Recurrence Coefficients of a New Generalization of the Meixner Polynomials

Recurrence Coefficients of a New Generalization of the Meixner Polynomials

We investigate new generalizations of the Meixner polynomials on the lattice N, on the shifted lattice N+1−β and on the bi-lattice N∪(N+1−β). We show that the coefficients of the three-term recurrence relation for the orthogonal polynomials are related to the solutions of the fifth Painlevé equation...

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Date:2011
Main Authors: Filipuk, G., Van Assche, W.
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Language:English
Published: Інститут математики НАН України 2011
Series:Symmetry, Integrability and Geometry: Methods and Applications
Online Access:https://nasplib.isofts.kiev.ua/handle/123456789/147388
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Cite this:Recurrence Coefficients of a New Generalization of the Meixner Polynomials / G. Filipuk, W. Van Assche // Symmetry, Integrability and Geometry: Methods and Applications. — 2011. — Т. 7. — Бібліогр.: 12 назв. — англ.

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spelling nasplib_isofts_kiev_ua-123456789-1473882025-02-09T17:27:30Z Recurrence Coefficients of a New Generalization of the Meixner Polynomials Filipuk, G. Van Assche, W. We investigate new generalizations of the Meixner polynomials on the lattice N, on the shifted lattice N+1−β and on the bi-lattice N∪(N+1−β). We show that the coefficients of the three-term recurrence relation for the orthogonal polynomials are related to the solutions of the fifth Painlevé equation PV. Initial conditions for different lattices can be transformed to the classical solutions of PV with special values of the parameters. We also study one property of the Bäcklund transformation of PV. This paper is a contribution to the Special Issue “Relationship of Orthogonal Polynomials and Special Functions with Quantum Groups and Integrable Systems”. The full collection is available at http://www.emis.de/journals/SIGMA/OPSF.html. GF is partially supported by Polish MNiSzW Grant N N201 397937. WVA is supported by Belgian Interuniversity Attraction Pole P6/02, FWO grant G.0427.09 and K.U. Leuven Research Grant OT/08/033. 2011 Article Recurrence Coefficients of a New Generalization of the Meixner Polynomials / G. Filipuk, W. Van Assche // Symmetry, Integrability and Geometry: Methods and Applications. — 2011. — Т. 7. — Бібліогр.: 12 назв. — англ. 1815-0659 2010 Mathematics Subject Classification: 34M55; 33E17; 33C47; 42C05; 64Q30 DOI:10.3842/SIGMA.2011.068 https://nasplib.isofts.kiev.ua/handle/123456789/147388 en Symmetry, Integrability and Geometry: Methods and Applications application/pdf Інститут математики НАН України
institution Digital Library of Periodicals of National Academy of Sciences of Ukraine
collection DSpace DC
language English
description We investigate new generalizations of the Meixner polynomials on the lattice N, on the shifted lattice N+1−β and on the bi-lattice N∪(N+1−β). We show that the coefficients of the three-term recurrence relation for the orthogonal polynomials are related to the solutions of the fifth Painlevé equation PV. Initial conditions for different lattices can be transformed to the classical solutions of PV with special values of the parameters. We also study one property of the Bäcklund transformation of PV.
format Article
author Filipuk, G.
Van Assche, W.
spellingShingle Filipuk, G.
Van Assche, W.
Recurrence Coefficients of a New Generalization of the Meixner Polynomials
Symmetry, Integrability and Geometry: Methods and Applications
author_facet Filipuk, G.
Van Assche, W.
author_sort Filipuk, G.
title Recurrence Coefficients of a New Generalization of the Meixner Polynomials
title_short Recurrence Coefficients of a New Generalization of the Meixner Polynomials
title_full Recurrence Coefficients of a New Generalization of the Meixner Polynomials
title_fullStr Recurrence Coefficients of a New Generalization of the Meixner Polynomials
title_full_unstemmed Recurrence Coefficients of a New Generalization of the Meixner Polynomials
title_sort recurrence coefficients of a new generalization of the meixner polynomials
publisher Інститут математики НАН України
publishDate 2011
url https://nasplib.isofts.kiev.ua/handle/123456789/147388
citation_txt Recurrence Coefficients of a New Generalization of the Meixner Polynomials / G. Filipuk, W. Van Assche // Symmetry, Integrability and Geometry: Methods and Applications. — 2011. — Т. 7. — Бібліогр.: 12 назв. — англ.
