Your search keyword '"Elisa Affili"' showing total 4 results

1. Recurrence of the random process governed with the fractional Laplacian and the Caputo time derivative

Author

Elisa Affili and Jukka T. Kemppainen

Subjects

fractional diffusion, continuous time random walks, fundamental solution, decay estimates, caputo derivative, fractional laplacian, Analysis, QA299.6-433

Abstract

We are addressing a parabolic equation with fractional derivatives in time and space that governs the scaling limit of continuous-time random walks with anomalous diffusion. For these equations, the fundamental solution represents the probability density of finding a particle released at the origin at time 0 at a given position and time. Using some estimates of the asymptotic behaviour of the fundamental solution, we evaluate the probability of the process returning infinite times to the origin in a heuristic way. Our calculations suggest that the process is always recurrent.

Published

2023

2. Decay estimates for evolution equations with classical and fractional time-derivatives

Author

Elisa Affili and Enrico Valdinoci

Subjects

Polynomial, Diffusion (acoustics), Applied Mathematics, 010102 general mathematics, Structure (category theory), Complex valued, Space (mathematics), 01 natural sciences, Exponential function, 010101 applied mathematics, Nonlinear system, Applied mathematics, 0101 mathematics, Exponential decay, Analysis, Mathematics

Abstract

Using energy methods, we prove some power-law and exponential decay estimates for classical and nonlocal evolutionary equations. The results obtained are framed into a general setting, which comprise, among the others, equations involving both standard and Caputo time-derivative, complex valued magnetic operators, fractional porous media equations and nonlocal Kirchhoff operators. Both local and fractional space diffusion are taken into account, possibly in a nonlinear setting. The different quantitative behaviours, which distinguish polynomial decays from exponential ones, depend heavily on the structure of the time-derivative involved in the equation.

Published

2019

3. A New Lotka-Volterra Model of Competition With Strategic Aggression : Civil Wars When Strategy Comes Into Play

Author

Elisa Affili, Serena Dipierro, Luca Rossi, Enrico Valdinoci, Elisa Affili, Serena Dipierro, Luca Rossi, and Enrico Valdinoci

Subjects

Dynamical systems, Differential equations, Mathematical optimization, Mathematical models, System theory

Abstract

This monograph introduces a new mathematical model in population dynamics that describes two species sharing the same environmental resources in a situation of open hostility. Its main feature is the expansion of the family of Lotka-Volterra systems by introducing a new term that defines aggression. Because the model is flexible, it can be applied to various scenarios in the context of human populations, such as strategy games, competition in the marketplace, and civil wars. Drawing from a variety of methodologies within dynamical systems, ODEs, and mathematical biology, the authors'approach focuses on the dynamical properties of the system. This is accomplished by detecting and describing all possible equilibria, and analyzing the strategies that may lead to the victory of the aggressive population. Techniques typical of two-dimensional dynamical systems are used, such as asymptotic behaviors regulated by the Poincaré–Bendixson Theorem. A New Lotka-Volterra Model of Competition With Strategic Aggression will appeal to researchers and students studying population dynamics and dynamical systems, particularly those interested in the cross section between mathematics and ecology.

Published

2024

4. Interpolation and approximation via Momentum ResNets and Neural ODEs

Author

Domènec Ruiz-Balet, Elisa Affili, Enrique Zuazua, Domènec Ruiz-Balet, Elisa Affili, and Enrique Zuazua

Subjects

Neural Differential Equation, General Computer Science, Mechanical Engineering, Deep learning, 34H05, 37N35, 93B05, Simultaneous control, Universal approximation, Optimization and Control (math.OC), Simultaneous tracking controllability, Control and Systems Engineering, FOS: Mathematics, Momentum ResNet, Electrical and Electronic Engineering, Mathematics - Optimization and Control

Abstract

In this article, we explore the effects of memory terms in continuous-layer Deep Residual Networks by studying Neural ODEs (NODEs). We investigate two types of models. On one side, we consider the case of Residual Neural Networks with dependence on multiple layers, more precisely Momentum ResNets. On the other side, we analyse a Neural ODE with auxiliary states playing the role of memory states.We examine the interpolation and universal approximation properties for both architectures through a simultaneous control perspective. We also prove the ability of the second model to represent sophisticated maps, such as parametrizations of time-dependent functions. Numerical simulations complement our study. (c) 2022 Elsevier B.V. All rights reserved.