A study of solutions for several classes of systems of complex nonlinear partial differential difference equations in ℂ2

A study of solutions for several classes of systems of complex nonlinear partial differential difference equations in ℂ2

This article is devoted to describing the entire solutions of several systems of the first-order nonlinear partial differential difference equations (PDDEs). Using the Nevanlinna theory and the Hadamard factorization theory of meromorphic functions, we establish some interesting results to reveal th...

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Bibliographic Details
Main Authors: Jiao Xin, Chen Yu Bin, Xu Hong Yan
Format: Article
Language:English
Published: De Gruyter 2025-05-01
Series:Demonstratio Mathematica
Subjects:
nevanlinna theory
entire function
system of functional equations
several complex variables
30d35
35m30
Online Access:https://doi.org/10.1515/dema-2025-0119
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Summary:This article is devoted to describing the entire solutions of several systems of the first-order nonlinear partial differential difference equations (PDDEs). Using the Nevanlinna theory and the Hadamard factorization theory of meromorphic functions, we establish some interesting results to reveal the existence and the forms of the finite-order transcendental entire solutions of several systems of the first-order nonlinear PDDEs: f(z1+c1,z2+c2)(a1gz1+a2gz2)=m1,g(z1+c1,z2+c2)(a3fz1+a4fz2)=m2,f(z1+c1,z2+c2)(a1fz1+a2gz1)=m1,g(z1+c1,z2+c2)(a3fz2+a4gz2)=m2,\begin{array}{l}\left\{\begin{array}{l}f\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{1}{g}_{{z}_{1}}+{a}_{2}{g}_{{z}_{2}})={m}_{1},\\ g\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{3}{f}_{{z}_{1}}+{a}_{4}{f}_{{z}_{2}})={m}_{2},\end{array}\right.\\ \left\{\begin{array}{l}f\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{1}{f}_{{z}_{1}}+{a}_{2}{g}_{{z}_{1}})={m}_{1},\\ g\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{3}{f}_{{z}_{2}}+{a}_{4}{g}_{{z}_{2}})={m}_{2},\end{array}\right.\end{array} and f(z1+c1,z2+c2)(a1fz2+a2gz1)=m1,g(z1+c1,z2+c2)(a3fz1+a4gz2)=m2,\left\{\begin{array}{l}f\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{1}{f}_{{z}_{2}}+{a}_{2}{g}_{{z}_{1}})={m}_{1},\\ g\left({z}_{1}+{c}_{1},{z}_{2}+{c}_{2})({a}_{3}{f}_{{z}_{1}}+{a}_{4}{g}_{{z}_{2}})={m}_{2},\end{array}\right. where a1,a2,a3,a4,c1,c2∈C{a}_{1},{a}_{2},{a}_{3},{a}_{4},{c}_{1},{c}_{2}\in {\mathbb{C}}, m1,m2∈C−{0}{m}_{1},{m}_{2}\in {\mathbb{C}}-\left\{0\right\}. Moreover, some examples are given to explain that there are significant differences in the forms of solutions from some previous systems of functional equations.
ISSN:2391-4661

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