Abstract
Here, we give the existence of analytical Cartesian solutions of the multi-component Camassa-Holm (MCCH) equations. Such solutions can be explicitly expressed, in which the velocity function is given by u = b (t) + A(t)x and no extra constraint on the dimension N is required. The advantage of our method is that we turn the process of analytically solving MCCH equations into algebraically constructing the suitable matrix A(t). As the applications, we obtain some interesting results: 1) If u is a linear transformation on x ∈ ℝN , then p takes a quadratic form of x. 2) If A = f(t)I + D with DT = −D, we obtain the spiral solutions. When N = 2, the solution can be used to describe “breather-type” oscillating motions of upper free surfaces. 3) If \(A = ({\textstyle{{{{\mathop \alpha \limits^. }_i}} \over {{\alpha _i}}}})N \times N,\), we obtain the generalized elliptically symmetric solutions. When N = 2, the solution can be used to describe the drifting phenomena of the shallow water flow.
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An, H., Hou, L. & Yuen, M. Analytical Cartesian solutions of the multi-component Camassa-Holm equations. J Nonlinear Math Phys 26, 255–272 (2019). https://doi.org/10.1080/14029251.2019.1591725
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DOI: https://doi.org/10.1080/14029251.2019.1591725
Keywords
- Solution
- Analytical Cartesian solution
- Camassa-Holm equation
- Curve integration theory
- Multicomponent Camassa-Holm equations