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Article

The Exact Solutions for Several Partial Differential-Difference Equations with Constant Coefficients

1
College of Arts and Sciences, Suqian University, Suqian 223800, China
2
School of Mathematics and Computer Science, Gannan Normal University, Ganzhou 341000, China
3
School of Mathematics and Computer, Jiangxi Science and Technology Normal University, Nanchang 330038, China
4
Department of Mathematics and Statistics, University of Victoria, Victoria, BC V8W 3R4, Canada
5
Department of Medical Research, China Medical University Hospital, China Medical University, Taichung 40402, Taiwan
6
Department of Mathematics and Informatics, Azerbaijan University, Baku AZ197, Azerbaijan
7
Section of Mathematics, International Telematic University Uninettuno, I-00186 Rome, Italy
*
Author to whom correspondence should be addressed.
These authors contributed equally to this work.
Mathematics 2022, 10(19), 3596; https://doi.org/10.3390/math10193596
Submission received: 25 August 2022 / Revised: 25 September 2022 / Accepted: 27 September 2022 / Published: 1 October 2022

Abstract

:
This article is concerned with the description of the entire solutions of several Fermat type partial differential-difference equations (PDDEs) μ f ( z ) + λ f z 1 ( z ) 2 + [ α f ( z + c ) β f ( z ) ] 2 = 1 , and μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) 2 + [ α f ( z + c ) β f ( z ) ] 2 = 1 , where f z 1 ( z ) = f z 1 and f z 2 ( z ) = f z 2 , c = ( c 1 , c 2 ) C 2 , α , β , μ , λ , λ 1 , λ 2 , c 1 , c 2 are constants in C . Our theorems in this paper give some descriptions of the forms of transcendental entire solutions for the above equations, which are some extensions and improvement of the previous theorems given by Xu, Cao, Liu, and Yang. In particular, we exhibit a series of examples to explain that the existence conditions and the forms of transcendental entire solutions with a finite order of such equations are precise.

1. Introduction and Some Basic Results

As is well known, the classical result of the Fermat type functional equation
f 2 + g 2 = 1
is that the entire solutions are f = cos ζ ( z ) , g = sin ζ ( z ) , where ζ ( z ) is an entire function, which was given by Gross [1]. Actually, the study of this functional equation can be tracked back to more than sixty years ago or even earlier (see [1,2,3]). Moreover, there are important and famous results on the Fermat type equation (see [4,5]). In recent years, replying on the rapid development of Nevanlinna theory in many fields including functional equations and difference of meromorphic function with one and several variables ([6,7,8,9,10,11,12]), there were lots of references focusing on the solutions of the Fermat type equation; when the function f has a special relationship with g, readers can refer to [13,14,15,16,17].
Around 2012, for the case f C , Liu and his colleagues paid considerable attention to the solutions of a series of Fermat type functional equations when g is replaced by f , f ( z + c ) , f ( z + c ) f ( z ) in Equation (1) (see [18,19,20]), they proved that the form of the finite order transcendental entire solution of f ( z ) 2 + f ( z + c ) 2 = 1 must be f ( z ) = sin ( z ± B i ) , and the form of the finite order transcendental entire solution of f ( z ) 2 + [ f ( z + c ) f ( z ) ] 2 = 1 must be f ( z ) = 12 sin ( 2 z + B i ) , where B is a constant. Later, Han and Lü [21]. Liu and Gao [22] investigated the existence of solutions of several deformations of Equation (1) such as f ( z ) 2 + f ( z ) 2 = e α z + β , f ( z ) 2 + f ( z + c ) 2 = Q ( z ) , where α , β are constants and Q ( z ) is a polynomial.
For the case f C n , n 2 , Khavinson [14] in 1995 pointed out that any entire solutions of the partial differential equations f z 1 2 + f z 2 2 = 1 in C 2 are necessarily linear. In 1999 and 2004, Saleeby [23,24] further studied the forms of the entire and meromorphic solutions of some partial differential equations, and obtained
Theorem 1
(see [23] Theorem 1). If f is an entire solution of
f z 1 ( z ) 2 + f z 2 ( z ) 2 = 1 ,
in C 2 , then f ( z 1 , z 2 ) = c 1 z 1 + c 2 z 2 + η , where η , c 1 , c 2 C and c 1 2 + c 2 2 = 1 .
In 2012, Chang and Li [25] investigated the entire solutions of
X 1 ( f ) 2 + X 2 ( f ) 2 = 1 ,
where
X 1 = p 1 z 1 + p 2 z 2 . X 1 = p 3 z 1 + p 4 z 2 ,
are linearly independent operators with p j being polynomials in C 2 and obtained:
Theorem 2
(see [25] Corollary 2.2). Let f be an entire solution of the Equation (3). Then, f satisfies
f z 1 = 1 D ( p 4 cos h p 2 sin h ) , f z 2 = 1 D ( p 1 sin h p 3 cos h ) ,
where D = p 1 p 4 p 2 p 3 , h is a constant or a nonconstant polynomial satisfying
h z 1 = a p 2 + b p 4 D 2 , h z 2 = a p 1 + b p 3 D 2 ,
and
a = D p 2 z 2 p 2 D z 1 + D p 1 z 1 p 1 D z 1 .
b = D p 3 z 1 p 3 D z 1 + D p 4 z 2 p 4 D z 2 .
In fact, Li [16,26] also discussed a series of partial differential equations with more general forms including f z 1 2 + f z 2 2 = e g , f z 1 2 + f z 2 2 = p , etc., where g , p are polynomials in C 2 . Recently, by using the characteristic equations for quasi-linear PDEs, and the Nevanlinna theory in C n , n 2 , Chen, Han, and Lü. Xu and his colleagues, etc. [27,28,29,30,31,32,33,34,35,36] investigated the entire and meromorphic solutions of the nonlinear partial differential equations; for example, Chen and Han [36] discussed the entire solutions of equation ( f l f z 1 ) m ( f l f z 2 ) n = p ( z 1 ) e g ( z ) , where l 0 , m , n 1 are integers, p ( z 1 ) is a polynomial in C and g ( z ) is a polynomial in C 2 , Lü [28] studied the entire solution of equation f z 1 2 + 2 B f z 1 f z 2 + f z 2 2 = e g , where B is a constant and g is a polynomial or an entire function in C 2 , etc., and they generalized and improved the previous results given by Li [15].
Based on the establishment of Nevanlinna difference theory in C n , n 2 (can be found in [6,37]), Xu and Cao [38] in 2018 and 2020 studied the solutions of some Fermat type partial differential-difference equations (PDDEs) and obtained:
Theorem 3
(see [38] Theorem 1.2). Let c = ( c 1 , c 2 ) C 2 . Then, any transcendental entire solutions with a finite order of the partial differential-difference equation
f z 1 ( z ) 2 + f ( z + c ) 2 = 1
has the form of f ( z 1 , z 2 ) = sin ( A z 1 + B ) , where A is a constant on C satisfying A e i A c 1 = 1 , and B is a constant on C ; in the special case whenever c 1 = 0 , we have f ( z 1 , z 2 ) = sin ( z 1 + B ) .
Remark 1.
In general, f is called as a transcendental entire solution of the equation if f is a transcendental entire function and also the solution of this equation, here a meromorphic function f ( z ) is transcendental if and only if
lim sup r + T ( r , f ) log r = ,
this definition can be found in [17].
Inspired by the above results, this article concerns the entire solutions of the following PDDEs
μ f ( z ) + λ f z 1 ( z ) 2 + [ α f ( z + c ) β f ( z ) ] 2 = 1 ,
and
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) 2 + [ α f ( z + c ) β f ( z ) ] 2 = 1 ,
where z = ( z 1 , z 2 ) , c = ( c 1 , c 2 ) , and α , β , μ , λ , λ 1 , λ 2 , c 1 , c 2 are constants in C . Obviously, we can see that (5) and (6) are some deformation Equations of (1) and (4).
The details theorems on the properties of transcendental entire solutions of the partial differential-difference Equations (5) and (6) are be shown in Section 2, and the proofs are given in Section 4 and Section 5. The results obtained in the paper are motivated by and benefit from the factorization theory of meromorphic functions and Nevanlinna theory in several complex variables. In particular, we will assume that the reader is familiar with the basics of Nevanlinna theory in several complex variables.

