Limiting Behavior of Travelling Waves for the Modified Degasperis-Procesi Equation
Jiuli Yin,1Liuwei Zhao,1and Shanyu Ding1
Academic Editor: Xing Biao Hu
Received18 Feb 2014
Revised06 May 2014
Accepted27 May 2014
Published09 Jul 2014
Abstract
Using an improved qualitative method which combines characteristics of several methods, we classify all travelling wave solutions of the modified Degasperis-Procesi equation in specified regions of the parametric space. Besides some popular exotic solutions including peaked waves, and looped and cusped waves, this equation also admits some very particular waves, such as fractal-like waves, double stumpons, double kinked waves, and butterfly-like waves. The last three types of solutions have not been reported in the literature. Furthermore, we give the limiting behavior of all periodic solutions as the parameters trend to some special values.
1. Introduction
The Degasperis-Procesi (DP) equation
was derived as a member of a one-parameter family of asymptotic shallow water approximations to the Euler equations [1, 2]. Since its discovery, many papers were devoted to the study of (1) (cf. [3–10] and the citations therein).
The DP equation is of interests because of the following two aspects. On one side, (1) is integrable [1]. On another side, the DP equation presents abundant nonlinear phenomena due to the coexistence of nonlinear convections and nonlinear dispersions. Equation (1) admits wave-breaking phenomena and existence of exotic solution including peakons and cuspons [11–15].
To further complement the study of the DP equation, Wazwaz gave and studied the modified Degasperis-Procesi equation (mDP) [16]:
It is clear that the nonlinear convection term has been changed to in (2). Wazwaz employed these modified forms as a vehicle to explore the change in the physical structure of the solution. Many researchers have obtained abundant travelling wave solutions by different methods. Ma et al. [17] applied the auxiliary equation method to obtain some new solitary and traveling wave solutions. Rui et al. [18] obtained abundant traveling wave solutions by the integral bifurcation method. In [19], a new characteristic of solitary wave solutions, bell-shaped solitary wave, and peakon coexisting for the same wave speed in mDP equation was found by Liu and Ouyang.
It is noted that the nonsmooth wave solutions of the mDP equation obtained in the previous studies have not been checked in a weak solution way. And new solutions of the mDP equation have been founded.
Motivated by the above two aspects, we try to answer them. It is noticeable that our method to search solutions of the mDP equation is combined with some characteristics of several methods [10–15]. Three characters lie in our method. (i) Definition of weak solutions of the mDP equation is given. (ii) More new exotic solutions are obtained. The parameter space is divided in further detail. (iii) The limiting behavior of traveling wave solutions is given.
This paper is organized as follows. In Section 2, we give the definition of weak solutions. In Section 3, we give theorems of the classification of travelling waves in the mDP equation. In Section 4, we give the proof. Section 5 is the conclusion.
2. Definitions and Notations
In this section, we will give the classification of travelling wave solutions of (2), which is stated in Theorem 3.
For a travelling wave , (2) takes the form
where is the wave speed.
By integrating with respect to and letting the integral constant be zero, (3) becomes
Equation (4) makes sense for all . The following definition is therefore natural.
Definition 1. A function is a travelling wave solution of (2) if satisfies (4) in distribution sense for some .
Like the proof of the proceeding of Lemmas 4 and 5 in [15], we can give the following definition of weak traveling wave solutions.
Definition 2. Any bounded function belongs to and is a travelling wave solution of (2) with speed if it satisfies the following two statements.(a)There are disjoint open intervals , , and a closed set such that , for , for , and for .(b)There is an such that(i)For each , there exists such thatwhere
and , at any finite endpoint of .(ii)If has strictly positive Lebesgue measure , we have .
3. Main Results
Let , , and be defined as in (11). All travelling wave solutions of (1) are smooth except at points where . We state our main result as follows.
Theorem 3. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling wave solutions.(2)For , there exists a periodic wave solution.(3)For , there exist a periodic wave solution and a looped periodic wave solution. Moreover, as , the periodic wave solution converges to a solitary wave solution pointing downward and the looped periodic wave solution converges to a looped wave solution.(4)For , there exists a looped periodic wave solution. Moreover, the looped periodic wave solution converges to a rotated looped wave solution.(5)For , there exists a cusped periodic wave solution.
Theorem 4. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling wave solutions.(2)For , there exists a periodic wave solution.(3)For , there exist periodic and looped periodic wave solutions. Moreover, as , the periodic wave solution converges to a solitary wave solution pointing downward and the looped periodic wave solution converges to a butterfly-like wave solution.(4)For , there exists a cusped periodic wave solution.