series Symmetry, Integrability and Geometry: Methods and Applications
work_keys_str_mv AT filipukg recurrencecoefficientsofanewgeneralizationofthemeixnerpolynomials
AT vanasschew recurrencecoefficientsofanewgeneralizationofthemeixnerpolynomials
first_indexed 2025-11-28T16:02:44Z
last_indexed 2025-11-28T16:02:44Z
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fulltext Symmetry, Integrability and Geometry: Methods and Applications SIGMA 7 (2011), 068, 11 pages Recurrence Coefficients of a New Generalization of the Meixner Polynomials? Galina FILIPUK † and Walter VAN ASSCHE ‡ † Faculty of Mathematics, Informatics and Mechanics, University of Warsaw, Banacha 2, Warsaw, 02-097, Poland E-mail: filipuk@mimuw.edu.pl URL: http://www.mimuw.edu.pl/~filipuk/ ‡ Department of Mathematics, Katholieke Universiteit Leuven, Celestijnenlaan 200B box 2400, BE-3001 Leuven, Belgium E-mail: walter@wis.kuleuven.be URL: http://wis.kuleuven.be/analyse/walter/ Received April 18, 2011, in final form July 07, 2011; Published online July 13, 2011 doi:10.3842/SIGMA.2011.068 Abstract. We investigate new generalizations of the Meixner polynomials on the lattice N, on the shifted lattice N + 1 − β and on the bi-lattice N ∪ (N + 1 − β). We show that the coefficients of the three-term recurrence relation for the orthogonal polynomials are related to the solutions of the fifth Painlevé equation PV. Initial conditions for different lattices can be transformed to the classical solutions of PV with special values of the parameters. We also study one property of the Bäcklund transformation of PV. Key words: Painlevé equations; Bäcklund transformations; classical solutions; orthogonal polynomials; recurrence coefficients 2010 Mathematics Subject Classification: 34M55; 33E17; 33C47; 42C05; 64Q30 1 Introduction The recurrence coefficients of orthogonal polynomials for semi-classical weights are often related to the Painlevé type equations (e.g., [10, 4, 5] and see also the overview in [2]). In this paper we study a new generalization of the Meixner weight. The recurrence coefficients of the corre- sponding orthogonal polynomials can be viewed as functions of one of the parameters. We show that the recurrence coefficients are related to solutions of the fifth Painlevé equation. Another generalization of the Meixner weight is presented in [2]. The paper is organized as follows. In the introduction we shall first review orthogonal poly- nomials for the generalized Meixner weight on different lattices and their main properties fol- lowing [12]. Next we shall briefly recall the fifth Painlevé equation and its Bäcklund transfor- mation. Further, by using the Toda system, we show that the recurrence coefficients can be expressed in terms of solutions of the fifth Painlevé equation. Finally we study initial conditions of the recurrence coefficients for different lattices and describe one property of the Bäcklund transformation of PV. ?This paper is a contribution to the Special Issue “Relationship of Orthogonal Polynomials and Spe- cial Functions with Quantum Groups and Integrable Systems”. The full collection is available at http://www.emis.de/journals/SIGMA/OPSF.html mailto:filipuk@mimuw.edu.pl http://www.mimuw.edu.pl/~filipuk/ mailto:walter@wis.kuleuven.be http://wis.kuleuven.be/analyse/walter/ http://dx.doi.org/10.3842/SIGMA.2011.068 http://www.emis.de/journals/SIGMA/OPSF.html 2 G. Filipuk and W. Van Assche 1.1 Orthogonal polynomials for the generalized Meixner weight One of the most important properties of orthogonal polynomials is the three-term recurrence relation. Let us consider a sequence (pn)n∈N of orthonormal polynomials for the weight w on the lattice N = {0, 1, 2, 3, . . .