# Well-posedness and Critical Index Set of the Cauchy Problem for the   Coupled KdV-KdV Systems on $\mathbb{T}$

**Authors:** Xin Yang, Bing-Yu Zhang

arXiv: 1907.05580 · 2023-02-16

## TL;DR

This paper investigates the well-posedness of coupled KdV-KdV systems on the torus, identifying critical index sets for different function spaces using number theory, revealing differences from the real line case.

## Contribution

It determines the critical index sets for the well-posedness of coupled KdV systems on the torus, linking them to Diophantine approximation and contrasting with the real line case.

## Key findings

- Critical index sets are explicitly characterized for various spaces.
- Number theory techniques are used to identify these sets.
- Differences from the real line case are highlighted.

## Abstract

Studied in this paper is the well-posedness of the Cauchy problem for the coupled KdV-KdV systems \[ u_t+a_1u_{xxx} = c_{11}uu_x+c_{12}vv_x+d_{11}u_{x}v+d_{12}uv_{x}, \quad u(x,0)= u_0(x) \] \[ v_t+a_2v_{xxx}= c_{21}uu_x+c_{22}vv_x +d_{21}u_{x}v+d_{22}uv_{x}, \quad v(x,0)=v_0(x)\] posed on the torus $\mathbb{T}$ in the spaces \[ {\cal H}^s_1:=H^s_0 (\mathbb{T})\times H^s_0 (\mathbb{T}), \quad {\cal H}^s_2:=H^s_0 (\mathbb{T})\times H^s(\mathbb{T}), \quad {\cal H}^s_3:=H^s (\mathbb{T})\times H^s_0 (\mathbb{T}), \quad {\cal H}^s_4:=H^s (\mathbb{T})\times H^s (\mathbb{T}).\] For $k=1,2,3,4$, it is shown that for given $a_1$, $a_2$, $(c_{ij})$ and $(d_{ij})$, there exists a unique $s^*_k \in (-\infty, +\infty]$, called the critical index, such that the system is analytically well-posed in $\cal{H}^s_k$ for $s>s^*_k$ while the bilinear estimate, the key for the proof of the analytical well-posedness, fails if $s<s^{*}_k$. Viewing the critical index $s^*_k$ as a function of the coefficients $a_1$, $a_2$, $(c_{ij})$ and $(d_{ij})$, its range $\cal{C}_k$ is called the critical index set for the analytical well-posedness of the system in the space $\cal{H}^s_k$. Invoking some classical results of Diophantine approximation in number theory, we are able to identify that \[ \mbox{$ {\cal C}_1= \left \{ -\frac12, \infty \right\} \bigcup \left \{ \alpha: \frac12\leq \alpha\leq 1 \right \}$ } \quad\text{and}\quad \mbox{${\cal C}_q= \left \{ -\frac12, -\frac14, \infty \right\} \bigcup \left \{ \alpha: \frac12\leq \alpha\leq 1 \right \}$ $\quad$ for $\quad$ $q=2,3,4$.}\] This is in sharp contrast to the $R$ case in which the critical index set ${\cal C}$ for the analytical well-posedness of in the space $H^s (R)\times H^s (R)$ consists of exactly four numbers: $ {\cal C}=\left \{ -\frac{13}{12}, -\frac34, 0, \frac34 \right \}.$

## Full text

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## References

49 references — full list in the complete paper: https://tomesphere.com/paper/1907.05580/full.md

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Source: https://tomesphere.com/paper/1907.05580