Modified Korteweg-de Vries equation: Difference between revisions
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<center><math>\partial_t v + \partial_x^3 v = 6(a^2 v^2 + bv) \partial_x v</math></center> | <center><math>\partial_t v + \partial_x^3 v = 6(a^2 v^2 + bv) \partial_x v</math></center> | ||
<span class="GramE">then</span> u = a^2 v^2 + | <span class="GramE">then</span> <math>u = a^2 v^2 + a \partial_x v + bv</math> solves <span class="SpellE">KdV</span> (this is the ''Gardener transform''). | ||
[[Category:Equations]] | [[Category:Equations]] |
Revision as of 19:33, 28 July 2006
The (defocusing) modified Korteweg-de Vries (mKdV) equation is
It is completely integrable, and has infinitely many conserved quantities. Indeed, for each non-negative integer k, there is a conserved quantity which is roughly equivalent to the H^k norm of u. This equation has been studied on the line, on the circle, and on the half-line.
The focussing mKdV
is very similar, but admits soliton solutions.
Miura transform
In the defocusing case, the Miura transformation transforms a solution of defocussing mKdV to a solution of [#kdv KdV]
Thus one expects the LWP and GWP theory for mKdV to be one derivative higher than that for KdV.
In the focusing case, the Miura transform is now . This transforms focussing mKdV to complex-valued KdV, which is a slightly less tractable equation. (However, the transformed solution v is still real in the highest order term, so in principle the real-valued theory carries over to this case).
The Miura transformation can be generalized. If v and w solve the system
Then is a solution of KdV. In particular, if a and b are constants and v solves
then solves KdV (this is the Gardener transform).