} ∞∑ k=0 pn(k)pk(k)w(k) = δn,k, where δn,k is the Kronecker delta. This relation takes the following form: xpn(x) = an+1pn+1(x) + bnpn(x) + anpn−1(x). (1) For the monic polynomials Pn related to orthonormal polynomials pn(x) = γnx n + · · · with 1 γ2n = ∞∑ k=0 P 2 n(k)w(k), the recurrence relation is given by xPn(x) = Pn+1(x) + bnPn(x) + a2nPn−1(x). The classical Meixner polynomials ([3, Chapter VI], [12]) are orthogonal on the lattice N with respect to the negative binomial (or Pascal) distribution: ∞∑ k=0 Mn(k;β, c)Mm(k;β, c) (β)kc k k! = c−nn! (β)n(1− c)β δn,m, β > 0, 0 < c < 1. Here the Pochhammer symbol is defined by (x)n = Γ(x+ n) Γ(x) = x(x+ 1) · · · (x+ n− 1). The weight wk = w(k) = (β)kc k/k! satisfies the Pearson equation ∇[(β + x)w(x)] = ( β + x− x c ) w(x), where ∇ is the backward difference operator ∇f(x) = f(x)− f(x− 1). Here the function w(x) = Γ(β + x)cx/(Γ(β)Γ(x+ 1)) gives the weights wk = w(k). The Pearson equation for the Meixner polynomials is, hence, of the form ∇[σ(x)w(x)] = τ(x)w(x) (2) with σ(x) = β + x and τ is a polynomial of degree 1. Recall that the classical orthogonal polynomials are characterized by the Pearson equation (2) with σ a polynomial of degree at most 2 and τ a polynomial of degree 1. Note that in (2) the operator ∇ is used for orthogonal polynomials on the lattice and it is replaced by differentiation in case of orthogonal polynomials on an interval of the real line. The Pearson equation plays an important role for classical orthogonal polynomials since it allows to find many useful properties Recurrence Coefficients of a New Generalization of the Meixner Polynomials 3 of these polynomials. It is known that the recurrence coefficients of the Meixner polynomials are given explicitly by a2n = n(n+ β − 1)c (1− c)2 , bn = n+ (n+ β)c 1− c , n ∈ N. The Meixner weight can be generalized [12]. One can use the weight function w(x) = Γ(β)Γ(γ + x)cx Γ(γ)Γ(β + x)Γ(x+ 1) which gives the weight wk = w(k) = (γ)kc k (β)kk! , c, β, γ > 0, (3) on the lattice N. The orthonormal polynomials (pn)n∈N for weight (3) satisfy ∞∑ k=0 pn(k)pm(k)wk = 0, n 6= m. (4) The special case β = 1 was studied in [2]. The case β = γ gives the well-known Charlier weight. The case γ = 1 corresponds to the classical Charlier weight on the shifted lattice N + 1− β. Theorem 1 ([12, Theorem 3.1]). The recurrence coefficients in the three-term recurrence re- lation (1) for the orthonormal polynomials defined by (4), with respect to weight (3) on the lattice N, satisfy a2n = nc− (γ − 1)un, bn = n+ γ − β + c− (γ − 1)vn/c, where (un + vn)(un+1 + vn) = γ − 1 c2 vn(vn − c) ( vn − c γ − β γ − 1 ) , (5) (un + vn)(un + vn−1) = un un − cn/(γ − 1) (un + c) ( un + c γ − β γ − 1 ) , (6) with initial conditions a20 = 0, b0 = γc β M(γ + 1, β + 1, c) M(γ, β, c) , (7) where M(a, b, z) is the confluent hypergeometric function 1F1(a; b; z). The system (5), (6) can be identified as a limiting case of an asymmetric discrete Painlevé equation [12]. In this paper we show that it can be obtained from the Bäcklund transformation of the fifth Painlevé equation. Furthermore, one can use the weight (3) on the shifted lattice N + 1 − β and one can also combine both lattices to obtain the bi-lattice N ∪ (N + 1 − β). The orthogonality measure for the bi-lattice is a linear combination of the measures on N and N + 1− β. The weight w in (3) on the shifted lattice N + 1 − β = {1 − β, 2 − β, 3 − β, . . .