2018
DOI: 10.1002/cpa.21752
|View full text |Cite
|
Sign up to set email alerts
|

Approximation of General Facets by Regular Facets with Respect to Anisotropic Total Variation Energies and Its Application to Crystalline Mean Curvature Flow

Abstract: We show that every bounded subset of a euclidean space can be approximated by a set that admits a certain vector field, the so‐called Cahn‐Hoffman vector field, that is subordinate to a given anisotropic metric and has a square‐integrable divergence. More generally, we introduce a concept of facets as a kind of directed sets, and show that they can be approximated in a similar manner. We use this approximation to construct test functions necessary to prove the comparison principle for viscosity solutions of th… Show more

Help me understand this report

Search citation statements

Order By: Relevance

Paper Sections

Select...
3
1

Citation Types

0
61
0

Year Published

2018
2018
2024
2024

Publication Types

Select...
8

Relationship

2
6

Authors

Journals

citations
Cited by 25 publications
(61 citation statements)
references
References 35 publications
0
61
0
Order By: Relevance
“…(iv) (Generic non-fattening): As in the classical case, for any given uniformly continuous initial datum u 0 all but countably many sublevels do not produce any fattening. (v) (Comparison with other notions of solutions): Our solution-via-approximation u coincides with the classical viscosity solution in the smooth case and with the Giga-Požár viscosity solution [38,39] whenever such a solution is well-defined, that is, when g is constant, φ is purely crystalline and the initial set is bounded. (vi) (Phase-field approximation): When g is constant, a phase-field Allen-Cahn type approximation of u holds.…”
mentioning
confidence: 70%
“…(iv) (Generic non-fattening): As in the classical case, for any given uniformly continuous initial datum u 0 all but countably many sublevels do not produce any fattening. (v) (Comparison with other notions of solutions): Our solution-via-approximation u coincides with the classical viscosity solution in the smooth case and with the Giga-Požár viscosity solution [38,39] whenever such a solution is well-defined, that is, when g is constant, φ is purely crystalline and the initial set is bounded. (vi) (Phase-field approximation): When g is constant, a phase-field Allen-Cahn type approximation of u holds.…”
mentioning
confidence: 70%
“…A typical example of such a motion is anisotropic mean curvature flow: given a norm φ on R n (called anisotropy), the equation for the anisotropic mean curvature flow of hypersurfaces parametrized as Γ t reads as β(ν)V = −div Γt [∇φ(ν)] on Γ t , (1.1) where V denotes the normal velocity of Γ t in the direction of the unit outer normal ν of Γ t and β is the mobility, a positive kinetic coefficient [30]. Anisotropic mean curvature flow is called crystalline provided the boundary of the Wulff shape W φ := {φ ≤ 1} lies on finitely many hyperplanes; in this quite interesting case, equation (1.1) must be properly interpreted, due to the nondifferentiability of φ ; see for instance [1,29,52,28,12,13,31,20,32,17,18]. Equation (1.1) (sometimes referred to as the two-phase evolution) can be generalized to the case of networks in the plane, and more generally to the case of partitions of space (sometimes called the multiphase case): here the evolving sets are intrisically nonsmooth, since the presence of triple junctions (in the plane), or multiple lines, quadruple points etc.…”
Section: Introductionmentioning
confidence: 99%
“…Remark 3.9 (Comparison with the Giga-Pozar solution). When φ is purely crystalline and g ≡ c for some c ∈ R the unique level set solution in the sense of Definition 3.6 coincides with the viscosity solution constructed in [33,34].…”
Section: 22mentioning
confidence: 65%
“…However, when the anisotropy φ in (1.1) is non-differentiable or crystalline, the lack of smoothness of the involved differential operators makes it much harder to pursue the aforementioned approaches. In fact, in the crystalline case the problem of finding a suitable weak formulation of (1.1) in dimension N ≥ 3 leading to a unique global-in-time solution for general initial sets has remained open until the very recent works [17,33,16,34].…”
Section: Introductionmentioning
confidence: 99%
See 1 more Smart Citation