Davey-Stewartson system: Difference between revisions

Revision as of 03:52, 28 July 2006

The Davey-Stewartson system [DavSte1974] in 2 spatial dimensions involves a complex field u and a real field phi:

$i\partial _{t}u+c_{0}\partial _{x}^{2}u+\partial _{y}^{2}u=c_{1}|u|^{2}u+c_{2}u\partial _{x}phi\partial _{x}^{2}phi+c_{3}\partial _{y}^{2}phi=partial_{x}(|u|^{2})Thefieldphidependsellipticallyonuwhen<math>c_{3}$ is positive and thus one usually only specifies the initial data for $u$ , not $\phi$ . This equation is a modification of the cubic nonlinear Schrodinger equation and is completely integrable in the cases $(c_{0},c_{1},c_{2},c_{3})=(-1,1,-2,1)$ (DS-I) and $(1,-1,2,-1)$ (DS-II). When $c_{3}>0$ the situation becomes a nonlinear Schrodinger equation with non-local nonlinearity, and can be treated by Strichartz estimates [GhSau1990]; for $c_{3}<0$ the situation is quite different but one can still use derivative NLS techniques (i.e. gauge transforms and energy methods) to obtain some local existence results [LiPo1993]. Further results are in [HaSau1995].

The Davey-Stewartson system is a special case of the Zakharov-Schulman system.

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 The '''Davey-Stewartson system''' [DavSte1974] in 2 spatial dimensions involves a complex field u and a real field phi:
-i u_t + c_0 u_xx + u_yy = c_1 |u|^2 u + c_2 u phi_x
+<math>i \partial_t u + c_0 \partial_x^2 u + \partial_y^2 u = c_1 |u|^2 u + c_2 u \partial_x phi
-phi_xx + c_3 phi_yy = partial_x ( |u|^2 )
+\partial_x^2 phi + c_3 \partial_y^2 phi = partial_x ( |u|^2 )
-The field phi depends elliptically on u when c_3 is positive and thus one usually only specifies the initial data for u, not phi.  This equation is a modification of the cubic nonlinear Schrodinger equation and is completely integrable in the cases (c_0, c_1, c_2, c_3) = (-1,1,-2,1) (DS-I) and (1,-1,2,-1) (DS-II).   When c_3 > 0 the situation becomes a nonlinear Schrodinger equation with non-local nonlinearity, and can be treated by Strichartz estimates [GhSau1990]; for c_3 < 0 the situation is quite different but one can still use derivative NLS techniques (i.e. gauge transforms and energy methods) to obtain some local existence results [LiPo1993].  Further results are in [HaSau1995].
+The field phi depends elliptically on u when <math>c_3</math> is positive and thus one usually only specifies the initial data for <math>u</math>, not <math>\phi</math>.  This equation is a modification of the cubic nonlinear Schrodinger equation and is completely integrable in the cases <math>(c_0, c_1, c_2, c_3) = (-1,1,-2,1)</math> (DS-I) and <math>(1,-1,2,-1)</math> (DS-II).   When <math>c_3 > 0</math> the situation becomes a nonlinear Schrodinger equation with non-local nonlinearity, and can be treated by Strichartz estimates [GhSau1990]; for <math>c_3 < 0</math> the situation is quite different but one can still use derivative NLS techniques (i.e. gauge transforms and energy methods) to obtain some local existence results [LiPo1993].  Further results are in [HaSau1995].
 The Davey-Stewartson system is a special case of the [[Zakharov-Schulman system]].
 [[Category:Equations]]

Davey-Stewartson system: Difference between revisions

Revision as of 03:52, 28 July 2006

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