Theorem 5. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling wave solutions.(2)For , there exists a periodic wave solution.(3)For , there exist a periodic wave solution and a looped periodic wave solution. Moreover, as , the looped periodic wave solution converges to a looped wave solution pointing downward.(4)If , there exist a periodic wave solution and a cusped periodic wave solution. Moreover, as , the periodic wave solution converges to a solitary wave solution pointing downward and the cusped periodic wave solution converges to a cusped wave solution.(5)If , there exists a cusped periodic wave solution.
Theorem 6. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling wave solutions.(2)For , there exists a periodic wave solution. Moreover, as , there exists a cusped wave solution and the periodic wave solution converges to solitary wave solution pointing downward.(3)For , there exists a cusped periodic wave solution.
Theorem 7. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling wave solutions.(2)For , there exists a periodic wave solution.(3)For , there exist two distinct periodic wave solutions. Moreover, as , one of these periodic wave solutions converges to a peaked periodic wave solution pointing downward.(4)For , there exist a periodic wave solution and a cusped periodic wave solution. Moreover, as , the periodic wave solution converges a solitary wave solution pointing downward and the cusped periodic wave solution converges to a cusped wave solution.(5)For , there exists a cusped periodic wave solution.
Theorem 8. If , any travelling wave solution of (1) falls into one of the following categories.(1)If , there are no bounded traveling solitary wave solutions.(2)If , there exists a periodic wave solution.(3)If , there are two types of periodic wave solution. Moreover, as , the two periodic wave solutions converge to solitary wave solution pointing downward and peaked wave solution.(4)If , there exists a cusped periodic wave solution.
Theorem 9. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling solitary wave solutions.(2)For , there exists a periodic wave solution.(3)For , there are two types of periodic wave solution. Moreover, as , the two periodic wave solutions converge to solitary wave solution pointing downward and solitary wave solution.(4)For , there exists a periodic wave solution. Moreover, as , the periodic wave solution converges to a peaked periodic wave solution.(5)For , there exists a cusped periodic wave solution.
Theorem 10. If , any travelling wave solution of (1) falls into one of the following categories.(1)For , there are no bounded traveling solitary wave solutions.(2)For , there exists a periodic wave solution. Moreover, as , the periodic wave solution converges to a peaked periodic wave solution.(3)For , there exists a cusped periodic wave solution.
Theorem 11 (composite waves). A countable number of cusped, peaked, and looped waves in the above cases corresponding to the same value of can be joined at points where to form composite waves. If , one can get travelling wave solution with very strange profiles, such as the travelling waves with a fractal appearance (see Figure 1(k)). For ., the composite waves are solutions of (2) even if . Hence we can obtain double stumpons which contain intervals where (see Figure 1(l)).
In this section, we will show that the functions satisfying (a) and (b) in Definition 2 consist exactly of the waves stated in Theorem 3.
Let be a function satisfying (a) and (b) and each wave segment solves the equation
for some interval and constants , .
For determining the solutions of (3), we should give the following facts.
Lemma 12. The qualitative behavior of solutions of near points where has a zero or a pole is as follows.(1)If has a simple zero at , the solution to (6) satisfies ~, where . It is easy to find that smooth solutions exist if has two simple zeros.(2)If has a double zero at , the solution of (6) satisfies ~ as . It is easy to find that smooth solitary wave solutions exist if has a simple zero.(3)Assume that has a double pole at ; then we obtain
where and is some constant. Particularly, if (or ), we get . Then the function is called a cusped wave solution. If , then the function is called a looped wave.(4)Peaked waves occur when the evolution of according to (6) suddenly changes direction at where and ; that is, .(5)Double kinked waves occur when the right-hand side of (6) has two double zeros which are not opposite numbers, and is not between the two zeros. When the pole falls in the interval of the two zeros, butterfly-like waves occur. One reason for the occurrence of these two new solutions is that the solutions to (2) must be symmetry because this equation is invariable under the transformation .
Now we apply the above analysis to
For convenience, we define , , and where
If , we define
Let
Remark 13. It is not difficult to find that has the same zero points as except . It is easy to see that a change in equation (6) will shift the graph vertically up or down.
Now we consider the existence of solutions and their limiting behavior, which have different analytical forms depending on the values of and .
