Your search keyword '"Gianmarco Giovannardi"' showing total 6 results

1. Regularity of solutions to the fractional Cheeger-Laplacian on domains in metric spaces of bounded geometry

Author

Gareth Speight, Nageswari Shanmugalingam, Gianmarco Giovannardi, Sylvester Eriksson-Bique, Riikka Korte, University of Oulu, Università degli Studi di Trento, Department of Mathematics and Systems Analysis, University of Cincinnati, Aalto-yliopisto, and Aalto University

Subjects

Primary: 31E05, Secondary: 35A15, 50C25, 35J70, Hölder condition, Metric measure space, 01 natural sciences, Fractional Laplacian, Combinatorics, 010104 statistics & probability, Mathematics - Analysis of PDEs, Mathematics - Metric Geometry, Traces and extensions, FOS: Mathematics, Uniqueness, 0101 mathematics, Besov space, Existence and uniqueness for Dirichlet problem, Mathematics, Dirichlet problem, Applied Mathematics, 010102 general mathematics, Metric Geometry (math.MG), Dirichlet's energy, Metric space, Bounded function, Laplace operator, Analysis, Strong maximum principle, Analysis of PDEs (math.AP)

Abstract

We study existence, uniqueness, and regularity properties of the Dirichlet problem related to fractional Dirichlet energy minimizers in a complete doubling metric measure space $(X,d_X,\mu_X)$ satisfying a $2$-Poincar\'e inequality. Given a bounded domain $\Omega\subset X$ with $\mu_X(X\setminus\Omega)>0$, and a function $f$ in the Besov class $B^\theta_{2,2}(X)\cap L^2(X)$, we study the problem of finding a function $u\in B^\theta_{2,2}(X)$ such that $u=f$ in $X\setminus\Omega$ and $\mathcal{E}_\theta(u,u)\le \mathcal{E}_\theta(h,h)$ whenever $h\in B^\theta_{2,2}(X)$ with $h=f$ in $X\setminus\Omega$. We show that such a solution always exists and that this solution is unique. We also show that the solution is locally H\"older continuous on $\Omega$, and satisfies a non-local maximum and strong maximum principle. Part of the results in this paper extend the work of Caffarelli and Silvestre in the Euclidean setting and Franchi and Ferrari in Carnot groups., Comment: 42 pages, comments welcome, submitted. Revision to add crucial references and attributions to the introduction

Published

2022

2. Regularity of Lipschitz boundaries with prescribed sub-Finsler mean curvature in the Heisenberg group H1

Author

Manuel Ritoré and Gianmarco Giovannardi

Subjects

Set (abstract data type), Pure mathematics, Mean curvature, Continuous function, Applied Mathematics, Euclidean geometry, Heisenberg group, Mathematics::Metric Geometry, Boundary (topology), Lipschitz continuity, Convex function, Analysis, Mathematics

Abstract

For a strictly convex set K ⊂ R 2 of class C 2 we consider its associated sub-Finsler K-perimeter | ∂ E | K in H 1 and the prescribed mean curvature functional | ∂ E | K − ∫ E f associated to a continuous function f. Given a critical set for this functional with Euclidean Lipschitz and intrinsic regular boundary, we prove that their characteristic curves are of class C 2 and that this regularity is optimal. The result holds in particular when the boundary of E is of class C 1 .

Published

2021

3. An Ahmad-Lazer-Paul-type result for indefinite mixed local-nonlocal problems

Author

Gianmarco Giovannardi, Dimitri Mugnai, and Eugenio Vecchi

Subjects

Mathematics - Analysis of PDEs, 35A15, 35J62, 35R11, Applied Mathematics, FOS: Mathematics, Analysis, Analysis of PDEs (math.AP)

Abstract

We prove the existence and multiplicity of weak solutions for a mixed local-nonlocal problem at resonance. In particular, we consider a not necessarily positive operator which appears in models describing the propagation of flames. A careful adaptation of well known variational methods is required to deal with the possible existence of negative eigenvalues., Comment: arXiv admin note: text overlap with arXiv:2207.14008