2. Results and Examples

The first main theorem is about the existence and the forms of the solutions for Equation (5).
Theorem 4.
Let c = ( c 1 , c 2 ) C 2 , c 2 0 , and α , β , μ , λ be nonzero constants in C . Let f ( z 1 , z 2 ) be a finite order transcendental entire solution of Equation (5). Then, f ( z 1 , z 2 ) must satisfy one of the following cases:
(i) if μ f ( z ) + λ f z 1 ( z ) is a constant, then
f ( z 1 , z 2 ) = η 1 μ 1 μ e μ λ z 1 + A z 2 + B ,
where η 1 , A , B C satisfy η 1 2 = μ 2 μ 2 + ( α β ) 2 and e A c 2 = β α e μ λ c 1 ;
(ii) if A 1 ± μ λ , then
f ( z 1 , z 2 ) = 1 2 ( λ A 1 + μ ) e A 1 z 1 + A 2 z 2 + B 1 2 ( λ A 1 μ ) e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function, A 1 , A 2 , B C satisfy
( λ A 1 + β i ) 2 = μ 2 α 2 , e 2 ( A 1 c 1 + A 2 c 2 ) = λ A 1 + μ + β i λ A 1 μ + β i ,
and
ϑ ( z 2 + c 2 ) ϑ ( z 2 ) = β α e μ λ c 1 ;
(iii) if A 1 = μ λ , then
f ( z 1 , z 2 ) = 1 4 μ e A 1 z 1 + A 2 z 2 + B + z 1 2 λ e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function satisfying (7). A 1 , A 2 , B C satisfy
2 μ β i = β 2 α 2 , β c 1 = λ i , e 2 ( A 1 c 1 + A 2 c 2 ) = 1 2 μ β i ;
(iv) if A 1 = μ λ , then
f ( z 1 , z 2 ) = z 1 2 λ e A 1 z 1 + A 2 z 2 + B + 1 4 μ e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function satisfying (7). A 1 , A 2 , B C satisfy
2 μ β i = α 2 β 2 , β c 1 = λ i , e 2 ( A 1 c 1 + A 2 c 2 ) = 1 + 2 μ β i .
The following examples show the existence of transcendental entire solutions of Equation (5).
Example 1.
Let η 1 2 = 1 3 + i 4 2 3 + 1 and
f ( z 1 , z 2 ) = η 1 e 1 2 z 1 + z 2 .
Thus, f ( z 1 , z 2 ) is a transcendental entire solution of (5) with α = e π 6 i , β = e π 3 i , λ = 2 , μ = 1 , ( c 1 , c 2 ) = ( π i , π i ) and ρ ( f ) = 1 . This shows that the form of solution in the conclusion (i) of Theorem 4 is precise.
Example 2.
Let A 2 = 1 2 π i ln cot π 12 1 3 3 2 and
f ( z 1 , z 2 ) = 1 2 ( 3 + 1 ) e 3 2 z 1 + A 2 z 2 1 2 ( 3 1 ) e 3 2 z 1 A 2 z 2 cos ( 2 z 2 ) e 1 2 z 1 + z 2 .
Thus, f ( z 1 , z 2 ) is a transcendental entire solution of (5) with α = e π 6 i , β = e π 3 i , λ = 2 , μ = 1 , ( c 1 , c 2 ) = ( π i , π i ) and ρ ( f ) = 1 . This shows that the form of solution in the conclusion (ii) of Theorem 4 is precise.
Example 3.
Let D = 1 4 ln 2 + π 8 i + 1 2 i , A 2 = 1 4 ln 2 π 8 i 1 2 i and
f ( z 1 , z 2 ) = 1 4 e i 2 z 1 + A 2 z 2 i z 1 4 e i 2 z 1 A 2 z 2 e ( D + 2 π i ) z 2 e i 2 z 1 .
Thus, f ( z 1 , z 2 ) is a transcendental entire solution of (5) with α = 2 5 4 e π 8 i , β = 2 , λ = 2 i , μ = 1 , ( c 1 , c 2 ) = ( 1 , 1 ) and ρ ( f ) = 1 . This shows that the form of solution in the conclusion (iii) of Theorem 4 is precise.
From Theorem 4, letting λ = μ = 1 and α = β = 1 , one can obtain the following result:
Corollary 1.
Let c = ( c 1 , c 2 ) C 2 and c 2 0 . If f ( z 1 , z 2 ) is a finite order transcendental entire solution of equation,
f ( z ) + f z 1 ( z ) 2 + [ f ( z + c ) f ( z ) ] 2 = 1 ,
then f ( z 1 , z 2 ) must be of the form
f ( z 1 , z 2 ) = ± 1 e z 1 + A z 2 + B ,
where A , B are constants and
A c 2 = c 1 + 2 k π i , k Z ;
or
f ( z 1 , z 2 ) = 1 2 ( 1 i ) e i z 1 + A 2 z 2 + B + 1 2 ( 1 + i ) e i z 1 A 2 z 2 B + ϑ ( z 2 ) e z 1 ,
where ϑ ( z 2 ) is a finite order entire function, a 2 , b are constants and
e 2 ( i c 1 + A 2 c 2 ) = 1 , ϑ ( z 2 + c 2 ) ϑ ( z 2 ) = e c 1 ,
From Theorem 4, letting α = 1 and β = 0 , one can obtain the following corollary:
