A Density Result for Homogeneous Sobolev Spaces on Planar Domains

Abstract: We show that in a bounded Gromov hyperbolic domain Ω smooth functions with bounded derivatives C ∞ (Ω) ∩ W k,∞ (Ω) are dense in the homogeneous Sobolev spaces L k,p (Ω). IntroductionWe continue the study of density of functions with bounded derivatives in the space of Sobolev functions in a domain in R n . It was shown by Koskela-Zhang [13] that for a simply connected planar domain Ω ⊂ R 2 , W 1,∞ is dense in W 1,p and in the special case of Jordan domains also C ∞ (R 2 ) ∩ W 1,∞ (Ω) is dense. The above result… Show more

“…In this section we prove Theorem 1.1, using the results of Section 2 and the partition of union from [28] that was recalled in Section 3. The polynomial approximation is exactly the same as in [28]. What is different is the way the estimates are carried out using Poincaré inequalities.…”

“…Such decomposition is standard in analysis, see for instance Whitney [34] or the book of Stein [32,Chapter VI]. We will use a version of the decomposition that was used in [28].…”

“…In this section we recall the decomposition of the domain Ω and the associated partition of unity that was obtained in [28]. In order to make the comparison between this paper and [28] easy, we use here the notation from [28].…”

“…The sets Hi are expanded by taking a connected component H i of a 2 −n−3 neighbourhood of Hi . The main property of the decomposition is that these expanded sets still satisfy H i ∩ H j = ∅ if and only if |i − j| ≤ 1 in a cyclical manner (Lemma 3.4 in [28]). Moreover, since the neighbourhoods are taken in the Euclidean distance, we may use an Euclidean partition of unity.…”

“…The validity of the approximation is proven using a Ψ − Ψ Poincaré inequality. The form of the polynomial approximation we use here was introduced in [28], where a density result was shown for homogeneous Sobolev spaces on simply connected planar domains. This was then extended to Gromov hyperbolic domains in higher dimensions in [27].…”

A density result on Orlicz-Sobolev spaces in the plane

“…In this section we prove Theorem 1.1, using the results of Section 2 and the partition of union from [28] that was recalled in Section 3. The polynomial approximation is exactly the same as in [28]. What is different is the way the estimates are carried out using Poincaré inequalities.…”

“…Such decomposition is standard in analysis, see for instance Whitney [34] or the book of Stein [32,Chapter VI]. We will use a version of the decomposition that was used in [28].…”

“…In this section we recall the decomposition of the domain Ω and the associated partition of unity that was obtained in [28]. In order to make the comparison between this paper and [28] easy, we use here the notation from [28].…”

“…The sets Hi are expanded by taking a connected component H i of a 2 −n−3 neighbourhood of Hi . The main property of the decomposition is that these expanded sets still satisfy H i ∩ H j = ∅ if and only if |i − j| ≤ 1 in a cyclical manner (Lemma 3.4 in [28]). Moreover, since the neighbourhoods are taken in the Euclidean distance, we may use an Euclidean partition of unity.…”

“…The validity of the approximation is proven using a Ψ − Ψ Poincaré inequality. The form of the polynomial approximation we use here was introduced in [28], where a density result was shown for homogeneous Sobolev spaces on simply connected planar domains. This was then extended to Gromov hyperbolic domains in higher dimensions in [27].…”

A density result on Orlicz-Sobolev spaces in the plane

Fractional Laplacian, homogeneous Sobolev spaces and their realizations

A density result on Orlicz-Sobolev spaces in the plane