} is, up to a constant factor, equal to the weight on the original lattice N, with different parameters [12]. Denoting wγ,β,c(x) = Γ(β) Γ(γ) Γ(γ + x)cx Γ(x+ 1)Γ(β + x) 4 G. Filipuk and W. Van Assche one has wγ,β,c(k + 1− β) = c1−β Γ(β)Γ(γ + 1− β) Γ(2− β)Γ(γ) wγ+1−β,2−β,c(k). (8) The corresponding orthonormal polynomials (qn)n∈N satisfy ∞∑ k=0 qn(k + 1− β)qm(k + 1− β)w(k + 1− β) = 0, n 6= m. Moreover, these polynomials are equal to the polynomials pn shifted in both the variable x and the parameters β and γ. For the positivity of the weights (w(k + 1 − β))k∈N it is necessary to have c > 0, β < 2, γ > β − 1. In [12, Theorem 3.2] it is shown that the recurrence coefficients in the three-term recurrence relation xqn(x) = ân+1qn+1(x) + b̂nqn(x) + ânqn−1(x) satisfy the same system (5), (6) (with hats) but with initial conditions â20 = 0, b̂0 = (1− β) M(γ − β + 1, 1− β, c) M(γ − β + 1, 2− β, c) . (9) Using the orthogonality measure µ = µ1 + τµ2, where τ > 0, µ1 is the discrete measure on N with weights wk = w(k) and µ2 is the discrete measure on N+1−β with weights vk = w(k+1−β), one can study orthonormal polynomials (rn)n∈N, satisfying the three-term recurrence relation xrn(x) = ãn+1rn+1(x) + b̃nrn(x) + ãnrn−1(x). One needs to impose the conditions c > 0, 0 < β < 2, γ > max(0, β− 1) for the positivity of the measures. The orthogonality relation is given by ∞∑ k=0 rn(k)rm(k)w(k) + τ ∞∑ k=0 rn(k + 1− β)rm(k + 1− β)w(k + 1− β) = 0, m 6= n. According to [12, Theorem 3.3] the recurrence coefficients ã2n and b̃n satisfy system (5), (6) (with tilde) but with initial conditions ã20 = 0, b̃0 = m1 + τm̂1 m0 + τm̂0 , (10) where m0 = M(γ, β, c), m1 = γc β M(γ + 1, β + 1, c), m̂0 = Γ(β)Γ(γ − β + 1) Γ(γ)Γ(2− β) c1−βM(γ − β + 1, 2− β, c), m̂1 = Γ(β)Γ(γ − β + 1) Γ(γ)Γ(1− β) c1−βM(γ − β + 1, 1− β, c). Thus, it is shown in [12] that the orthogonal polynomials for the generalized Meixner weight on the lattice N, on the shifted lattice N + 1 − β and on the bi-lattice N ∪ (N + 1 − β) have recurrence coefficients a2n and bn which satisfy the same nonlinear system of discrete (recurrence) equations but the initial conditions are different in each case. Recurrence Coefficients of a New Generalization of the Meixner Polynomials 5 1.2 The fifth Painlevé equation and its Bäcklund transformation The Painlevé equations possess the so-called Painlevé property: the only movable singularities of the solutions are poles [9]. They are often referred to as nonlinear special functions and have numerous applications in mathematics and mathematical physics. The fifth Painlevé equation PV is given by y′′ = ( 1 2y + 1 y − 1 ) (y′)2 − y′ t + (y − 1)2 t2 ( Ay + B y ) + Cy t + Dy(y + 1) y − 1 , (11) where y = y(t) and A, B, C, D are arbitrary complex parameters. By using a transformation y(t) → y(k1t) we can take the value of the parameter D equal to any non-zero number. There exists a Bäcklund transformation between solutions of the fifth Painlevé equation with D 6= 0. Theorem 2 ([9, Theorem 39.1]). If y = y(t) is the solution the fifth Painlevé equation (11) with parameters A, B, C, D, then the transformation Tε1,ε2,ε3 : y → y1 gives another solution y1 = y1(t) with new values of the parameters A1, B1, C1, D1, where y1 = 1− 2dty ty′ − ay2 + (a− b+ dt)y + b , A1 = − 1 16D (C + d(1− a− b))2, B1 = 1 16D (C − d(1− a− b))2, C1 = d(b− a), D1 = D, a = ε1 √ 2A, b = ε2 √ −2B, d = ε3 √ −2D, ε2j = 1, j ∈ {1, 2, 3}. See also [11] for a further description of the Bäcklund transformations and the isomorphism of the group of Bäcklund transformations and the affine Weyl group of A (1) 3 