Corollary 2.
Let c = ( c 1 , c 2 ) C 2 , c 2 0 , and λ , μ be nonzero constants. If f ( z 1 , z 2 ) is a finite order transcendental entire solution of equation
μ f ( z ) + λ f z 1 ( z ) 2 + f ( z + c ) 2 = 1 ,
then f ( z 1 , z 2 ) must be of the form
f ( z 1 , z 2 ) = 1 2 ( μ + λ a 1 ) e A 1 z 1 + A 2 z 2 + B + 1 2 ( μ λ A 1 ) e A 1 z 1 A 2 z 2 B ,
where A 1 , A 2 , B are constants and satisfying
A 1 2 = μ 2 1 λ 2 , e 2 ( A 1 c 1 + A 2 c 2 ) = λ A 1 + μ λ A 1 μ .
Remark 2.
In view of the form of f ( z ) in Corollary 2, one can see that the order of f must be 1. However, the following example shows that the equation can admit the transcendental entire solution of the order greater than one if we remove the condition c 2 0 . Let
f ( z ) = 1 2 i ( 3 + 2 ) e z 1 + z 2 + z 2 2 + 1 2 i ( 3 2 ) e z 1 z 2 z 2 2 .
Then, ρ ( f ) = 2 and f is a transcendental entire solution of equation
3 i f ( z 1 , z 2 ) + 2 i f z 1 ( z 1 , z 2 ) 2 + f ( z 1 ln ( 2 3 ) , z 2 + 0 ) 2 = 1 ,
For α = 0 and β = 1 in Equation (5), we have
Corollary 3.
Let λ , μ be two nonzero constants. Then, the following partial differential equation
μ f ( z ) + λ f z 1 ( z ) 2 + f ( z ) 2 = 1
does not admit any finite order transcendental entire solution.
Proof. 
Assume that f ( z ) is a finite order transcendental entire solution of Equation (10). By using the same argument as in the proof of Theorem 4, there exists a nonconstant polynomial p ( z ) C 2 satisfying
μ f ( z ) + λ f z 1 ( z ) = 1 2 ( e p + e p ) , f ( z ) = 1 2 i ( e p e p ) .
Thus, it follows that
μ + λ p z 1 ( z ) i e 2 p = μ λ p z 1 + i .
Noting that p is a nonconstant polynomial, we can deduce that
μ + λ p z 1 i 0 , μ λ p z 1 + i 0 .
Otherwise, the left-side of Equation (11) is transcendental and the right is polynomial; this is a contradiction. In view of (12), it follows that μ = 0 , which is a contradiction.
Therefore, this proves the conclusion of Corollary 3. □
For Equation (6), we obtain the following results about the existence and the forms of transcendental entire solutions of such equation.
Theorem 5.
Let c = ( c 1 , c 2 ) C 2 , α , β , μ , λ 1 , λ 2 be nonzero constants in C , s 1 : = λ 2 z 1 λ 1 z 2 and s 0 : = λ 2 c 1 λ 1 c 2 0 . Let f ( z 1 , z 2 ) be a finite order transcendental entire solution of Equation (6). Then, f ( z ) must satisfy one of the following cases:
(i) if μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) is a constant, then
f ( z 1 , z 2 ) = η 1 μ 1 μ e μ λ 1 z 1 + A ( λ 2 z 1 λ 1 z 2 ) + B ,
where η 1 , A , B C satisfy η 1 2 = μ 2 μ 2 + ( α β ) 2 and e A ( λ 2 c 1 λ 1 c 2 ) = β α e μ λ 1 c 1 ;
(ii) if μ 2 ( λ 1 A 1 + λ 2 A 2 ) 2 , then
f ( z 1 , z 2 ) = 1 2 ( λ 1 A 1 + λ 2 A 2 + μ ) e A 1 z 1 + A 2 z 2 + B 1 2 ( λ 1 A 1 + λ 2 A 2 μ ) e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ ( s 1 ) is a finite order entire function in s 1 satisfying
ϑ ( s 1 + s 0 ) ϑ ( s 1 ) = β α e μ λ 1 s 0 ,
and A 1 , A 2 , B C satisfy
( λ 1 A 1 + λ 2 A 2 + β i ) 2 = μ 2 α 2 , e 2 ( A 1 c 1 + A 2 c 2 ) = λ 1 A 1 + λ 2 A 2 + β i + μ λ 1 A 1 + λ 2 A 2 + β i μ ;
(iii) if μ = λ 1 A 1 + λ 2 A 2 , then
f ( z 1 , z 2 ) = 1 4 μ e A 1 z 1 + A 2 z 2 + B + z 1 2 λ 1 e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ ( s 1 ) is a finite order entire function satisfying (13) and A 1 , A 2 , B C satisfy
2 μ β i = β 2 α 2 , β c 1 = λ 1 i , e 2 ( A 1 c 1 + A 2 c 2 ) = 1 2 μ β i ;
