Regularity theory

Template:Short description Regularity is a topic of the mathematical study of partial differential equations (PDE) such as Laplace's equation, about the integrability and differentiability of weak solutions. Hilbert's nineteenth problem was concerned with this concept.^[1]

The motivation for this study is as follows.^[2] It is often difficult to construct a classical solution satisfying the PDE in regular sense, so we search for a weak solution at first, and then find out whether the weak solution is smooth enough to be qualified as a classical solution.

Several theorems have been proposed for different types of PDEs.

Template:Main Let ${\displaystyle U}$ be an open, bounded subset of ${\displaystyle {ℝ}^n}$, denote its boundary as ${\displaystyle \partial U}$ and the variables as ${\displaystyle x=(x_1,...,x_n)}$. Representing the PDE as a partial differential operator ${\displaystyle L}$ acting on an unknown function ${\displaystyle u=u(x)}$ of ${\displaystyle x\in U}$ results in a BVP of the form $${\displaystyle \{\begin{array}{cccc}Lu& =f& & \text{in }U\\ u& =0& & \text{on }\partial U,\end{array}}$$ where ${\displaystyle f:U\to ℝ}$ is a given function ${\displaystyle f=f(x)}$ and ${\displaystyle u:U\cup \partial U\to ℝ}$ and the elliptic operator ${\displaystyle L}$ is of the divergence form: $${\displaystyle Lu(x)=-{\displaystyle \sum _{i,j=1}^n}(a_{ij}(x)u_{x_i}{)}_{x_j}+{\displaystyle \sum _{i=1}^n}{b}_i(x)u_{x_i}(x)+c(x)u(x),}$$then

• Interior regularity: If m is a natural number, ${\displaystyle a^{ij},b^j,c\in C^{m+1}(U),f\in H^m(U)}$ (2) , ${\displaystyle u\in H_0^1(U)}$ is a weak solution, then for any open set V in U with compact closure, ${\displaystyle \Vert u{\Vert }_{H^{m+2}(V)}\le C(\Vert f{\Vert }_{H^m(U)}+\Vert u{\Vert }_{L^2(U)})}$(3), where C depends on U, V, L, m, per se ${\displaystyle u\in H_{loc}^{m+2}(U)}$, which also holds if m is infinity by Sobolev embedding theorem.
• Boundary regularity: (2) together with the assumption that ${\displaystyle \partial U}$ is ${\displaystyle C^{m+2}}$ indicates that (3) still holds after replacing V with U, i.e. ${\displaystyle u\in H^{m+2}(U)}$, which also holds if m is infinity.

Parabolic and hyperbolic PDEs describe the time evolution of a quantity u governed by an elliptic operator L and an external force f over a space ${\displaystyle U\subset {ℝ}^n}$. We assume the boundary of U to be smooth, and the elliptic operator to be independent of time, with smooth coefficients, i.e.$${\displaystyle Lu(t,x)=-{\displaystyle \sum _{i,j=1}^n}(a_{ij}(x)u_{x_i}(t,x){)}_{x_j}+{\displaystyle \sum _{i=1}^n}{b}_i(x)u_{x_i}(t,x)+c(x)u(t,x).}$$In addition, we subscribe the boundary value of u to be 0.

Then the regularity of the solution is given by the following table,

where m is a natural number, ${\displaystyle x\in U}$ denotes the space variable, t denotes the time variable, H^s is a Sobolev space of functions with square-integrable weak derivatives, and L_t^pX is the Bochner space of integrable X-valued functions.

Not every weak solution is smooth; for example, there may be discontinuities in the weak solutions of conservation laws called shock waves.^[3]

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