type. 2 Main results In this paper we show how to obtain a relation between the recurrence coefficients and the (classical) solutions of the fifth Painlevé equation. The calculations are similar to calculations in [2] but are more involved. The study of initial conditions of the recurrence coefficients for different lattices is also presented. We can summarize the known results and our recent findings concerning the (generalized) Meixner weights as follows. The weight (β)kc k/(k!), β > 0, 0 < c < 1, is the classical Meixner weight and the recurrence coefficients are known explicitly. The weight (β)kc k/(k!)2, β > 0, c > 0, is studied in [2] and the recurrence coefficients are related to classical solutions of PV with parameters ((β − 1)2/2,−(β + n)2/2, 2n,−2). It is shown in this paper that the recurrence coefficients for the weight (γ)kc k/(k!(β)k), c, β, γ > 0, are related to the classical solutions of PV with parameters ((γ − 1)2/2,−(γ − β + n)2/2, k1(β + n),−k21/2)), k1 6= 0. 2.1 Relation to the fifth Painlevé equation and its Bäcklund transformation First we obtain a nonlinear discrete equation for vn(c). From equation (5) with n and equa- tion (6) with n + 1 we eliminate un+1 by computing the resultant. Next, from the obtained equation and (6) with n we eliminate un. As a result, we obtain a nonlinear discrete equation for vn(c) which we denote by F (vn−1, vn, vn+1, c) = 0. (12) 6 G. Filipuk and W. Van Assche The equation was obtained by using Mathematica1 but it is too long and too complicated too include here explicitly (all enquiries concerning computations can be sent to the first author). We shall show later on that equation (12) can in fact be obtained from the Bäcklund transformation of the fifth Painlevé equation. Next we derive the differential equation for vn. In [2] we have used the Toda system. Since the weight w in (3) on the shifted lattice N+1−β = {1−β, 2−β, 3−β, . . .} is, up to a constant factor, equal to the weight on the original lattice N with different parameters [12], it can be shown [2, 5] that the recurrence coefficients an and bn as functions of the parameter c satisfy the Toda system( a2n )′ := d dc ( a2n ) = a2n c (bn − bn−1), b′n := d dc bn = 1 c ( a2n+1 − a2n ) . (13) The same system (13) holds for the initial lattice N [2]. Solving (5) for un+1 and (6) for vn−1 and substituting into the Toda system (13) (where we have replaced a2n and bn by their expressions in terms of un and vn from Theorem 1), we get two equations u′n = R1(un, vn, c) and v′n = R2(un, vn, c), (14) where the differentiation is with respect to c. The explicit expressions for R1 and R2 are again quite complicated but readily computed in Mathematica. By differentiating equation (14) and substituting the expression for u′n we obtain an equation for v′′n, v′n, vn, un. Finally, elimina- ting un between this equation and (14) gives a nonlinear second order second degree equation for vn: G(v′′n, v ′ n, vn, c) = 0. (15) We have again used Mathematica to compute this long expression. Now the main difficulty is in identifying this equation. Since (5), (6) is similar to the discrete system in [2], we can try to reduce equation (15) to the fifth Painlevé equation. First, we scale the independent variable c → c/k1 and denote c = k1t, v(c) = V (t). The equation (15) becomes G1(V ′′ n , V ′ n, Vn, t) = 0, where the differentiation is with respect to t. By considering the Ansatz Vn(t) = p1(t)y ′ + p2(t)y 2 + p3(t)y + p4(t) y(y − 1) , where y = y(t) is the solution of the fifth Painlevé equation and pj(t) are unknown functions, we