Certain Results for the 2-Variable Peters Mixed Type and Related Polynomials
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摘要
In this article, the 2-variable general polynomials are taken as base with Peters polynomials to introduce a family of 2-variable Peters mixed type polynomials.These polynomials are framed within the context of monomiality principle and their properties are established. Certain summation formulae for these polynomials are also derived. Examples of some members belonging to this family are considered and numbers related to some mixed special polynomials are also explored.
In this article, the 2-variable general polynomials are taken as base with Peters polynomials to introduce a family of 2-variable Peters mixed type polynomials.These polynomials are framed within the context of monomiality principle and their properties are established. Certain summation formulae for these polynomials are also derived. Examples of some members belonging to this family are considered and numbers related to some mixed special polynomials are also explored.
In this article, the 2-variable general polynomials are taken as base with Peters polynomials to introduce a family of 2-variable Peters mixed type polynomials.These polynomials are framed within the context of monomiality principle and their properties are established. Certain summation formulae for these polynomials are also derived. Examples of some members belonging to this family are considered and numbers related to some mixed special polynomials are also explored.
引文
[1] L. C. Andrews, Special Functions for Engineers and Applied Mathematicians, Macmillan Publishing Company, New York, 1985.
[2] P. Appell and J. Kampe′de Fe′riet, Fonctions Hyperge′ome′triques et Hypersphe′riques:Polyn o?mes d’ Hermite, Gauthier-Villars, Paris, 1926.
[3] L. Carlitz, A note on Bernoulli and Euler polynomials of second kind, Scr. Math., 25(1961),323–330.
[4] G. Dattoli, Hermite-Bessel and Laguerre-Bessel functions:a by-product of the monomiality principle, Advanced Special functions and applications,(Melfi, 1999), 147–164, Proc. Melfi Sch. Adv. Top. Math. Phys., 1, Aracne, Rome, 2000.
[5] G. Dattoli, Summation formulae of special functions and multivariable Hermite polynomials, Nuovo Cimento Soc. Ital. Fis. B, 119(5)(2004), 479–488.
[6] G. Dattoli, C. Cesarano, and D. Sacchetti, A note on truncated polynomials, Appl. Math.Comput., 134(2003), 595–605.
[7] G. Dattoli, S. Lorenzutta, A. M. Mancho, and A. Torre, Generalized polynomials and associated operational identities, J. Comput. Appl. Math., 108(1-2)(1999), 209–218.
[8] G. Dattoli, M. Migliorati, and H. M. Srivastava, A class of Bessel summation formulas and associated operational methods, Frac. Appl. Anal., 7(2)(2004), 169–176.
[9] R. Dere, and Y. Simsek, Applications of umbral algebra to some special polynomials, Adv.Stud. Contemp. Math., 22(3)(2012), 433–438.
[10] H. W. Gould, and A. T. Hopper, Operational formulas connected with two generalization of Hermite polynomials, Duke. Math. J., 29(1962), 51–63.
[11] Subuhi Khan, and N. Raza, General-Appell polynomials within the context of monomiality principle, Int. J. Anal.,(2013), 1–11.
[12] D. S. Kim, and T. Kim, Poly-Cauchy and Peters mixed type polynomials, Adv. Diff. Eq., 4(2014), 1–18.
[13] D. S. Kim, and T. Kim, A Note on Boole polynomials, Integ. Trans. Sp. Funct., 4(2014), 1–7.
[14] D. S. Kim, T. Kim, and J. J. Seo, A Note on Changhee polynomials and numbers, Adv. Studies. Theoer. Phys., 7(20)(2013), 993–1003.
[15] T. Kim, D. S. Kim, T. Mansour, S. H. Rim, and M. Schork, Umbral calculus and Sheffer sequences of polynomials, J. Math. Phys., 54(2013), https://doi.org/10.1063/1.4817853.
[16] E. D. Rainville, Special Functions, Macmillan, New York, 1960, reprinted by Chelsea Publ.Co., Bronx, New York, 1971.
[17] S. Roman, The Umbral Calculus, Academic Press, New York, 1984.
[18] I. M. Sheffer, Some properties of polynomial sets of type zero, Duke Math. J., 5(1939), 590–622.
[19] J. F. Steffensen, The poweriod, an extension of the mathematical notion of power, Acta.Math., 73(1941), 333–366.
[2] P. Appell and J. Kampe′de Fe′riet, Fonctions Hyperge′ome′triques et Hypersphe′riques:Polyn o?mes d’ Hermite, Gauthier-Villars, Paris, 1926.
[3] L. Carlitz, A note on Bernoulli and Euler polynomials of second kind, Scr. Math., 25(1961),323–330.
[4] G. Dattoli, Hermite-Bessel and Laguerre-Bessel functions:a by-product of the monomiality principle, Advanced Special functions and applications,(Melfi, 1999), 147–164, Proc. Melfi Sch. Adv. Top. Math. Phys., 1, Aracne, Rome, 2000.
[5] G. Dattoli, Summation formulae of special functions and multivariable Hermite polynomials, Nuovo Cimento Soc. Ital. Fis. B, 119(5)(2004), 479–488.
[6] G. Dattoli, C. Cesarano, and D. Sacchetti, A note on truncated polynomials, Appl. Math.Comput., 134(2003), 595–605.
[7] G. Dattoli, S. Lorenzutta, A. M. Mancho, and A. Torre, Generalized polynomials and associated operational identities, J. Comput. Appl. Math., 108(1-2)(1999), 209–218.
[8] G. Dattoli, M. Migliorati, and H. M. Srivastava, A class of Bessel summation formulas and associated operational methods, Frac. Appl. Anal., 7(2)(2004), 169–176.
[9] R. Dere, and Y. Simsek, Applications of umbral algebra to some special polynomials, Adv.Stud. Contemp. Math., 22(3)(2012), 433–438.
[10] H. W. Gould, and A. T. Hopper, Operational formulas connected with two generalization of Hermite polynomials, Duke. Math. J., 29(1962), 51–63.
[11] Subuhi Khan, and N. Raza, General-Appell polynomials within the context of monomiality principle, Int. J. Anal.,(2013), 1–11.
[12] D. S. Kim, and T. Kim, Poly-Cauchy and Peters mixed type polynomials, Adv. Diff. Eq., 4(2014), 1–18.
[13] D. S. Kim, and T. Kim, A Note on Boole polynomials, Integ. Trans. Sp. Funct., 4(2014), 1–7.
[14] D. S. Kim, T. Kim, and J. J. Seo, A Note on Changhee polynomials and numbers, Adv. Studies. Theoer. Phys., 7(20)(2013), 993–1003.
[15] T. Kim, D. S. Kim, T. Mansour, S. H. Rim, and M. Schork, Umbral calculus and Sheffer sequences of polynomials, J. Math. Phys., 54(2013), https://doi.org/10.1063/1.4817853.
[16] E. D. Rainville, Special Functions, Macmillan, New York, 1960, reprinted by Chelsea Publ.Co., Bronx, New York, 1971.
[17] S. Roman, The Umbral Calculus, Academic Press, New York, 1984.
[18] I. M. Sheffer, Some properties of polynomial sets of type zero, Duke Math. J., 5(1939), 590–622.
[19] J. F. Steffensen, The poweriod, an extension of the mathematical notion of power, Acta.Math., 73(1941), 333–366.