Skip to content

Advertisement

Boundary Value Problems
Boundary Value Problems Cover Image
  • Research Article
  • Open Access

A New Conservative Difference Scheme for the General Rosenau-RLW Equation

Boundary Value Problems20102010:516260

https://doi.org/10.1155/2010/516260

©  Jin-Ming Zuo et al. 2010

  • Received: 28 May 2010
  • Accepted: 14 October 2010
  • Published:

Abstract

A new conservative finite difference scheme is presented for an initial-boundary value problem of the general Rosenau-RLW equation. Existence of its difference solutions are proved by Brouwer fixed point theorem. It is proved by the discrete energy method that the scheme is uniquely solvable, unconditionally stable, and second-order convergent. Numerical examples show the efficiency of the scheme.

Keywords

  • Difference Scheme
  • Fixed Point Theorem
  • Truncation Error
  • Discrete Function
  • Discrete Energy

1. Introduction

In this paper, we consider the following initial-boundary value problem of the general Rosenau-RLW equation:
(11)
with an initial condition
(12)
and boundary conditions
(13)
where is a integer and is a known smooth function. When , (1.1) is called as usual Rosenau-RLW equation. When , (1.1) is called as modified Rosenau-RLW (MRosenau-RLW) equation. The initial boundary value problem (1.1)–(1.3) possesses the following conservative quantities:
(14)
(15)

It is known the conservative scheme is better than the nonconservative ones. Zhang et al. [1] point out that the nonconservative scheme may easily show nonlinear blow up. In [2] Li and Vu-Quoc said " in some areas, the ability to preserve some invariant properties of the original differential equation is a criterion to judge the success of a numerical simulation". In [311], some conservative finite difference schemes were used for a system of the generalized nonlinear Schrödinger equations, Regularized long wave (RLW) equations, Sine-Gordon equation, Klein-Gordon equation, Zakharov equations, Rosenau equation, respectively. Numerical results of all the schemes are very good. Hence, we propose a new conservative difference scheme for the general Rosenau-RLW equation, which simulates conservative laws (1.4) and (1.5) at the same time. The outline of the paper is as follows. In Section 2, a nonlinear difference scheme is proposed and corresponding convergence and stability of the scheme are proved. In Section 3, some numerical experiments are shown.

2. A Nonlinear-Implicit Conservative Scheme

In this section, we propose a nonlinear-implicit conservative scheme for the initial-boundary value problem (1.1)–(1.3) and give its numerical analysis.

2.1. The Nonlinear-Implicit Scheme and Its Conservative Law

For convenience, we introduce the following notations
(21)
where and denote the spatial and temporal mesh sizes, , , respectively,
(22)

and in the paper, denotes a general positive constant, which may have different values in different occurrences.

Since , then the finite difference scheme for the problem (1.1)–(1.3) is written as follows:
(23)
(24)
(25)

Lemma 2.1 (see [12]).

For any two mesh functions, , one has
(26)
Furthermore, if , then
(27)

Theorem 2.2.

Suppose that , then scheme (2.3)–(2.5) is conservative in the senses:
(28)
(29)

Proof.

Multiplying (2.3) with , according to boundary condition (2.5), and then summing up for from 1 to , we have
(210)
Let
(211)

Then (2.8) is gotten from (2.10).

Computing the inner product of (2.3) with , according to boundary condition (2.5) and Lemma 2.1, we obtain
(212)
where
(213)
According to
(214)
we have . It follows from (2.12) that
(215)
Let
(216)

Then (2.9) is gotten from (2.15). This completes the proof of Theorem 2.2.

2.2. Existence and Prior Estimates of Difference Solution

To show the existence of the approximations for scheme (2.3)–(2.5), we introduce the following Brouwer fixed point theorem [13].

Lemma 2.3.

Let be a finite-dimensional inner product space, be the associated norm, and be continuous. Assume, moreover, that there exist , for all , , . Then, there exists a such that and .

Let , , then have the following.

Theorem 2.4.

There exists which satisfies scheme (2.3)–(2.5).

Proof.

It follows from the original problem (1.1)–(1.3) that satisfies scheme (2.3)–(2.5). Assume there exists which satisfy scheme (2.3)–(2.5), as , now we try to prove that , satisfy scheme (2.3)–(2.5).

We define on as follows:
(217)
where . Computing the inner product of (2.17) with and considering and , we obtain
(218)

Hence, for all , there exists . It follows from Lemma 2.3 that exists which satisfies . Let , then it can be proved that is the solution of scheme (2.3)–(2.5). This completes the proof of Theorem 2.4.

Next we will give some priori estimates of difference solutions. First the following two lemmas [14] are introduced:

Lemma 2.5 (discrete Sobolev's estimate).

For any discrete function on the finite interval , there is the inequality
(219)

where are two constants independent of and step length .

Lemma 2.6 (discrete Gronwall's inequality).