finally get the following theorem. Theorem 3. The equation G1(V ′′ n , V ′ n, Vn, t) = 0 is reduced to the fifth Painlevé equation PV by the following transformations: 1. V (t) = k1t(ty ′ − (1 + β − 2γ)y2 + (1 + n− k1t+ β − 2γ)y − n) 2(γ − 1)(y − 1)y , (16) where y = y(t) satisfies PV with A = (β − 1)2 2 , B = −n 2 2 , C = k1(n− β + 2γ), D = −k 2 1 2 ; (17) 1http://www.wolfram.com http://www.wolfram.com Recurrence Coefficients of a New Generalization of the Meixner Polynomials 7 2. V (t) = k1t(ty ′ − (β − γ)y2 + (n− 1− k1t+ β)y + 1− n− γ) 2(γ − 1)(y − 1)y , (18) where y = y(t) satisfies PV with A = (β − γ)2 2 , B = −(γ + n− 1)2 2 , C = k1(2 + n− β), D = −k 2 1 2 ; (19) 3. V (t) = k1t(ty ′ + (γ − 1)y2 + (1 + n− k1t− β)y − n+ β − γ) 2(γ − 1)(y − 1)y , where y = y(t) satisfies PV with A = (γ − 1)2 2 , B = −(γ − β + n)2 2 , C = k1(β + n), D = −k 2 1 2 . (20) Remark 1. The parameters (17) are invariant under β → 2− β, γ → γ + 1− β; compare with the parameters in the weight (8). Remark 2. Cases 2 and 3 in Theorem 3 follow from case 1 by considering the Bäcklund transformation of Theorem 2. Indeed, the compositions of the transformations T1,1,−1 ◦ T1,−1,1 = T1,1,1 ◦ T1,−1,−1 give the transformation Y1 = y − 2(γ − 1)(y − 1)2y ty′ − (1 + β − 2γ)y2 + (1 + n− k1t+ β − 2γ)y − n , where y = y(t) solves PV with parameters (17) and Y1 solves PV with (19). Similarly, the compositions of the transformations T1,1,−1 ◦ T−1,−1,1 = T1,1,1 ◦ T−1,−1,−1 give Y2 = w + 2(β − γ)(y − 1)2y ty′ − (1 + β − 2γ)y2 + (1 + n− k1t+ β − 2γ)y − n , where y = y(t) solves PV with (17) and Y2 solves PV with (20). Next we show that equation (12) can, in fact, be obtained from the Bäcklund transformation of PV in Theorem 2. Let us take, for instance, the parameters (17) and k1 = 1 for simplicity (hence, c = t). Suppose y = yn(t) solves PV with (17). Then by considering the transformations T1,−1,−1 ◦ T−1,−1,1 ◦ T−1,−1,1 and T1,−1,−1 ◦ T1,1,−1 ◦ T1,1,1 we get new solutions of PV with parameters (17) for n+ 1 and n− 1 respectively. In particular, yn+1 = 1− 2t(n+ γ)y (β − 1)(ty′ + y(1 + n+ t− β + (β − 1)y)− n) + 2t(1 + n− β + γ)y (β − 1)(ty′ + y(n− 1 + t+ β + (1− β)y)− n) and yn−1 = 1 + 2t(γ + n− 1)y (β − 1)(ty′ − y(1 + n+ t− β + (β − 1)y) + n) − 2t(n− β + γ)y (β − 1)(ty′ − y(n− 1 + t+ β + (1− β)y) + n) . Expressing vn±1 in terms of yn by using (16), we can compute that (12) is identically zero. Hence, the discrete system (5), (6) can be obtained from the Bäcklund transformation of PV. 8 G. Filipuk and W. Van Assche 2.2 Initial conditions In this section we study the initial conditions (7), (9), (10) for the generalized Meixner weight (3) on the lattice N, on the shifted lattice and on the bi-lattice respectively. Let n = 0. Since γ 6= 1, we get that u0 = 0 from a20 = 0. We also put k1 = 1 and c = t. From (14) we have that v = v0(t) satisfies the first order nonlinear equation t2v′ = (γ − 1)v2 + t(2− t+ β − 2γ)v + (γ − β)t2. (21) Since b0 = γ − β + t− (γ − 1)v0/t, we can find v0 for (7), (9) and (10). We can verify that all of them satisfy (21) using formulas for the confluent hypergeometric functions from [1]. Note that (10) depends on an arbitrary parameter τ . The fifth Painlevé equation (11) with parameters (19) with k1 = 1 and n = 0 has particular solutions which solve the following first order nonlinear equation: ty′ = (β − γ)y2 + (t− 1− β + 2γ)y + 1− γ. (22) Substituting expression (18) in (21) and assuming that y satisfies (22), we indeed find that the equation is satisfied. We also find that v(t) = t/y(t). Thus, the initial conditions (7), (9), (10) for the generalized Meixner weight (3) on the lattice N, on the shifted lattice and on the bi-lattice respectively are related to solutions of the first order differential equation (22), which, in turn, satisfies PV. 3 A remark on the Bäcklund transformation In this section we study the Bäcklund transformation of the fifth Painlevé equation (PV) and find when a linear combination of two solutions is also a solution of PV. In particular, we show that if y1 and y2 are solutions of PV obtained from a solution y by certain Bäcklund transformations, then there is a constant M 6= 0, 1 such that My1 + (1−M)y2 is also a solution of PV. Example 1. In [2] it is shown that if y := yn(t) (related to the recurrence coefficients of the generalized Meixner polynomials) is the solution of (11) with A = (β − 1)2 2 , B = −(β + n)2 2 , C = 2n, D = −2, then one can show that yn+1 = yn+1(t) given by yn+1 = 1 + 4(n+ 1)ty (β − 1)(ty′ + (2t+ 2β − 1 + n− (β − 1)y)y − n− β) − 4t(n+ β)y (β − 1)(ty′ + (1 + n+ 2t+ (β − 1)y)y − n− β) (23) is the solution of (11) with A = (β − 1)2 2 , B = −(β + n+ 1)2 2 , C = 2(n+ 1), D = −2. It can be observed that the transformation (23) can be written in the following form: yn+1 = My1 + (1−M)y2, M = n+ 1 1− β , Recurrence Coefficients of a New Generalization of the Meixner Polynomials 9 where y1 = T1,−1,1y = 1 + 4ty n+ β − (n− 1 + 2β + 2t)y + (β − 1)y2 − ty′ is a solution of (11) with A1 = (n+ 1)2 2 , B1 = −1 2 , C1 = −2(2β + n− 1), D1 = −2 and y2 = T−1,−1,1y = 1 + 4ty n+ β − (1 + n+ 2t)y − (β − 1)y2 − ty′ is a solution of (11) with A2 = (n+ β)2 2 , B2 = −β 2 2 , C2 = −2(n+ 1), D2 = −2. Similarly, if y1 = T1,1,−1y = 1 + 4ty n+ β − (1 + n+ 2t)y − (β − 1)y2 + ty′ , y2 = T−1,1,−1y = 1 + 4ty n+ β − (n− 1 + 2β + 2t)y + (β − 1)y2 + ty′ are solutions of (11) with A1 = (β + n− 1)2 2 , B1 = −(β − 1)2 2 , C1 = −2(n+ 1), D1 = −2 and A2 = n2 2 , B2 = 0, C2 = −2(2β + n− 1), D2 = −2, respectively, then yn−1 = My1 + (1−M)y2, M = (β + n− 1) β − 1 is a solution of (11) with A = (β − 1)2 2 , B = −(β + n− 1)2 2 , C = 2(n− 1), D = −2. Such observations motivate us to study the question when the sum My1 + (1 −M)y2 of two solutions of PV is also a solution of the same equation. Clearly, we impose the conditions that M 6= 0 and M 6= 1. Theorem 4. Let y = y(t) be a solution of PV with parameters A, B, C, D = −2 and y1 = Tε1,ε2,ε3y, y2 = Tδ1,δ2,δ3y, where ε2j = δ2j = 1 and εj 6= δj for some j ∈ {1, 2, 3}. Then v = M y1 + (1−M) y2 with M 6= 0; 1 is a solution of PV with parameters Av, Bv, Cv, Dv = −2 in the following cases: 10 G. Filipuk and W. Van Assche 1. δ1 = ε1, δ2 = −ε2, δ3 = ε3 and M = 2ε1 √ 2A+ 2ε2 √ −2B − ε3C − 2 4ε2 √ −2B , Av = −B, Bv = 2ε1 √ 2A− 2A− 1 2 , Cv = −C − 2ε3; 2. δ1 = −ε1, δ2 = ε2, δ3 = ε3 and M = 2ε1 √ 2A+ 2ε2 √ −2B − ε3C − 2 4ε1 √ 2A , Av = A, Bv = 2ε2 √ −2B + 2B − 1 2 , Cv = C + 2ε3. Proof. The proof of this result is computational. We first obtain that in case δ3 = −ε3 one gets only cases M = 0 and M = 1. In case δ3 = ε3 one needs to consider 3 cases separately (since δ1 = ε1, δ2 = ε2 gives a trivial result for the function v): δ1 = ε1, δ2 = −ε2; δ1 = −ε1, δ2 = ε2; δ1 = −ε1, δ2 = −ε2. However, in the last case we get M = 0 or M = 1. � The examples at the beginning of the section correspond to the second case of the theorem. Similarly, we can get expressions for yn+1 and yn−1 in the previous section by using this theorem. Various properties of the repeated application of the Bäcklund transformations are studied in [6, 7, 8]. Repeated applications of the Bäcklund transformations to the seed solutions