(iv) if μ = ( λ 1 A 1 + λ 2 A 2 ) , then
f ( z 1 , z 2 ) = z 1 2 λ 1 e A 1 z 1 + A 2 z 2 + B + 1 4 μ e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ ( s 1 ) is a finite order entire function satisfying (13) and A 1 , A 2 , B C satisfy
2 μ β i = β 2 α 2 , β c 1 = λ 1 i , e 2 ( A 1 c 1 + A 2 c 2 ) = 1 + 2 μ β i .
The following examples show the existence of transcendental entire solutions of (6).
Example 4.
Let η 1 2 = 1 1 2 i and
f ( z 1 , z 2 ) = η 1 e 3 z 1 + z 2 .
Thus, f ( z 1 , z 2 ) is a transcendental entire solution of (6) with α = 1 , β = i , λ 1 = 1 , λ 2 = 2 , μ = 1 , ( c 1 , c 2 ) = ( π 2 i , 2 π i ) and ρ ( f ) = 1 . This shows that the form of solution in the conclusion (i) of Theorem 5 is precise.
Example 5.
Let
f ( z 1 , z 2 ) = 1 2 ( 2 + 1 i ) e A 1 z 1 + A 2 z 2 + 1 2 ( 2 1 + i ) e A 1 z 1 A 2 z 2 1 2 sin [ 2 π i ( 2 z 1 z 2 ) ] e 2 z 1 + 2 ( 2 z 1 z 2 ) .
where A 1 = 2 2 log ( 2 + 1 ) ( 2 π ) i and A 2 = log ( 2 + 1 ) 1 + ( π 2 1 ) i . Thus, f ( z 1 , z 2 ) is a transcendental entire solution of (6) with α = 1 , β = 1 , λ 1 = 1 , λ 2 = 2 , μ = 2 , ( c 1 , c 2 ) = ( 1 , 3 ) and ρ ( f ) = 1 . This shows that the form of solution in the conclusion (ii) of Theorem 5 is precise.
From Theorem 5, we have
Corollary 4.
Let c = ( c 1 , c 2 ) C 2 and c 1 c 2 . If f ( z 1 , z 2 ) is a finite order transcendental entire solution of equation
f ( z ) + f z 1 ( z ) + f z 2 ( z ) 2 + [ f ( z + c ) f ( z ) ] 2 = 1 ,
then f ( z 1 , z 2 ) must be of the form
f ( z 1 , z 2 ) = ± 1 e z 1 + A ( z 2 z 1 ) + B ,
where A , B are constants and
A ( c 2 c 1 ) = c 1 + 2 k π i , k Z ;
or
f ( z 1 , z 2 ) = 1 2 ( 1 i ) e i z 1 + A 2 z 2 + B + 1 2 ( 1 + i ) e i z 1 A 2 z 2 B + ϑ ( z 1 z 2 ) e z 1 ,
where ϑ ( z 1 z 2 ) is a finite order entire function, A 2 , B are constants and
e 2 ( i c 1 + A 2 c 2 ) = 1 , ϑ ( z 1 z 2 + c 1 c 2 ) ϑ ( z 1 z 2 ) = e c 1 c 2 ,
When α = 1 and β = 0 in Equation (6), we obtain
Corollary 5.
Let c = ( c 1 , c 2 ) C 2 and λ 1 , λ 2 , μ be nonzero constants such that λ 1 c 2 λ 2 c 1 0 . If f ( z 1 , z 2 ) is a finite order transcendental entire solution of equation
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) 2 + f ( z + c ) 2 = 1 ,
then f ( z 1 , z 2 ) must be of the form
f ( z 1 , z 2 ) = 1 2 ( μ + λ 1 A 1 + λ 2 A 2 ) e A 1 z 1 + A 2 z 2 + B + 1 2 ( μ λ 1 A 1 λ 2 A 2 ) e A 1 z 1 A 2 z 2 B ,
where a 1 , a 2 , b are constants and satisfying
( λ 1 A 1 + λ 2 A 2 ) 2 = μ 2 1 , e 2 ( A 1 c 1 + A 2 c 2 ) = λ 1 A 1 + λ 2 A 2 + μ λ 1 A 1 + λ 2 A 2 μ ,
Remark 3.
From Corollary 5, the order of f must be 1. However, we can find the transcendental entire solutions of Equation (17) of the order greater than one if λ 1 c 2 λ 2 c 1 = 0 . For example, let
f ( z ) = 1 2 i ( 3 + 2 ) e z 1 + z 2 + [ ( 2 i 1 ) z 1 z 2 ] 3 + 1 2 i ( 3 2 ) e z 1 z 2 [ ( 2 i 1 ) z 1 z 2 ] 3 ,
then ρ ( f ) = 3 and f is a transcendental entire solution of equation
3 i f ( z 1 , z 2 ) + f z 1 + ( 2 i 1 ) f z 2 2 + f z 1 + 1 2 i ln ( 2 + 3 ) , z 2 + 2 i 1 2 i ln ( 2 + 3 ) 2 = 1 .
When α = 0 and β = 1 in Equation (6), similar to the argument as in the proof of Corollary 3, we have
Corollary 6.
Let λ 1 , λ 2 , μ be two nonzero constants. Then, the following partial differential equation
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) 2 + f ( z ) 2 = 1
does not admit any finite order transcendental entire solution.

