The present paper is a study of modied Hermite polynomials of two variables Hn(x; y; a) which for a = e reduces to Hermite polynomials of two variables Hn(x; y) due to M.A. Khan and G.S. Abukhammash. / El presente artculo se estudian polinomios modicados de Hermite de dos variables Hn(x; y; a) que para a = e se reducen a los polinomios de Hermite de dos variables Hn(x; y) introducidos por M.A. Khan y G.S.Abukhammash. Generating Functions Recurrence Relations Rodrigues Formula Msc(2010): 42c05 33c45 Funciones Generatrices Relaciones de Recurrencia Formula Rodrigues 42c05 33c45
3	The Symmetric Meixner-Pollaczek polynomials Araaya, Tsehaye January 2003 (has links) <p>The Symmetric Meixner-Pollaczek polynomials are considered. We denote these polynomials in this thesis by <i>p</i><i>n</i><sup>(λ)</sup>(<i>x</i>) instead of the standard notation <i>p</i><i>n</i><sup>(λ)</sup> (<i>x</i>/2, <i>π</i>/2), where λ > 0. The limiting case of these sequences of polynomials <i>p</i><i>n</i><sup>(0)</sup> (<i>x</i>) =lim<sub>λ→0</sub> <i>p</i><i>n</i><sup>(λ)</sup>(<i>x</i>), is obtained, and is shown to be an orthogonal sequence in the strip, <i>S</i> = {<i>z</i> ∈ ℂ : −1≤ℭ (<i>z</i>)≤1}.</p><p>From the point of view of Umbral Calculus, this sequence has a special property that makes it unique in the Symmetric Meixner-Pollaczek class of polynomials: it is of convolution type. A convolution type sequence of polynomials has a unique associated operator called a delta operator. Such an operator is found for <i>p</i><i>n</i><sup>(0)</sup> (<i>x</i>), and its integral representation is developed. A convolution type sequence of polynomials may have associated Sheffer sequences of polynomials. The set of associated Sheffer sequences of the sequence <i>p</i><i>n</i><sup>(0)</sup>(<i>x</i>) is obtained, and is found</p><p>to be ℙ = {{<i>p</i><i>n</i><sup>(λ)</sup> (<i>x</i>)} =0 : λ ∈ R}. The major properties of these sequences of polynomials are studied.</p><p>The polynomials {<i>p</i><i>n</i><sup>(λ)</sup> (<i>x</i>)}<sup>∞</sup><i>n</i><sub>=0</sub>, λ < 0, are not orthogonal polynomials on the real line with respect to any positive real measure for failing to satisfy Favard’s three term recurrence relation condition. For every λ ≤ 0, an associated nonstandard inner product is defined with respect to which <i>p</i><i>n</i><sup>(λ)</sup>(x) is orthogonal. </p><p>Finally, the connection and linearization problems for the Symmetric Meixner-Pollaczek polynomials are solved. In solving the connection problem the convolution property of the polynomials is exploited, which in turn helps to solve the general linearization problem.</p> Mathematical analysis Meixner-Pollaczek polynomial Orthogonal polynomial Polynomial operator Inner product Umbral calculus Sheffer polynomial Convolution type polynomial Connection and linearization problem 33C45 05A40 33D45 Matematisk analys Mathematical analysis Analys
4	The Symmetric Meixner-Pollaczek polynomials Araaya, Tsehaye January 2003 (has links) The Symmetric Meixner-Pollaczek polynomials are considered. We denote these polynomials in this thesis by pn(λ)(x) instead of the standard notation pn(λ) (x/2, π/2), where λ > 0. The limiting case of these sequences of polynomials pn(0) (x) =limλ→0 pn(λ)(x), is obtained, and is shown to be an orthogonal sequence in the strip, S = {z ∈ ℂ : −1≤ℭ (z)≤1}. From the point of view of Umbral Calculus, this sequence has a special property that makes it unique in the Symmetric Meixner-Pollaczek class of polynomials: it is of convolution type. A convolution type sequence of polynomials has a unique associated operator called a delta operator. Such an operator is found for pn(0) (x), and its integral representation is developed. A convolution type sequence of polynomials may have associated Sheffer sequences of polynomials. The set of associated Sheffer sequences of the sequence pn(0)(x) is obtained, and is found to be ℙ = {{pn(λ) (x)} =0 : λ ∈ R}. The major properties of these sequences of polynomials are studied. The polynomials {pn(λ) (x)}∞n=0, λ < 0, are not orthogonal polynomials on the real line with respect to any positive real measure for failing to satisfy Favard’s three term recurrence relation condition. For every λ ≤ 0, an associated nonstandard inner product is defined with respect to which pn(λ)(x) is orthogonal. Finally, the connection and linearization problems for the Symmetric Meixner-Pollaczek polynomials are solved. In solving the connection problem the convolution property of the polynomials is exploited, which in turn helps to solve the general linearization problem. Mathematical analysis Meixner-Pollaczek polynomial Orthogonal polynomial Polynomial operator Inner product Umbral calculus Sheffer polynomial Convolution type polynomial Connection and linearization problem 33C45 05A40 33D45 Matematisk analys Mathematical analysis Analys

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