usually lead to very cumbersome formulas. However, as shown in this section, we can get linear depen- dence between three solutions. Moreover, our formulas suggest that the function v has the same poles as y1 and y2 and, thus, they can be useful to study various properties of the solutions. Other Painlevé equations might have similar properties so one can try to study when for instance a linear combination of several solutions or a product or a cross-ratio of several solutions is also a solution (see also the representation of solutions in [11]). Although computationally difficult, this deserves further study. Acknowledgements GF is partially supported by Polish MNiSzW Grant N N201 397937. WVA is supported by Belgian Interuniversity Attraction Pole P6/02, FWO grant G.0427.09 and K.U. Leuven Research Grant OT/08/033. References [1] Abramowitz M., Stegun I., Handbook of mathematical functions, Dover Publications, New York, 1965. [2] Boelen L., Filipuk G., Van Assche W., Recurrence coefficients of generalized Meixner polynomials and Painlevé equations, J. Phys. A: Math. Theor. 44 (2011), 035202, 19 pages. [3] Chihara T.S., An introduction to orthogonal polynomials, Mathematics and its Applications, Vol. 13, Gordon and Breach Science Publishers, New York – London – Paris, 1978. [4] Filipuk G., Van Assche W., Zhang L., On the recurrence coefficients of semiclassical Laguerre polynomials, arXiv:1105.5229. [5] Filipuk G., Van Assche W., Recurrence coefficients of the generalized Charlier polynomials and the fifth Painlevé equation, arXiv:1106.2959. [6] Gromak V., Filipuk G., On functional relations between solutions of the fifth Painlevé equation, Differ. Equ. 37 (2001), 614–620. [7] Gromak V., Filipuk G., The Bäcklund transformations of the fifth Painlevé equation and their applications, Math. Model. Anal. 6 (2001), 221–230. http://dx.doi.org/10.1088/1751-8113/44/3/035202 http://arxiv.org/abs/1105.5229 http://arxiv.org/abs/1106.2959 http://dx.doi.org/10.1023/A:1019204329101 http://dx.doi.org/10.1023/A:1019204329101 http://dx.doi.org/10.1080/13926292.2001.9637161 Recurrence Coefficients of a New Generalization of the Meixner Polynomials 11 [8] Gromak V., Filipuk G., Bäcklund transformations of the fifth Painlevé equation and their applications, in Proceedings of the Summer School “Complex Differential and Functional Equations” (Mekrijärvi, 2000), Univ. Joensuu Dept. Math. Rep. Ser., Vol. 5, Univ. Joensuu, Joensuu, 2003, 9–20. [9] Gromak V.I., Laine I., Shimomura S., Painlevé differential equations in the complex plane, de Gruyter Studies in Mathematics, Vol. 28, Walter de Gruyter & Co., Berlin, 2002. [10] Magnus A.P., Painlevé type differential equations for the recurrence coefficients of semi-classical orthogonal polynomials, J. Comput. Appl. Math. 57 (1995), 215–237, math.CA/9307218. [11] Noumi M., Painlevé equations through symmetry, Translations of Mathematical Monographs, Vol. 223, American Mathematical Society, Providence, RI, 2004. [12] Smet C., Van Assche W., Orthogonal polynomials on a bi-lattice, Constr. Approx., to appear, arXiv:1101.1817. http://dx.doi.org/10.1016/0377-0427(93)E0247-J http://arxiv.org/abs/math.CA/9307218 http://arxiv.org/abs/1101.1817 1 Introduction 1.1 Orthogonal polynomials for the generalized Meixner weight 1.2 The fifth Painlevé equation and its Bäcklund transformation 2 Main results 2.1 Relation to the fifth Painlevé equation and its Bäcklund transformation 2.2 Initial conditions 3 A remark on the Bäcklund transformation References

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