3. Some Lemmas

The following lemma plays the key role in proving our results.
Lemma 1
([39] Lemma 3.1). Let f j ( 0 ) , j = 1 , 2 , 3 be meromorphic functions on C m such that f 1 is not constant, and f 1 + f 2 + f 3 = 1 , and such that
j = 1 3 N 2 ( r , 1 f j ) + 2 N ¯ ( r , f j ) < λ T ( r , f 1 ) + O ( log + T ( r , f 1 ) ) ,
for all r outside possibly a set with finite logarithmic measure, where λ < 1 is a positive number. Then, either f 2 = 1 or f 3 = 1 .
Remark 4.
Here, N 2 ( r , 1 f ) is the counting function of the zeros of f in | z | r , where the simple zero is counted once, and the multiple zero is counted twice.

4. The Proof of Theorem 4

Proof. 
Suppose that f is a transcendental entire solution of Equation (5) with finite order. Now, we will divide into two cases below.
(i) If λ f z 1 + μ f is a constant, let
λ f z 1 + μ f = η 1 ,
and
α f ( z + c ) β f ( z ) = η 2 ,
where η 1 , η 2 are constants in C . In view of (5), it follows that
η 1 2 + η 2 2 = 1 ,
Solving Equation (19), we have
f ( z ) = η 1 e μ λ z 1 + ϕ ( z 2 ) μ ,
where ϕ ( z 2 ) is an entire function in z 2 . Substituting (22) into (20), it yields
α η 1 e μ λ ( z 1 + c 1 ) + ϕ ( z 2 + c 2 ) μ β η 1 e μ λ z 1 + ϕ ( z 2 ) μ = η 2 ,
Thus, it follows from (23) that
( α β ) η 1 = μ η 2 , α μ e μ λ ( z 1 + c 1 ) + ϕ ( z 2 + c 2 ) + β μ e β λ z 1 + ϕ ( z 2 ) = 0 ,
that is,
η 1 2 = μ 2 μ 2 + ( α β ) 2 , e ϕ ( z 2 + c 2 ) ϕ ( z 2 ) = β α e μ λ c 1 ,
Hence, we have
ϕ ( z 2 ) = A z 2 + b , e A c 2 = β α e μ λ c 1 .
Thus, the conclusion (i) of Theorem 4 is proved from (22) and (24).
(ii) If λ f z 1 + μ f is not a constant, we can rewrite (5) as the form
μ f ( z ) + λ f z 1 ( z ) + i ( α f ( z + c ) β f ( z ) ) μ f ( z ) + λ f z 1 ( z ) i ( α f ( z + c ) β f ( z ) ) = 1 .
Since f is an entire function, it follows that μ f ( z ) + λ f z 1 ( z ) + i ( α f ( z + c ) β f ( z ) ) and μ f ( z ) + λ f z 1 ( z ) i ( α f ( z + c ) β f ( z ) ) do not exist zeros and poles. Thus, by virtue of Refs. [3,10,11], there exists a nonconstant polynomial p ( z ) in C 2 such that
μ f ( z ) + λ f z 1 ( z ) + i ( α f ( z + c ) β f ( z ) ) = e p ( z ) , μ f ( z ) + λ f z 1 ( z ) i ( α f ( z + c ) β f ( z ) ) = e p ( z ) .
The above equations lead to
μ f ( z ) + λ f z 1 ( z ) = 1 2 ( e p + e p ) ,
α f ( z + c ) β f ( z ) = 1 2 i ( e p e p ) .
In view of (25) and (26), we can deduce that
β μ f ( z ) + β λ f z 1 ( z ) = α 2 ( e p ( z + c ) + e p ( z + c ) ) λ p z 1 + μ 2 i e p ( z ) λ p z 1 μ 2 i e p ( z ) .
Thus, it yields from (25) and (27) that
λ p z 1 + μ + β i α i e p ( z ) + p ( z + c ) + λ p z 1 μ + β i α i e p ( z + c ) p ( z ) e 2 p ( z + c ) 1 .
Noting that μ 0 , we thus have that λ p z 1 + μ + β i α i 0 and λ p z 1 μ + β i α i 0 can not hold at the same time. Otherwise, it follows from (28) that e 2 p ( z + c ) = 1 , that is, p ( z ) 0 , which is a contradiction with p ( z ) being a nonconstant polynomial.
If λ p z 1 μ + β i α i 0 , it follows that λ p z 1 + μ + β i α i 0 from (28) and that
λ p z 1 + μ + β i α i e p ( z ) + p ( z + c ) e 2 p ( z + c ) 1 .
By using the second basic theorem for the function e 2 p ( z + c ) , we have from (29) that
T ( r , e 2 p ( z + c ) ) N r , 1 e 2 p ( z + c ) + N r , 1 e 2 p ( z + c ) + 1 + S ( r , e 2 p ( z + c ) ) N r , 1 λ p z 1 + μ + β i α i e p ( z ) + p ( z + c ) + S ( r , e 2 p ( z + c ) ) O ( log r ) + S ( r , e 2 p ( z + c ) ) ;
this is impossible. If λ p z 1 + μ + β i α i 0 , similar to the argument as in the above, we also obtain a contradiction. Hence, we have λ p z 1 + μ + β i α i 0 and λ p z 1 μ + β i α i 0 .
By Lemma 1, we have
λ p z 1 + μ + β i α i e p ( z ) + p ( z + c ) 1 , o r λ p z 1 μ + β i α i e p ( z + c ) p ( z ) 1 .
If
λ p z 1 + μ + β i α i e p ( z ) + p ( z + c ) 1 ,
then p ( z ) + p ( z + c ) should be constant; this is a contradiction.
If
λ p z 1 μ + β i α i e p ( z + c ) p ( z ) 1 ,
then p ( z + c ) p ( z ) is a constant. Thus, we have p ( z ) = L ( z ) + H ( c 2 z 1 c 1 z 2 ) + b , where L ( z ) = A 1 z 1 + A 2 z 2 , H ( s ) is a polynomial in s = c 2 z 1 c 1 z 2 , A 1 , A 2 , B are constants in C . By combining (30) with (28), we have
λ p z 1 + μ + β i α i e p ( z ) p ( z + c ) 1 .
Substituting p ( z ) into (30) and (31), it follows that
λ ( A 1 + c 2 H ) μ + β i α i e L ( c ) 1 , λ ( A 1 + c 2 H ) + μ + β i α i e L ( c ) 1 ,
where L ( c ) = A 1 c 1 + A 2 c 2 . Thus, we have that c 2 H is a constant, which implies deg s H 1 as c 2 0 . This shows that L ( z ) + H ( c 2 z 1 c 1 z 2 ) + B is a linear form of z 1 , z 2 . For convenience, we still denote it to be p ( z ) = L ( z ) + B . Thus, it follows from (32) that
λ A 1 μ + β i α i e L ( c ) 1 , λ A 1 + μ + β i α i e L ( c ) 1 .
This leads to
( λ A 1 + β i ) 2 = μ 2 α 2 , e 2 L ( c ) = λ A 1 + μ + β i λ A 1 μ + β i .
Substituting p ( z ) = A 1 z 1 + A 2 z 2 + B into the Equation (25), it follows
μ f ( z ) + λ f z 1 = 1 2 ( e A 1 z 1 + A 2 z 2 + B + e A 1 z 1 A 2 z 2 B ) .
If A 1 ± μ λ , solving Equation (35), we have
f ( z 1 , z 2 ) = 1 2 ( λ A 1 + μ ) e A 1 z 1 + A 2 z 2 + B 1 2 ( λ A 1 μ ) e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function. Substituting (36) into (26), and combining with (34), we have
( λ A 1 + β i ) 2 = μ 2 α 2 , e 2 ( A 1 c 1 + A 2 c 2 ) = λ A 1 + μ + β i λ A 1 μ + β i ,
and
ϑ ( z 2 + c 2 ) ϑ ( z 2 ) = β α e μ λ c 1 .
If A 1 = μ λ , similar to the above argument, we have
f ( z 1 , z 2 ) = 1 4 μ e A 1 z 1 + A 2 z 2 + B + z 1 2 λ e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function satisfying (37). Substituting (38) into (26), and combining with (34), it follows that f ( z 1 , z 2 ) satisfies (8).
If A 1 = μ λ , similar to the above argument, we have
f ( z 1 , z 2 ) = z 1 2 λ e A 1 z 1 + A 2 z 2 + B + 1 4 μ e A 1 z 1 A 2 z 2 B + ϑ ( z 2 ) e μ λ z 1 ,
where ϑ ( z 2 ) is a finite order entire function satisfying (37). Substituting (39) into (26), and combining with (34), it follows that f ( z 1 , z 2 ) satisfies (9).
Therefore, this completes the proof of Theorem 4. □

