(p, k) Matrix Mittag‐Leffler and Pochhammer Functions With Applications to Fractional Differential Systems.

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Bibliographic Details
Title: (p, k) Matrix Mittag‐Leffler and Pochhammer Functions With Applications to Fractional Differential Systems.
Authors: Al–Sheikh, Mohamed S.1 (AUTHOR) mohammedali.2459@azhar.edu.eg, Bakhet, Ahmed1,2 (AUTHOR), Mahmoud, Ahmed Adly1 (AUTHOR), Zahran, Ahmed M.1 (AUTHOR), Cortés, J.-C. (AUTHOR) jccortes@imm.upv.es
Source: Abstract & Applied Analysis. 6/19/2026, Vol. 2026, p1-10. 10p.
Subjects: Fractional differential equations, Matrix functions
Abstract: In this study, we introduce the two‐parameter Pochhammer matrix function. Notably, we establish the (p, k) Pochhammer matrix symbol as a key new construct for our generalizations. Furthermore, we construct gamma and beta matrix functions of two parameters and prove properties similar to their classical counterparts. Additionally, we define the (p, k) Mittag‐Leffler matrix function, exploring its fundamental properties, computation methods, and practical applications in solving systems of linear fractional differential equations. [ABSTRACT FROM AUTHOR]
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Database: Engineering Source
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Abstract:In this study, we introduce the two‐parameter Pochhammer matrix function. Notably, we establish the (p, k) Pochhammer matrix symbol as a key new construct for our generalizations. Furthermore, we construct gamma and beta matrix functions of two parameters and prove properties similar to their classical counterparts. Additionally, we define the (p, k) Mittag‐Leffler matrix function, exploring its fundamental properties, computation methods, and practical applications in solving systems of linear fractional differential equations. [ABSTRACT FROM AUTHOR]
ISSN:10853375
DOI:10.1155/aaa/6468748