2013
DOI: 10.3934/krm.2013.6.219
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Fine asymptotics of profiles and relaxation to equilibrium for growth-fragmentation equations with variable drift rates

Abstract: We are concerned with the long-time behavior of the growth-fragmentation equation. We prove fine estimates on the principal eigenfunctions of the growth-fragmentation operator, giving their first-order behavior close to 0 and +∞. Using these estimates we prove a spectral gap result by following the technique in [1], which implies that solutions decay to the equilibrium exponentially fast. The growth and fragmentation coefficients we consider are quite general, essentially only assumed to behave asymptotically … Show more

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Cited by 36 publications
(97 citation statements)
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“…Usually, even when it is possible to establish (5), it is difficult to find an explicit expression for the asymptotic profile. In [2], the authors provided fine estimates on the principal eigenfunctions, giving their first order behaviour close to 0, and +∞ (see also [7]). In this work, we have been able to characterize the asymptotic profile in a fairly explicit way using special properties of refracted Lévy processes.…”
Section: Ifmentioning
confidence: 99%
See 1 more Smart Citation
“…Usually, even when it is possible to establish (5), it is difficult to find an explicit expression for the asymptotic profile. In [2], the authors provided fine estimates on the principal eigenfunctions, giving their first order behaviour close to 0, and +∞ (see also [7]). In this work, we have been able to characterize the asymptotic profile in a fairly explicit way using special properties of refracted Lévy processes.…”
Section: Ifmentioning
confidence: 99%
“…By definition of Φ − , for a solution to (18) to exist, one must have that Ψ ′ − (−1) ≥ 0. First of all, Ψ ′ − (−1) is well-defined and finite thanks to (2). Moreover, by (13), Ψ ′ − (−1) ≥ 0 is equivalent to − 1 0 log(s) ρ(s)ds ≤ a − and in this case the solution to (18) is given by…”
Section: Preliminaries and General Strategymentioning
confidence: 99%
“…We notice that B only appears multiplied by N in Equation (2), so that it cannot be accurately estimated from this equation where N vanishes (near 0 and near +∞). Hence, we denote H = BN and in this article we focus on estimating H rather than B (the interested reader may find in [12] a fully rigorous estimate of B, obtained after a truncated division by N, i.e.…”
Section: Introductionmentioning
confidence: 98%
“…Inverse Problem (IP): Given a measure N ε of the solution N of Equation (2), if N ε satisfies Estimate (3), how can we get an approximation H ε of H solution of Equation (4), and estimate the approximation error ∥H − H ε ∥ L 2 (x q dx) in terms of ε, for small enough values of q and for large enough values of q?…”
Section: Introductionmentioning
confidence: 99%
“…This is true not only for BeckerDöring equation [5], but also for growth fragmentation equations [15,4], for stochastic models [16], etc. This is one of the reasons that makes size distribution analysis so important: if taken at an instant where steady state or steady growth is observed, it is possible to interpret it as solution of a time-independent equation and thus to estimate kinetic coefficients from its shape.…”
Section: Statistical Analysis Of the Datamentioning
confidence: 99%