5. The Proof of Theorem 5

Proof. 
Suppose that f is a transcendental entire solution of Equation (6) with a finite order. Two cases will be considered below.
(i) If λ 1 f z 1 + λ 2 f z 2 + μ f is a constant, let
λ 1 f z 1 + λ 2 f z 2 + μ f = η 1 ,
and
α f ( z + c ) β f ( z ) = η 2 ,
where η 1 , η 2 are constants in C satisfying (21) from (6). The characteristic equations of (40) are
d z 1 d t = λ 1 , d z 2 d t = λ 2 , d f d t = η 1 μ f .
Using the initial conditions: z 1 = 0 , z 2 = s 1 , and f = f ( 0 , s 1 ) with a parameter s. Thus, we obtain the following parametric representation for the solutions of the characteristic equations: z 1 = λ 1 t , z 2 = λ 2 t + s 1 , and
f ( z 1 , z 2 ) = η 1 μ 1 μ e μ λ 1 z 1 + φ ( s 1 ) ,
where φ ( s 1 ) is an entire function in s 1 : = λ 1 z 2 λ 2 z 1 . Substituting (42) into (41), we have
α η 1 μ 1 μ e μ λ 1 ( z 1 + c 1 ) + φ ( s 1 + s 0 ) β η 1 μ 1 μ e μ λ 1 z 1 + φ ( s 1 ) = η 2 ,
which implies that
α η 1 μ β η 1 μ η 2 , α μ e μ λ 1 ( z 1 + c 1 ) + φ ( s 1 + s 0 ) β μ e μ λ 1 z 1 + φ ( s 1 ) 0 ,
where s 0 : = λ 2 c 1 λ 1 c 2 . In view of (21), we have
η 1 2 = μ 2 μ 2 + ( α β ) 2 ,
and
e φ ( s 1 + s 0 ) φ ( s 1 ) = β α e μ λ 1 c 1 .
Thus, it follows that φ ( s 1 ) = A s 1 + b where A , b are constants satisfying
e A s 0 = e A ( λ 2 c 1 λ 1 c 2 ) = β α e μ λ 1 c 1 .
In view of (42)–(44), we have
f ( z 1 , z 2 ) = η 1 μ 1 μ e μ λ 1 z 1 + A ( λ 2 z 1 λ 1 z 2 ) + b ,
where α , β , μ , λ 1 , λ 2 , η 1 , c 1 , c 2 , A are constants and satisfying (43) and (44). Therefore, this proves the conclusion (i) of Theorem 5.
(ii) If λ 1 f z 1 + λ 2 f z 2 + μ f is not a constant, we can rewrite (6) as the form
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) + i ( α f ( z + c ) β f ( z ) ) × μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) i ( α f ( z + c ) β f ( z ) ) = 1 .
Since f is an entire function, it follows that μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) + i ( α f ( z + c ) β f ( z ) ) and μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) i ( α f ( z + c ) β f ( z ) ) do not exist zeros and poles. Thus, by virtue of Refs. [3,10,11], there exists a nonconstant polynomial p ( z ) in C 2 such that
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) + i ( α f ( z + c ) β f ( z ) ) = e p ( z ) , μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) i ( α f ( z + c ) β f ( z ) ) = e p ( z ) .
The above equations lead to
μ f ( z ) + λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) = 1 2 ( e p + e p ) ,
α f ( z + c ) β f ( z ) = 1 2 i ( e p e p ) .
In view of (46) and (47), we can deduce that
α μ f ( z + c ) + β λ 1 f z 1 ( z ) + λ 2 f z 2 ( z ) = α 2 ( e p ( z + c ) + e p ( z + c ) ) λ 1 p z 1 + λ 2 p z 2 2 i ( e p ( z ) + e p ( z ) ) .
From (48) and (46), we have
α μ f ( z + c ) β μ f ( z ) = α 2 ( e p ( z + c ) + e p ( z + c ) ) λ 1 p z 1 + λ 2 p z 2 + β i 2 i ( e p ( z ) + e p ( z ) ) .
Thus, it yields from (46) and (49) that
λ 1 p z 1 + λ 2 p z 2 + μ + β i α i e p ( z ) + p ( z + c ) + λ 1 p z 1 + λ 2 p z 2 μ + β i α i e p ( z + c ) p ( z ) e 2 p ( z + c ) 1 .