Suppose that the discrete function satisfies the inequality
(220)
where and are nonnegative constants. Then
(221)

where is sufficiently small, such that .

Theorem 2.7.

Suppose that , then the following inequalities
(222)

hold.

Proof.

It is follows from (2.9) that
(223)
According to Lemma 2.5, we obtain
(224)

This completes the proof of Theorem 2.7.

Remark 2.8.

Theorem 2.7 implies that scheme (2.3)–(2.5) is unconditionally stable.

2.3. Convergence and Uniqueness of Difference Solution

First, we consider the convergence of scheme (2.3)–(2.5). We define the truncation error as follows:
(225)

then from Taylor's expansion, we obtain the following.

Theorem 2.9.

Suppose that and , then the truncation errors of scheme (2.3)–(2.5) satisfy
(226)

as ,

Theorem 2.10.

Suppose that the conditions of Theorem 2.9 are satisfied, then the solution of scheme (2.3)–(2.5) converges to the solution of problem (1.1)–(1.3) with order in the norm.

Proof.

Subtracting (2.3) from (2.25) letting
(227)
we obtain
(228)
Computing the inner product of (2.28) with , we obtain
(229)
From the conservative property (1.5), it can be proved by Lemma 2.5 that . Then by Theorem 2.7 we can estimate (2.29) as follows:
(230)
According to the following inequality [11]
(231)
Substituting (2.30)–(2.31) into (2.29), we obtain
(232)
Let
(233)
then (2.32) can be rewritten as
(234)
Choosing suitable which is small enough, we obtain by Lemma 2.6 that
(235)
From the discrete initial conditions, we know that is of second-order accuracy, then
(236)
Then we have
(237)

It follows from Lemma 2.5, we have . This completes the proof of Theorem 2.10.

Theorem 2.11.

Scheme (2.3)–(2.5) is uniquely solvable.

Proof.

Assume that and both satisfy scheme (2.3)–(2.5), let , we obtain
(238)
Similarly to the proof of Theorem 2.10, we have
(239)

This completes the proof of Theorem 2.11.

Remark 2.12.

All results above in this paper are correct for initial-boundary value problem of the general Rosenau-RLW equation with finite or infinite boundary.

3. Numerical Experiments

In order to test the correction of the numerical analysis in this paper, we consider the following initial-boundary value problems of the general Rosenau-RLW equation:
(31)
with an initial condition
(32)
and boundary conditions
(33)
where . Then the exact solution of the initial value problem (3.1)-(3.2) is
(34)

where is wave velocity.

It follows from (3.4) that the initial-boundary value problem (3.1)–(3.3) is consistent to the boundary value problem (3.3) for . In the following examples, we always choose , .

Tables 1, 2, and 3 give the errors in the sense of -norm and -norm of the numerical solutions under various steps of and at for and . The three tables verify the second-order convergence and good stability of the numerical solutions. Tables 4, 5, and 6 shows the conservative law of discrete mass and discrete energy computed by scheme (2.3)–(2.5) for and .
Table 1

The errors of numerical solutions at with for .

0.4

  

0.2

3.953 296

3.930 200

0.1

3.987 130

3.980 050

0.05

3.997 412

3.994 759

0.025

4.221 051

4.151 348

Table 2

The errors of numerical solutions at with for .

0.4

  

0.2

3.961 294

3.934 592

0.1

3.996 350

3.988 283

0.05

4.003 273

4.000 165

0.025

4.290 286

4.242 688

Table 3

The errors of numerical solutions at with for .

0.4

  

0.2

3.885 945

3.851 797

0.1

3.975 084

3.965 980

0.05

4.000 294

3.995 992

0.025

4.391 818

4.381 199

Table 4

Discrete mass and discrete energy with at various for .

 

10

1.897 658 262 960 01

0.533 175 231 580 85

20

1.897 658 268 873 21

0.533 175 231 872 51

30

1.897 658 262 993 93

0.533 175 231 177 25

40

1.897 658 265 568 93

0.533 175 231 478 09

50

1.897 658 260 975 87

0.533 175 231 776 18

60

1.897 658 265 384 88

0.533 175 231 074 05

Table 5

Discrete mass and discrete energy with at various for .

 

10

2.672 608 675 265 30

1.113 462 678 852 70

20

2.672 608 676 236 58

1.113 462 678 465 22

30

2.672 608 674 147 13

1.113 462 678 083 94

40

2.672 608 672 639 88

1.113 462 678 711 58

50

2.672 608 672 874 71

1.113 462 678 330 06

60

2.672 608 679 729 44

1.113 462 678 958 71

Table 6

Discrete mass and discrete energy with at various for .

