Symmetry Reductions and Exact Solutions of Shallow Water Wave Equations

Abstract

In this paper we study symmetry reductions and exact solutions of the shallow water wave (SWW) equation uxxxt + α ux uxt + β ut uxx - uxt - uxx = 0,(1) where α and β are arbitrary, nonzero, constants, which is derivable using the so-called Boussinesq approximation. Two special cases of this equation, or the equivalent nonlocal equation obtained by setting ux=U, have been discussed in the literature. The case α=2β was discussed by Ablowitz, Kaup, Newell and Segur [ Stud.\ Appl.\ Math., 53 (1974) 249], who showed that this case was solvable by inverse scattering through a second order linear problem. This case and the case α=β were studied by Hirota and Satsuma [ J.\ Phys.\ Soc.\ Japan, 40 (1976) 611] using Hirota's bi-linear technique. Further the case α=β is solvable by inverse scattering through a third order linear problem. In this paper a catalogue of symmetry reductions is obtained using the classical Lie method and the nonclassical method due to Bluman and Cole [ J.\ Math.\ Mech.\/, 18 (1969) 1025]. The classical Lie method yields symmetry reductions of (1) expressible in terms of the first, third and fifth \ transcendents and Weierstrass elliptic functions. The nonclassical method yields a plethora of exact solutions of (1) with α=β which possess a rich variety of qualitative behaviours. These solutions all like a two-soliton solution for t<0 but differ radically for t>0 and may be viewed as a nonlinear superposition of two solitons, one travelling to the left with arbitrary speed and the other to the right with equal and opposite speed.

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