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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Product from function in $W^{1,2}_0(\Omega)$ and function in $W^{1,2}(\Omega)$

I was wandering what i say about product $$ u\eta $$ where $u\in W^{1,2}(\Omega)$ and $\eta\in W^{1,2}_0(\Omega)$. In particular, when i can say that $$ u\eta\in W^{1,2}_0(\Omega). $$ Is it necessary to make more assumptions about u?
Revzora
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Sobolev space $W^{k,p}_0$

Given a smooth domain $\Omega$, one can define the sobolev space $$W_{k,p}^0 = \text{ closure of } C_c^{\infty} \text{ in } W_{k,p}(U)$$ One interpretation of this space is given in the book Partial Differential Equations by Evans as $W^{k,p}_0$…
tgtt
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Unique Harmonic Extension in $H^1(\Omega)$

In lecture we had the following theorem: Let $\Omega \subseteq \subseteq \mathbb{R}^n$. Then $$H^1(\Omega) = H^1_0(\Omega) \oplus \{u \in H^1 : \Delta u = 0\}$$ where $\Delta u$ is understood in the distributional sense. Moreover, if $\Omega$ is…
TheGeekGreek
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How to show that $u(t,x)\in C([0,T],H^{1}(\mathbb{R}^{n}))$?

If $u(t,x)\in L^{2}([0,T],H^{2}(\mathbb{R}^{n}))$, $\partial_{t}u \in L^{2}([0,T],L^{2}(\mathbb{R}^{n}))$, prove that $$ u(t,x)\in C([0,T],H^{1}(\mathbb{R}^{n})) $$
Tomas
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If $f$ is in $H^{s},$ is it true that $1/f$ is in $H^{s}?$

No. It is not true. However, I was wondering under what conditions it is true. I think that if $s>n/2$ and $1/f$ is bounded the result holds. Is it true? Edit. If the domain is unbounded the set described may be empty as shown by TZakrevskiy's…
yess
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If $(m-1)p\geq n$, $u(x)=|x|$ does not belong to $W^{m,p}(B(0,1))$.

Suppose $(m-1)p\geq n$. I tried proof that $u(x)=|x|$ does not belong to $W^{m,p}(B(0,1))$. I was able to calculate $|D^0u|=|x|$, $|D^1u|=1$ and $|D^2u|=\sqrt{\dfrac{1-|x|_s^2}{|x|^2}}$. Here $D^ju$ represents the $N^j$-vector of all partial weak…
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Sobolev Embedding Theorem

In the Sobolev Embedding Theorem, what does it mean for the constant to depend on the domain $\Omega$? I know the constant depends on the dimension of the domain, but when you say $C$ depends on $\Omega$, how is it deferent from the dependence of…
Koda
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Radial Lemma for Sobolev Spaces

My question is about show: Let $N\geq 2$ and $1\leq p<\infty$. Every radial function $u\in W^{1,p}(\mathbb R^ N)$ satisfy $$ |u(x)|\leq C|x|^{-\frac{N-1}{p}}\|u\|_{W^{1,p}(\mathbb R^ N)}, $$ where $C$ is a positive constant depending only on $N$ and…
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Smooth approximation of non-negative Sobolev function

I need a help to solve this question: Let $u\in H^{1}_{0}(\Omega)$ with $u\geq 0$. Can I find a sequence of smooth non-negative functions converging to $u$ in $H^{1}_{0}(\Omega)$? Thank you in advance.
Said
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Evans-Gariepy proof of $f\in W^{1,\infty}_\text{loc}(U)$ iff $f$ is locally Lipschitz continuous in $U$

I am reading the following proof: I do not understand where the equality $$\int_U f(x)\frac{\phi(x+he_i)-\phi(x)}{h}dx=-\int_U g_i^h(x)\phi(x+he_i)dx$$ is coming from. If we were integrating over all of $\mathbb{R}^n$, then it would follow by…
Reveillark
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Why the weighted fractional Sobolev semi-norm si not defined for $p=1$?

We defined the Weighted Sobolev semi-norm by $$[u]_{W^{s,p,\alpha }(\Omega )}^p=\iint_{\Omega \times \Omega }\frac{|u(x)-u(y)|^p |x|^{\alpha _1p}|y|^{\alpha _2p}}{|x-y|^{sp+d}}dxdy,$$ where $\alpha =\alpha _1+\alpha _2$, where $p\in(1,\infty )$. The…
idm
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If $u\in \mathcal C_c^\infty (\mathbb R^d)$ does $|u|^a\in W^{1,p}$ if $a>0$ for $p\geq 1$?

If $u\in \mathcal C_c^\infty (\mathbb R^d)$ (i.e. compacted supported) does $|u|^a\in W^{1,p}(\mathbb R^d)$ if $a>0$ and $p\geq 1$ ? I don't need a proof, just a confirmation because I used it in my bachelor thesis, but I'm not totally sure that…
user330587
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Prove $\|u\|_{L^r(\mathbb R^d)}\leq C\|\nabla u\|_{L^p(\mathbb R^d)}^a\|u\|_{L^q(\mathbb R^d)}^{1-a}$ if $\frac{1}{r}=\frac{1-a}{q}$

Let $a\in (0,1)$. Prove $$\|u\|_{L^r(\mathbb R^d)}\leq C\|\nabla u\|_{L^p(\mathbb R^d)}^a\|u\|_{L^q(\mathbb R^d)}^{1-a},\quad u\in \mathcal C_c^1(\mathbb R^d)$$ if $\frac{1}{r}=\frac{1-a}{q}$ and $\frac{1}{p}-\frac{1}{d}=0$ with $C$ independent of…
idm
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Sobolev functions vanish in a ball

Assume $u\in H^1(\mathbb R^N)$ and $u=0$ a.e. in $B_1$. Does it hold that $u\in H_0^1(\mathbb R^N\setminus \overline B_1)$? I tried to find smooth functions with compact support to approximate $u$. For example $\rho_n*u$, with $\rho_n$ being…
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One of conjectures of De Giorgi

conjecture: If $\exp(tw), \exp(tw^{-1}) \in L^1_{\operatorname{loc}}$ for each $t > 0$ then $w$ is regular weight. $w$ is regular if weighted Sobolev space $W^l_p(\Omega,w)$ is equal to the completion of $C^{\infty}$ with respect to the weighted…