 

10

3.988 663 320 390 89

1.917 613 014 656 71

20

3.988 663 260 854 26

1.917 613 014 739 89

30

3.988 663 167 685 49

1.917 613 014 820 83

40

3.988 663 194 506 97

1.917 613 014 927 44

50

3.988 663 973 359 89

1.917 613 014 009 71

60

3.988 663 621 972 59

1.917 613 014 679 17

Figures 1, 2, and 3 plot the exact solutions at and the numerical solutions computed by scheme (2.3)–(2.5) with at , which also show the accuracy of scheme (2.3)–(2.5).
Figure 1
Figure 1

Exact solutions of at and numerical solutions computed by scheme (2. 3)–(2.5) at for .

Figure 2
Figure 2

Exact solutions of at and numerical solutions computed by scheme (2. 3)–(2.5) at for .

Figure 3
Figure 3

Exact solutions of at and numerical solutions computed by scheme (2. 3)–(2.5) at for .

Declarations

Acknowledgments

The authors would like to express their sincere thanks to the referees for their valuable suggestions and comments. This paper is supported by the National Natural Science Foundation of China (nos. 10871117 and 10571110).

Authors’ Affiliations

(1)
School of Science, Shandong University of Technology, Zibo, 255049, China
(2)
School of Mathematics, Shandong University, Jinan, 250100, China

References

  1. Zhang F, Pérez-García VM, Vázquez L: Numerical simulation of nonlinear Schrödinger systems: a new conservative scheme. Applied Mathematics and Computation 1995,71(2-3):165-177. 10.1016/0096-3003(94)00152-TMathSciNetView ArticleMATHGoogle Scholar
  2. Li S, Vu-Quoc L: Finite difference calculus invariant structure of a class of algorithms for the nonlinear Klein-Gordon equation. SIAM Journal on Numerical Analysis 1995,32(6):1839-1875. 10.1137/0732083MathSciNetView ArticleMATHGoogle Scholar
  3. Chang Q, Xu L: A numerical method for a system of generalized nonlinear Schrödinger equations. Journal of Computational Mathematics 1986,4(3):191-199.MathSciNetMATHGoogle Scholar
  4. Chang Q, Jia E, Sun W: Difference schemes for solving the generalized nonlinear Schrödinger equation. Journal of Computational Physics 1999,148(2):397-415. 10.1006/jcph.1998.6120MathSciNetView ArticleMATHGoogle Scholar
  5. Wang T-C, Zhang L-M: Analysis of some new conservative schemes for nonlinear Schrödinger equation with wave operator. Applied Mathematics and Computation 2006,182(2):1780-1794. 10.1016/j.amc.2006.06.015MathSciNetView ArticleMATHGoogle Scholar
  6. Wang T, Guo B, Zhang L: New conservative difference schemes for a coupled nonlinear Schrödinger system. Applied Mathematics and Computation 2010,217(4):1604-1619. 10.1016/j.amc.2009.07.040MathSciNetView ArticleMATHGoogle Scholar
  7. Zhang L: A finite difference scheme for generalized regularized long-wave equation. Applied Mathematics and Computation 2005,168(2):962-972. 10.1016/j.amc.2004.09.027MathSciNetView ArticleMATHGoogle Scholar
  8. Zhang F, Vázquez L: Two energy conserving numerical schemes for the sine-Gordon equation. Applied Mathematics and Computation 1991,45(1):17-30. 10.1016/0096-3003(91)90087-4MathSciNetView ArticleMATHGoogle Scholar
  9. Wong YS, Chang Q, Gong L: An initial-boundary value problem of a nonlinear Klein-Gordon equation. Applied Mathematics and Computation 1997,84(1):77-93. 10.1016/S0096-3003(96)00065-3MathSciNetView ArticleMATHGoogle Scholar
  10. Chang QS, Guo BL, Jiang H: Finite difference method for generalized Zakharov equations. Mathematics of Computation 1995,64(210):537-553. 10.1090/S0025-5718-1995-1284664-5MathSciNetView ArticleMATHGoogle Scholar
  11. Hu JS, Zheng KL: Two conservative difference schemes for the generalized Rosenau equation. Boundary Value Problems 2010, 2010:-18.Google Scholar
  12. Hu B, Xu Y, Hu J: Crank-Nicolson finite difference scheme for the Rosenau-Burgers equation. Applied Mathematics and Computation 2008,204(1):311-316. 10.1016/j.amc.2008.06.051MathSciNetView ArticleMATHGoogle Scholar
  13. Browder FE: Existence and uniqueness theorems for solutions of nonlinear boundary value problems. In Proceedings of Symposia in Applied Mathematics, vol. 17. American Mathematical Society, Providence, RI, USA; 1965:24-49.Google Scholar
  14. Zhou Y: Applications of Discrete Functional Analysis to the Finite Difference Method. International Academic Publishers, Beijing, China; 1991:vi+260.MATHGoogle Scholar

Copyright

© Jin-Ming Zuo et al. 2010

This article is published under license to BioMed Central Ltd. This is an open access article distributed under the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Advertisement