Questions tagged [sobolev-spaces]

For questions about or related to Sobolev spaces, which are function spaces equipped with a norm that controls both a function and its weak derivatives in some Lebesgue space.

Sobolev spaces are function spaces generalizing the Lebesgue spaces. Whereas elements of Lebesgue spaces have certain integrability condition imposed on them, derivatives of functions in a Sobolev space are also required to be sufficiently integrable: that is, we require all (weak) partial derivatives of the function up to a certain order belong to a certain fixed Lebesgue space.

In more detail, let $U \subseteq \mathbb{R}^n$ be an open set. A weak $\alpha$th partial derivative $D^\alpha f$ of $f$ is a function $g\in L^1_{\mathrm{loc}}(U)$ such that $$\int_U f D^\alpha \phi \, dx = (-1)^{|\alpha|} \int g\phi \, dx$$ for each compactly supported smooth function $\phi \in C^\infty_c(U)$. the Sobolev space $W^{k, p}(U)$ consists of those functions $f\in L^p(U)$ such that for every multi-index $\alpha$ of length at most $k$, every weak partial derivative $D^{\alpha}f$ exists and is an element of $L^p$. The Sobolev spaces are equipped with norms defined by

$$\|u\|_{W^{k,p}(U)} = \begin{cases} \left( \sum_{|\alpha| \le k} \|D^{\alpha} u\|_{L^p(U)}^p \right)^{1/p} & p < \infty, \\ \max_{|\alpha| \le k} \|D^{\alpha}\|_{L^{\infty}(U)} &p=\infty .\end{cases}$$

$(W^{k,p}(U),\|\cdot\|_{W^{k,p}(U)})$ are Banach spaces for each $k\in\mathbb N$, and each $p\in[1,\infty]$. The norms measure both the size and the regularity of a function.

The basic fundamental result of Sobolev spaces is the Sobolev embedding theorem. In words, it says that (1) if $kp<n$, having $k$ weak derivatives in $L^p$ places your function in a better Lebesgue space $L^{p^*}$, where $\frac1{p^*} = \frac1p - \frac kn$, and (2) if $kp>n$, then your function is not only in $L^\infty$ but also has a continuous representative in some space of Hölder continuous functions. In particular, sufficiently many weak derivatives means that your function is in fact classically differentiable.

Reference: Sobolev space.

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Existence of the Sobolev-solution of the equation $- \Delta u + {u^3} = 1$

I have the following problem from my Calculus of Variation class. Problem. Let $\Omega $ be an open, bounded subset of $\mathbb{R}^3$. Prove or disprove that there exists $u \in W_0^{1,2}\left( \Omega \right)$ such that $- \Delta u + {u^3} = 1$ in…
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Elliptic Regularity in Sobolev Spaces with Negative Order $(s<0)$

I am looking for an elliptic regularity theorem in the Sobolev Space $H^s(\mathbb R^3)$ for $s<0$. In fact we have the equation $$A\,u=f,$$ where $A$ is an elliptic operator and $f\in H^s(\mathbb R^3)$ with $s<0$. Can we deduce that $u\in…
H. J
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For which $ 0 \leq p \leq \infty$ does it hold that $f \in W^{1, p}(U)$?

I recently started the study of Sobolev spaces for my PDE class. In short, I still have quite some difficulties to handle the associated concepts as well as notation. In order to clear things up, I will go along and pose several related questions to…
Taufi
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Why is there a sequence $u_n\in X\cap \mathcal C^2[-1,1]$ s.t. $u_n\to u$ in $W^{1,2}(-1,1)$?

Let $$X=\{u\in W^{1,2}(-1,1)\mid u(-1)=u(1), \int_{-1}^1 u=0\}.$$ I proved Wirtinger inequality i.e. $$\int_{-1}^1 (u')^2\geq \pi^2\int_{-1}^1 u^2$$ for all $u\in X\cap \mathcal C^2([-1,1])$. But I want to prove it when $u\in X$ (and not $X\cap…
user330587
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Problem to understand Sobolev imbedding.