By using the same argument as in the proof of Theorem 4, we have λ 1 p z 1 + λ 2 p z 2 + μ + β i α i 0 and λ 1 p z 1 + λ 2 p z 2 μ + β i α i 0 . By Lemma 1 and (50), we have
λ 1 p z 1 + λ 2 p z 2 + μ + β i α i e p ( z ) + p ( z + c ) 1 , o r λ 1 p z 1 + λ 2 p z 2 μ + β i α i e p ( z + c ) p ( z ) 1 .
If
λ 1 p z 1 + λ 2 p z 2 + μ + β i α i e p ( z ) + p ( z + c ) 1 ,
then p ( z ) + p ( z + c ) should be constant; this is a contradiction.
If
λ 1 p z 1 + λ 2 p z 2 μ + β i α i e p ( z + c ) p ( z ) 1 ,
then p ( z + c ) p ( z ) is a constant. Thus, we have p ( z ) = L ( z ) + H ( c 2 z 1 c 1 z 2 ) + b , where L ( z ) = A 1 z 1 + A 2 z 2 , H ( s ) is a polynomial in s = c 2 z 1 c 1 z 2 , A 1 , A 2 , B are constants in C . By combining (51) with (50), we have
λ 1 p z 1 + λ 2 p z 2 + μ + β i α i e p ( z ) p ( z + c ) 1 .
Substituting p ( z ) into (51) and (52), it follows that
λ 1 A 1 + λ 2 A 2 + ( λ 1 c 2 λ 2 c 1 ) H μ + β i α i e L ( c ) 1 ,
λ 1 A 1 + λ 2 A 2 + ( λ 1 c 2 λ 2 c 1 ) H + μ + β i α i e L ( c ) 1 .
Thus, we have that ( λ 1 c 2 λ 2 c 1 ) H is a constant, which implies deg s H 1 as λ 1 c 2 λ 2 c 1 0 . This shows that L ( z ) + H ( c 2 z 1 c 1 z 2 ) + B is a linear form of z 1 , z 2 . For convenience, we still assume that p ( z ) = L ( z ) + B . Thus, it follows from (53) and (54) that
λ 1 A 1 + λ 2 A 2 μ + β i α i e L ( c ) 1 , λ 1 A 1 + λ 2 A 2 + μ + β i α i e L ( c ) 1 .
This leads to
( λ 1 A 1 + λ 2 A 2 + β i ) 2 = μ 2 α 2 , e 2 L ( c ) = λ 1 A 1 + λ 2 A 2 + μ + β i λ 1 A 1 + λ 2 A 2 μ + β i .
Substituting p ( z ) = A 1 z 1 + A 2 z 2 + B into the Equation (46), it follows
μ f ( z ) + λ 1 f z 1 + λ 2 f z 2 = 1 2 ( e A 1 z 1 + A 2 z 2 + B + e A 1 z 1 A 2 z 2 B ) .
If μ 2 ( λ 1 A 1 + λ 2 A 2 ) 2 , solving Equation (57), we have
f ( z 1 , z 2 ) = 1 2 ( λ 1 A 1 + λ 2 A 2 + μ ) e A 1 z 1 + A 2 z 2 + B 1 2 ( λ 1 A 1 + λ 2 A 2 μ ) e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ is a finite order entire function in s 1 . Substituting (58) into (47), and combining with (55), we have
ϑ ( s 1 + s 0 ) ϑ ( s 1 ) = β α e μ λ 1 s 0 ,
where s 0 = λ 2 c 1 λ 1 c 2 . Therefore, in view of (56), (58), and (59), we have
f ( z 1 , z 2 ) = 1 2 ( λ 1 A 1 + λ 2 A 2 + μ ) e A 1 z 1 + A 2 z 2 + B 1 2 ( λ 1 A 1 + λ 2 A 2 μ ) e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ is a finite order entire function in s 1 , and A 1 , A 2 , B are constants satisfying (56) and (59).
If μ = λ 1 A 1 + λ 2 A 2 , solving Equation (56), similar to the above argument, we have
f ( z 1 , z 2 ) = 1 4 μ e A 1 z 1 + A 2 z 2 + B + z 1 2 λ 1 e A 1 z 1 A 2 z 2 B + ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ ( s 1 ) is a finite order entire function satisfying (59). Substituting (61) into (47), and combining with (55), we can obtain (15).
If μ = ( λ 1 A 1 + λ 2 A 2 ) , solving Equation (56), similar to the above argument, we have
f ( z 1 , z 2 ) = z 1 2 λ 1 e A 1 z 1 + A 2 z 2 + B + 1 4 μ e A 1 z 1 A 2 z 2 B ϑ ( s 1 ) e μ λ 1 z 1 ,
where ϑ ( s 1 ) is a finite order entire function satisfying (59). Substituting (62) into (47), and combining with (55), we can obtain (16).
Therefore, we complete the proof of Theorem 5. □

