This article is concerned with a conjecture in [B. Dubrovin, Comm. Math. Phys., 267 (2006), pp. 117-139] on the formation of dispersive shocks in a class of Hamiltonian dispersive regularizations of the quasi-linear transport equation. The regularizations are characterized by two arbitrary functions of one variable, where the condition of integrability implies that one of these functions must not vanish. It is shown numerically for a large class of equations that the local behavior of their solution near the point of gradient catastrophe for the transport equation is described by a special solution of a Painleve-type equation. This local description holds also for solutions to equations where blowup can occur in finite time. Furthermore, it is shown that a solution of the dispersive equations away from the point of gradient catastrophe is approximated by a solution of the transport equation with the same initial data, modulo terms of order epsilon^(2), where epsilon^(2) is the small dispersion parameter. Corrections up to order epsilon^(4) are obtained and tested numerically.
Numerical study of breakup in generalized Korteweg - de Vries and Kawahara equations / Dubrovin, Boris; Grava, Tamara; Klein, C.. - In: SIAM JOURNAL ON APPLIED MATHEMATICS. - ISSN 0036-1399. - 71:4(2011), pp. 983-1008. [10.1137/100819783]
Numerical study of breakup in generalized Korteweg - de Vries and Kawahara equations
Dubrovin, Boris;Grava, Tamara;
2011-01-01
Abstract
This article is concerned with a conjecture in [B. Dubrovin, Comm. Math. Phys., 267 (2006), pp. 117-139] on the formation of dispersive shocks in a class of Hamiltonian dispersive regularizations of the quasi-linear transport equation. The regularizations are characterized by two arbitrary functions of one variable, where the condition of integrability implies that one of these functions must not vanish. It is shown numerically for a large class of equations that the local behavior of their solution near the point of gradient catastrophe for the transport equation is described by a special solution of a Painleve-type equation. This local description holds also for solutions to equations where blowup can occur in finite time. Furthermore, it is shown that a solution of the dispersive equations away from the point of gradient catastrophe is approximated by a solution of the transport equation with the same initial data, modulo terms of order epsilon^(2), where epsilon^(2) is the small dispersion parameter. Corrections up to order epsilon^(4) are obtained and tested numerically.| File | Dimensione | Formato | |
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