There are Sobolev/Rellich-Kondrachov theorem imbedding : Let $\Omega\subset \mathbb R^n $ open bounded with Lipschitz boundary. 1) If $1\leq p
user330587
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Why $\mathcal C^\infty (\Omega )\cap W^{k,p}(\Omega )$ dense in $W^{k,p}(\Omega )$ instead of $\mathcal C^\infty (\Omega )$.

Let $\Omega \subset \mathbb R^n$ open. In my course, I have a theorem that says that $\mathcal C^\infty (\Omega )\cap W^{k,p}(\Omega )$ is dense in $W^{k,p}(\Omega )$. But don't we have that $\mathcal C^\infty (\Omega )\subset W^{k,p}(\Omega )$ ?…
user330587
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Interpolation of derivatives in Sobolev spaces

I am looking to establish a result of the following form, or to find counterexample where this fails. If $1 \leq p < \infty$ and $u \in L^p(\mathbb R^d)$ has weak derivatives up to second order with $D^2u \in L^p(\mathbb R^d),$ then $u \in…
ktoi
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Sobolev embeddings: counter example

let $\Omega =\{(x,y)\in \mathbb{R}^2 : 0 < x < 1, 0 < y < x^2\}$ be a bounded and open domain and it is not $C^1$. And consider the function $u(x,y)=x^a.$ Use the function $u$ to prove that $H^1(\Omega)$ dose not inject in $L^p(\Omega)$ for $p >…
Math1995
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Finding $u_0 \in H_0^1(0,1)$ given $u'_0$

For $\varepsilon > 0$ consider the function $$u'_0 := \frac{3\varepsilon}{8\pi}\cos(2\pi x \varepsilon^{-1}) \qquad x \in (0,1)$$ Now I want to find $u_0 \in H_0^1(0,1)$. So I have to integrate the above function and by definition of $H_0^1(0,1)$,…
TheGeekGreek
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Can we obtain the following variation of Poincaré inequality?

The known Poincaré inequality says that in the conditions of the theorem we have \begin{equation} \|u - u_{\Omega}\|_{L^{p}(\Omega)} \le C \| \nabla u \|_{L^{p}(\Omega)}. \end{equation} see for instance [1] Can we obatain also \begin{equation} \|u -…
user29999
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Dualty is Sobolev spaces

I have a question about duality in Sobolev spaces .Let $\Omega $ be an open of $R$,Suppose that u$\in H_{0}^{2}(\Omega )\cap H^{3}(\Omega )$ and $v\in H_{0}^{2}(\Omega ).$ Is that this expression make a sens ? $\int\limits_\Omega {\partial…
Gustave
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Does the norm of fractional Sobolev spaces can be expressed in a series manner?

Consider function $f$ contained in periodic Sobolev space $H^k$, then it has Sobolev norm $\|f\|_{H^k}^2 = \sum_i (1+i^k)^2 f_i^2$, where $\{f_i\}_i$ are Fourier coefficients. I am wondering if $f\in H^s$ with $ 0
newbie
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Why $x\longmapsto \mathrm{sgn}(x)$ not in $W^{1,p}(\mathbb R)$?

Why $x\longmapsto \mathrm{sgn}(x)$ not in $W^{1,p}(\mathbb R)$ for all $p\in [1,+\infty ]?$ Indeed, $$\int_{-1}^1 sgn(x)\varphi'(x)\mathrm d x=\int (1_{(0,\infty ]}(x)-1_{(-\infty ,0)}(x))\varphi'(x)\mathrm d x=\int(x1_{(0,\infty )}(x)-x1_{(-\infty…
MSE
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On a subspace of a Sobolev space

I have a question about a subspace of a Sobolev space. Let $D$ be a domain of $\mathbb{R}^{d}$. That is, $D$ is a connected open subset. For a open subset $E \subset D$, $H^{1}(E)$ denotes first order $L^{2}$-Sobolev space on $E$ with Neumann…
sharpe
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Show that $|x|\in H^1(-1,1)$.

Let $$H^1(-1,1)=W^{1,2}(-1,1)=\left\{u\in L^2(-1,1)\mid \exists g\in L^2(-1,1): \forall \varphi\in \mathcal D(-1,1), \int u\varphi'=-\int g\varphi\right\}.$$ I just started Sobolev space, so how can I show that $|x|\in H^1(-1,1)$ ? What I tried is…
MSE
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