Korteweg-de Vries equation on R: Difference between revisions
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The local and global well-posedness theory for the [[Korteweg-de Vries equation]] on the real line is as follows. | The local and global [[well-posedness]] theory for the [[Korteweg-de Vries equation]] on the real line is as follows. | ||
* Scaling is <span class="SpellE">s_c</span> = -3/2. | * Scaling is <span class="SpellE">s_c</span> = -3/2. | ||
* LWP in <span class="SpellE">H^s</span> for s >= -3/4 [ | * LWP in <span class="SpellE">H^s</span> for s >= -3/4 [[CtCoTa-p]], using a modified [[Miura transform]] and the [[mKdV on R|mKdV theory]]. This is despite the failure of the key bilinear estimate [[NaTkTs2001]] | ||
** For s within a logarithm for s=-3/4 [ | ** For s within a logarithm for s=-3/4 [[MurTao-p]]. | ||
** Was proven for s > -3/4 [[ | ** Was proven for s > -3/4 [[KnPoVe1996]]. | ||
** Was proven for s > -5/8 in [[ | ** Was proven for s > -5/8 in [[KnPoVe1993b]]. | ||
** Was proven for s >= 0 in [[ | ** Was proven for s >= 0 in [[Bo1993b]]. | ||
** Was proven for s > 3/4 in [[ | ** Was proven for s > 3/4 in [[KnPoVe1993]]. | ||
** Was proven for s > 3/2 in [[ | ** Was proven for s > 3/2 in [[BnSmr1975]], [[Ka1975]], [[Ka1979]], [[GiTs1989]], [[Bub1980]], .... | ||
** One has local ill- | ** One has local [[ill-posedness]] (in the sense that the map is not uniformly continuous) for s < -3/4 (in the complex setting) by [[soliton]] examples [[KnPoVe2001]]. | ||
*** For real <span class="SpellE">KdV</span> this has also been established in [ | *** For real <span class="SpellE">KdV</span> this has also been established in [[CtCoTa-p]], by the [[Miura transform]] and the [[mKdV on R| corresponding result for mKdV]]. | ||
*** Below -3/4 the solution map was known to not be C^3 [[ | *** Below -3/4 the solution map was known to not be C^3 [[Bo1993b]], [[Bo1997]]; this was refined to C^2 in [[Tz1999b]]. | ||
** When the initial data is a real, rapidly decreasing measure one has a global smooth solution for t > 0 [[ | ** When the initial data is a real, rapidly decreasing measure one has a global smooth solution for t > 0 [[Kp1993]]. Without the rapidly decreasing hypothesis one can still construct a global weak solution [[Ts1989]] | ||
* GWP in <span class="SpellE">H^s</span> for s > -3/4 (if u is real) [[ | * GWP in <span class="SpellE">H^s</span> for s > -3/4 (if u is real) [[CoKeStTkTa2003]]. | ||
** Was proven for s > -3/10 in [[ | ** Was proven for s > -3/10 in [[CoKeStTkTa2001]] | ||
** Was proven for s>= 0 in [[ | ** Was proven for s>= 0 in [[Bo1993b]]. Global weak solutions in L^2 were constructed in [[Ka1983]], [[KrFa1983]], and were shown to obey the expected local smoothing estimate. These weak solutions were shown to be unique in [[Zh1997b]] | ||
** Was proven for s>= 1 in [[ | ** Was proven for s>= 1 in [[KnPoVe1993]]. | ||
** Was proven for s>= 2 in [[ | ** Was proven for s>= 2 in [[BnSmr1975]], [[Ka1975]], [[Ka1979]], .... | ||
** ''Remark'' | ** ''Remark'': In the complex setting GWP fails for large data with Fourier support on the half-line [Bona-Winther?], [Birnir?], ????. This result extends to a wide class of [[dispersive]] PDE. | ||
* By use of the inverse scattering transform one can show that smooth solutions eventually resolve into | * By use of the inverse scattering transform one can show that smooth solutions eventually resolve into [[solitons]], that two colliding <span class="SpellE">solitons</span> emerge as (slightly phase shifted) <span class="SpellE">solitons</span>, etc. | ||
* <span class="SpellE">Solitons</span> are <span class="SpellE">orbitally</span> H^1 stable [[ | * <span class="SpellE">Solitons</span> are <span class="SpellE">orbitally</span> H^1 stable [[Bj1972]] | ||
** In <span class="SpellE">H^s</span>, 0 <= s < 1, the orbital stability of | ** In <span class="SpellE">H^s</span>, 0 <= s < 1, the [[orbital stability]] of solitons is at most polynomial (the distance to the ground state manifold in <span class="SpellE">H^s</span> norm grows like at most O(t^{1-s+}) in time) [[RaySt-p]] | ||
** In L^2, orbital stability | ** In L^2, orbital and asymptotic stability have been obtained in [[MeVe2003]]. | ||
==KdV-like systems== | |||
The <span class="SpellE">KdV</span> equation can also be generalized to a 2x2 system | The <span class="SpellE">KdV</span> equation can also be generalized to a 2x2 system | ||
