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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Question in Sobolev space

Let $\Omega$ be a bounded domain and suppose $u\in W^{1,2}(\Omega)\cap C^{0,\alpha}(\Omega)$ for some $0<\alpha<1$. Then is it true that $$u\in W^{1,p}(\Omega)~~\text{ for all } p>1?$$ My attempt: For $1
Arun
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A queston in Rellich's embedding theorem

Let $(e_j)$ be an orthonormal basis of $H^1_0(\Omega)$ and define $X_k=\oplus_{j\geq k}X(j)$ where $X(j)=span\{e_j\}$. Then $$\sup_{u\in X_k-0}\dfrac{\|u\|_{L^q(\Omega)}}{\|u\|_{H^1_0(\Omega)}}\to 0, \text{ as } k\to \infty.$$ This is a result used…
Arun
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Distributional derivative of a square integrable function and dual of Sobolev space

This is a simple question: Let $f\in L^2(\mathbb{R})$, $f'$ be its distributional derivative, then is $f'$an element of $H^{-1}(\mathbb{R})$, the dual of Sobolev space $H^1(\mathbb{R})$? Also, if I take an element of $H^{-1}(\mathbb{R})$, say $q$,…
Xuxu
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Density in negative Sobolev spaces

Consider $\Omega = (0,2 \pi)^d$ and the negative Sobolev space $H^{-s}(\Omega)$, defined as the dual of $H^s_0(\Omega)$ for the $L^2$ inner product. Due to the simple shape of $\Omega$, we can see $H^{-s}(\Omega)$ as a Banach/Hilbert space with the…
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Proving the composition of a function with an $H^1$ function is in $H^1$.

Let $\Omega \subseteq \mathbb{R}^n$ be open, bounded with smooth boundary. Does $u \in H^1(\Omega)$ imply that $(1+u^2)^{\frac{1}{2}}\in H^1(\Omega)$? If yes, I would expect a more general result holds about composing $H^1(\Omega)$ with $C^1$…
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Easy question about $H_0^1$ space

I have some trouble with proper understanding of $H_0^1(0,1)$ space. Consider the following space $$H_D = \{u\in H^1(0,1): u(0) = u(1) = 0\}.$$ What can we say about the connection between $H_D$ and $H^1_0(0,1)$. Is $H_D$ in $H^1_0(0,1)$? In…
Dina
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for what values $\alpha\in \Bbb{R}$ we have $v_{\alpha}\in H^{1}(\Omega)$?

If $\Omega$ circle with radius $\frac{1}{2}$ centred at the origin, for what values $\alpha\in \Bbb{R}$ for function $$v_{\alpha}(x,y)=|log(x^2+y^2)|^{\alpha}$$ we have $v_{\alpha}\in H^{1}(\Omega)$?
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Smoothing for a function in $W^{k,p}$ which vanishies on boundary

Let $\Omega$ be a domain $\Omega$ of $\mathbb{R}^d$. Let $u \in W^{k,p}(\Omega)$ whose restriction to the boundary $\partial \Omega$ is identically zero. (To consider the "value", should we choose the superscripts $k,p$ so that $W^{k,p}$ is imbedded…
Camford Oxbridge
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Radial lemmas of Strauss, Berestycki, and Lions

A famous radial lemma of Strauss states that Theorem (Strauss). For $n \geq 2$, every radial function $u \in W^{1,2}(\mathbf R^n)$ is almost everywhere equal to a function $U$, continuous for $x \ne 0$ and such that $$|U(x)| \lesssim…
QA Ngô
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Weighted integrability of Sobolev functions in $H^2_p$

Suppose $u \in H^2_p(\mathbb{R}^n)$. What can be said about the decay of $u$ in an $L^p(\mathbb{R}^n)$ sense, i.e. is it true that $$\int_{\mathbb{R}^n} |xu(x)|^pdx < \infty?$$
Rooibos
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Poincaré inequality with a difference quotient

I am working on the following problem: For $\Omega\in \mathbb{R}^N$ an open set and $K\subset\subset\Omega$ a compact subset, define the difference quotient in $j$ direction by $$D^h_ju(x)=\frac{u(x+he_j)-u(x)}{h}$$ prove that there exists a…
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Sobolev imbedding theorem $H^{1,p}(\mathbb{R}^n)$ contained in $L^{{np}/(n-p)}(\mathbb{R}^n)$ (Taylor Michael)

i. I can not make sense of the following: For (2.4) I imagine that it is the fundamental theorem of the calculation but I can not prove it formally. Neither will it be understood how to arrive at equation 2.6. For this I had thought the…
eraldcoil
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$u\in W^{1,p}(\Omega)$ with $u\in L^q(\Omega)$. Does this implies that $v\in L^q(\Omega)$ for $v$ close to $u$?

Let $\Omega\subset\mathbb{R}^n$ be a bounded domain and suppose that $p0$ such that for all $v\in W^{1,p}(\Omega)$…
Tomás
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A question about the relation between weak and strong derivatives in Sobolev spaces

I am attaching photos from the chapter "Sobolev Spaces". What the author does is that first he approximates a $W^{1,1}$ function by smooth functions that converge in the $\|\|_{W^{1,1}}$ norm, and hence also converge pointwise ae. Then he takes a…