KdV hierarchy: Difference between revisions

The Korteweg-de Vries equation

${\displaystyle \partial _{t}V+\partial _{x}^{3}V=6\partial _{x}V}$

can be rewritten in the Lax Pair form

${\displaystyle \partial _{t}L=[L,P]}$

where ${\displaystyle L}$ is the second-order operator

${\displaystyle L=-D^{2}+V}$

${\displaystyle (D=d/dx)}$ and ${\displaystyle P}$ is the third-order antiselfadjoint operator

${\displaystyle P=4D^{3}+3(DV+VD)}$.

Notethat ${\displaystyle P}$ consists of the zeroth order and higher terms of the formal power series expansion of ${\displaystyle 4iL^{3/2}}$).

One can replace ${\displaystyle P}$ with other fractional powers of L. For instance, the zeroth order and higher terms of ${\displaystyle 4iL^{5/2}}$ are

and the Lax pair equation becomes

${\displaystyle \partial _{t}V+\partial _{x}^{5}u=\partial _{x}(5V_{x}^{2}+10VV_{x}x+10V^{3})withHamiltonian<center><math>H(V)=\int V_{x}x^{2}-5V^{2}V_{x}x-5V^{4}dx.}$

These flows all commute with each other and their Hamiltonians are conserved by all the flows simultaneously.

The KdV hierarchy are examples of higher order water wave models; a general formulation is

${\displaystyle \partial _{t}u+\partial _{x}^{2j+1}u=P(u,u_{x},...,\partial _{x}</span>^{2j}u)<math></center>where<math>u}$ is real-valued and ${\displaystyle P}$ is a polynomial with no constant or linear terms; thus KdV and gKdV correspond to j=1, and the higher order equations in the hierarchy correspond to j=2,3,etc. LWP for these equations in high regularity Sobolev spaces is in KnPoVe1994, and independently by Cai (ref?); see also CrKpSr1992.The case j=2 was studied by Choi (ref?).The non-scalar diagonal case was treated in KnSt1997; the periodic case was studied in [Bo-p3].Note in the periodic case it is possible to have ill-posedness for every regularity, for instance ${\displaystyle \partial _{t}u+u_{x}xx=u^{2}u_{x}^{2}isill-posedinevery<math>H^{s}}$ [Bo-p3]