<center><math>\partial_t u + \partial_x^3 u + a_3 \partial_x^3 v + u \partial_x u + a_1 v \partial_x v + a_2 \partial_x (uv)= 0<br | <center><math>\partial_t u + \partial_x^3 u + a_3 \partial_x^3 v + u \partial_x u + a_1 v \partial_x v + a_2 \partial_x (uv)= 0</math><br ><math>b_1 \partial_t v + \partial_x^3 v + b_2 a_3 \partial_x^3 u + v \partial_x v + b_2 a_2 u \partial_x u + b_2 a_1 \partial_x (uv) + r \partial_x v</math></center> | ||
<span class="GramE">where</span> b_1,b_2 are positive constants and a_1,a_2,a_3,r are real constants. This system was introduced in [[ | <span class="GramE">where</span> b_1,b_2 are positive constants and a_1,a_2,a_3,r are real constants. This system was introduced in [[GeaGw1984]] to study strongly interacting pairs of weakly nonlinear long waves, and studied further in [[BnPoSauTm1992]]. In [[AsCoeWgg1996]] it was shown that this system was also globally well-posed on L^2. <br /> It is an interesting question as to whether these results can be pushed further to match the <span class="SpellE">KdV</span> theory; the apparent lack of [[complete integrability]] in this system (for generic choices of parameters <span class="SpellE">b_i</span>, <span class="SpellE">a_i</span>, <span class="GramE">r</span>) suggests a possible difficulty. | ||
[[Category:Integrability]] | |||
[[Category:Equations]] | [[Category:Equations]] | ||
[[Category:Airy]] |
Latest revision as of 21:51, 11 September 2007
The local and global well-posedness theory for the Korteweg-de Vries equation on the real line is as follows.
- Scaling is s_c = -3/2.
- LWP in H^s for s >= -3/4 CtCoTa-p, using a modified Miura transform and the mKdV theory. This is despite the failure of the key bilinear estimate NaTkTs2001
- For s within a logarithm for s=-3/4 MurTao-p.
- Was proven for s > -3/4 KnPoVe1996.
- Was proven for s > -5/8 in KnPoVe1993b.
- Was proven for s >= 0 in Bo1993b.
- Was proven for s > 3/4 in KnPoVe1993.
- Was proven for s > 3/2 in BnSmr1975, Ka1975, Ka1979, GiTs1989, Bub1980, ....
- One has local ill-posedness (in the sense that the map is not uniformly continuous) for s < -3/4 (in the complex setting) by soliton examples KnPoVe2001.
- For real KdV this has also been established in CtCoTa-p, by the Miura transform and the corresponding result for mKdV.
- Below -3/4 the solution map was known to not be C^3 Bo1993b, Bo1997; this was refined to C^2 in Tz1999b.
- When the initial data is a real, rapidly decreasing measure one has a global smooth solution for t > 0 Kp1993. Without the rapidly decreasing hypothesis one can still construct a global weak solution Ts1989
- GWP in H^s for s > -3/4 (if u is real) CoKeStTkTa2003.
- Was proven for s > -3/10 in CoKeStTkTa2001
- Was proven for s>= 0 in Bo1993b. Global weak solutions in L^2 were constructed in Ka1983, KrFa1983, and were shown to obey the expected local smoothing estimate. These weak solutions were shown to be unique in Zh1997b
- Was proven for s>= 1 in KnPoVe1993.
- Was proven for s>= 2 in BnSmr1975, Ka1975, Ka1979, ....
- Remark: In the complex setting GWP fails for large data with Fourier support on the half-line [Bona-Winther?], [Birnir?], ????. This result extends to a wide class of dispersive PDE.
- By use of the inverse scattering transform one can show that smooth solutions eventually resolve into solitons, that two colliding solitons emerge as (slightly phase shifted) solitons, etc.
- Solitons are orbitally H^1 stable Bj1972
- In H^s, 0 <= s < 1, the orbital stability of solitons is at most polynomial (the distance to the ground state manifold in H^s norm grows like at most O(t^{1-s+}) in time) RaySt-p
- In L^2, orbital and asymptotic stability have been obtained in MeVe2003.
KdV-like systems
The KdV equation can also be generalized to a 2x2 system
where b_1,b_2 are positive constants and a_1,a_2,a_3,r are real constants. This system was introduced in GeaGw1984 to study strongly interacting pairs of weakly nonlinear long waves, and studied further in BnPoSauTm1992. In AsCoeWgg1996 it was shown that this system was also globally well-posed on L^2.
It is an interesting question as to whether these results can be pushed further to match the KdV theory; the apparent lack of complete integrability in this system (for generic choices of parameters b_i, a_i, r) suggests a possible difficulty.