Published

2023

4. Higher Dimensional Holonomy Map for Ruled Submanifolds in Graded Manifolds

Author

Gianmarco Giovannardi

Subjects

Mathematics - Differential Geometry, Pure mathematics, QA299.6-433, Applied Mathematics, 49q99, 010102 general mathematics, Holonomy, 58h99, 58a17, sub-riemannian manifolds, 01 natural sciences, 58H99, 49Q99, 58A17, 010101 applied mathematics, Differential Geometry (math.DG), FOS: Mathematics, graded manifolds, higher-dimensional holonomy map, Geometry and Topology, Mathematics::Differential Geometry, 0101 mathematics, regular and singular ruled submanifolds, Analysis, Mathematics, admissible variations

Abstract

The deformability condition for submanifolds of fixed degree immersed in a graded manifold can be expressed as a system of first order PDEs. In the particular but important case of ruled submanifolds, we introduce a natural choice of coordinates, which allows to deeply simplify the formal expression of the system, and to reduce it to a system of ODEs along a characteristic direction. We introduce a notion of higher dimensional holonomy map in analogy with the one-dimensional case [29], and we provide a characterization for singularities as well as a deformability criterion.

Published

2020

5. Submanifolds of Fixed Degree in Graded Manifolds for Perceptual Completion

Author

Manuel Ritoré, Giovanna Citti, Alessandro Sarti, Gianmarco Giovannardi, Nielsen, F., Barbaresco, F, Citti G., Giovannardi G., Ritore M., and Sarti A.

Subjects

Pure mathematics, Minimal surface, Group (mathematics), Graded structure, Structure (category theory), Lie group, Codimension, Type (model theory), Area formula, Image (mathematics), Degree preservig variation, Fixed degree surface, Metric (mathematics), Perceptual completion, Mathematics

Abstract

We extend to a Engel type structure a cortically inspired model of perceptual completion initially proposed in the Lie group of positions and orientations with a sub-Riemannian metric. According to this model, a given image is lifted in the group and completed by a minimal surface. The main obstacle in extending the model to a higher dimensional group, which can code also curvatures, is the lack of a good definition of codimension 2 minimal surface. We present here this notion, and describe an application to image completion.

Published

2021

6. Variational formulas for submanifolds of fixed degree

Author

Giovanna Citti, Gianmarco Giovannardi, Manuel Ritoré, Citti G., Giovannardi G., and Ritore M.

Subjects

Mathematics - Differential Geometry, 0209 industrial biotechnology, 02 engineering and technology, 53C42, 01 natural sciences, 49Q05, 53C42, 53C17, 020901 industrial engineering & automation, Operator (computer programming), 53C17, Mathematics - Metric Geometry, FOS: Mathematics, 0101 mathematics, Admissible variations, Mathematics, Mean curvature, Partial differential equation, Degree (graph theory), Applied Mathematics, 010102 general mathematics, Mathematical analysis, Degree of a submanifold, Metric Geometry (math.MG), Graded manifolds, Submanifold, 49Q05, Manifold, Differential Geometry (math.DG), Metric (mathematics), Sub-Riemannian manifolds, Vector field, Mathematics::Differential Geometry, Analysis, Isolated submanifolds

Abstract

We consider in this paper an area functional defined on submanifolds of fixed degree immersed into a graded manifold equipped with a Riemannian metric. Since the expression of this area depends on the degree, not all variations are admissible. It turns out that the associated variational vector fields must satisfy a system of partial differential equations of first order on the submanifold. Moreover, given a vector field solution of this system, we provide a sufficient condition that guarantees the possibility of deforming the original submanifold by variations preserving its degree. As in the case of singular curves in sub-Riemannian geometry, there are examples of isolated surfaces that cannot be deformed in any direction. When the deformability condition holds we compute the Euler-Lagrange equations. The resulting mean curvature operator can be of third order., Horizon 2020 Project ref. 777822: GHAIA, MEC-Feder grants MTM2017-84851-C2-1-P and PID2020-118180GB-I00, Junta de Andalucía grants A-FQM-441-UGR18 and P20-00164, Research Unit MNat SOMM17/6109 and PRIN 2015 “Variational and perturbative aspects of nonlinear differential problems”, Universidad de Granada/CBUA

Published

2019