6. Conclusions

From Theorems 4 and 5, we investigate the transcendental entire solutions of two classes of partial differential-difference equations with constant coefficients, which are more general than the previous equations given by [19,20,38]. We describe the forms of the finite order transcendental entire solutions of these equations under the different conditions of the coefficients, and we also give several examples to demonstrate that every form of the solutions of these equations are precise. By comparing previous relevant references, we can find that our results are some improvements and generalizations of the previous theorems [19,20,38].

Author Contributions

Conceptualization, H.X. and H.M.S.; writing—original draft preparation, H.X., L.X. and H.M.S.; writing—review and editing, H.X., L.X. and H.M.S.; funding acquisition, H.X. All authors have read and agreed to the published version of the manuscript.

Funding

This work was supported by the National Natural Science Foundation of China (12161074), and the Talent Introduction Research Foundation of Suqian University (106-CK00042/028).

Data Availability Statement

Not applicable.

Conflicts of Interest

The authors declare no conflict of interest.

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Xu, H.; Xu, L.; Srivastava, H.M. The Exact Solutions for Several Partial Differential-Difference Equations with Constant Coefficients. Mathematics 2022, 10, 3596. https://doi.org/10.3390/math10193596

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Xu H, Xu L, Srivastava HM. The Exact Solutions for Several Partial Differential-Difference Equations with Constant Coefficients. Mathematics. 2022; 10(19):3596. https://doi.org/10.3390/math10193596

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Xu, Hongyan, Ling Xu, and Hari Mohan Srivastava. 2022. "The Exact Solutions for Several Partial Differential-Difference Equations with Constant Coefficients" Mathematics 10, no. 19: 3596. https://doi.org/10.3390/math10193596

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Xu, H., Xu, L., & Srivastava, H. M. (2022). The Exact Solutions for Several Partial Differential-Difference Equations with Constant Coefficients. Mathematics, 10(19), 3596. https://doi.org/10.3390/math10193596

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