Case A (). In this case, we have the following. (1) If , we can get that has only a simple zero and (see Figure 2(a)). Hence, there are no bounded traveling wave solutions. As , it is easy to find that, as (see Figure 2(b)), has a double zero and a simple zero, so there are no bounded traveling wave solutions either. (2) If , we can observe that has three distinct simple zeros denoted by , , and , and for (see Figure 2(c)). Then there exists a periodic wave solution with and . As , we have and has three distinct simple zeros denoted by , , and (see Figure 2(d)). Then there exists a periodic wave solution with and . (3) If , we can deduce that has five distinct simple zeros denoted by , , , , and (see Figure 2(e)). Obviously, for . Hence there exists a periodic wave solution with and . Then, we will study the limiting behavior of the periodic wave solution. As , has a double zero at and three simple zeros, and for (see Figure 2(f)). Hence we deduce that, as , the periodic wave solution converges to a solitary wave solution pointing downward with , , and as . Moreover, if , we can get and for (see Figure 2(e)). It looks like there exists another periodic wave solution, but we cannot ignore the fact that . When near , according to Lemma 12, we have ~ and ~. Hence as and the loop is formed. So there exists a looped periodic wave solution with and . Similarly, as (see Figure 2(f)), the looped periodic wave solution converges to a looped wave solution with , , and as . (4) If , has three simple zeros, denoted by , , and , and for . Hence there exists a periodic looped wave solution of solution of (3) with and . As , has a simple zero besides (see Figure 2(h)). Hence the periodic looped wave solution converges to a looped wave solution , , and as . (5) If , we can conclude that has only a simple zero, denoted by , and for (see Figure 2(i)). When reaches the pole point , it will make a sudden turn at this point and yield a cusp at ; that is, . So there exists a cusped periodic wave solution of with and .
(a)
(b)
(c)
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(e)
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(h)
(i)
Case B (). (1) If (see Figures 3(a) and 3(b)), similarly to the analysis in Case A, we obtain that there are no bounded traveling solitary wave solutions of (3). (2) If (see Figures 3(c) and 3(d)), there exists a periodic wave solution of (3) with and . (3) If , we can deduce that has five distinct simple zeros denoted by , , , , and (see Figure 3(e)). Obviously, for . Hence there exists a periodic wave solution. Moreover, as , the periodic wave solution converges to a solitary wave solution pointing downward. Similarly, if , we can get and for (see Figure 3(e)). So there exists a periodic looped wave of (3). Moreover, as (see Figure 3(e)), it looks like that the periodic looped wave solution converges to a looped solitary wave solution. However it is not true due to the fact that both and converge to zero as besides . According to Lemma 12, there exists a butterfly-like wave solution of (6) with and . (4) If , it is easy to observe that has only one simple zero and ; hence there exists a cusped periodic wave solution.
(a)
(b)
(c)
(d)
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Case C (). In this case, the geometric analysis of is shown in Figure 4. The result given in Theorem 5 can be proved in a way similar to that in Case B.
(a)
(b)
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Case D (). In this case, the geometric analysis of is shown in Figure 5. The result given in Theorem 6 can be proved in a way similar to that in Case B.
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Case E (). In this case, the geometric analysis of is shown in Figure 6. The result given in Theorem 7 can be proved in a way similar to that in Case B.
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Case F (). In this case, the geometric analysis of is shown in Figure 7. The result given in Theorem 8 can be proved in a way similar to that in Case B.
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Case G (). In this case, the geometric analysis of is shown in Figure 8. The result given in Theorem 9 can be proved in a way similar to that in Case B.
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Case H (). In this case, the geometric analysis of is shown in Figure 9. The result given in Theorem 3 can be proved in a way similar to that in Case B.
(a)
(b)
(c)
(d)
(e)
Then, we will study the existence of composite waves. By Theorems 3–10, any countable number of travelling waves in the above cases corresponding to the same value of can be joined at points where to form composite waves. If , then the composite wave is a solution of (2). For , the composite waves are solutions of (2) even if . Consequently, we can obtain double stumpons which contain intervals where (see Figure 1(l)). Since any countable number of wave segments can be joined together, one can get travelling waves with very strange profiles, such as the travelling waves with a fractal appearance where (see Figure 1(k)). Then the proof of Theorem 11 is completed.
5. Conclusions
By an improved method combining some characteristics of several methods, we have obtained abundant traveling waves in the mDP equation. Those solutions include looped wave solutions, cusped wave solutions, peaked wave solutions, fractal-like waves, double stumpons, double kinked waves, and butterfly-like waves. Under different parametric conditions, various sufficient conditions to guarantee the existence of the above solutions are given. Our method can also be applied to other models where the location of extreme value points is determined. The limiting behavior of traveling wave solutions can also be given. Based on the study, it might be concluded that the improved method is useful and efficient. It can be widely applied to other nonlinear wave equations. Our study may be useful to further understand the role that the nonlinearly dispersive terms pay on the optical wave solutions.
Conflict of Interests
The authors declare that they have no conflict of interests regarding the publication of this paper.
Acknowledgments
This work is supported by the National Nature Science Foundation of China (no. 11101191) and it is also sponsored by the Qing Lan Project.
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