Markov Jump Dynamics with Additive Intensities in Continuum: State Evolution and Mesoscopic Scaling

Berns, Christoph; Kondratiev, Yuri; Kutoviy, Oleksandr

doi:10.1007/s10955-015-1365-z

Cited by 4 publications

(2 citation statements)

References 29 publications

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“…The rigorous derivation of the kinetic description was already done in [4]. Scaling the potential as b → εb and rescaling, we see that only the last terms in L and L ∆ will be multiplied by ε.…”

Section: Moving Cellsmentioning

confidence: 95%

Stochastic models of tumour development and related mesoscopic equations

Finkelshtein

2015

Мiждисциплiнарнi дослiдження складних систем

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We consider different mathematical models inspired by the problems of medicine, in particular, the tumour growth and the related topics. We demonstrate how to starting from an individual-based (microscopic) description, which characterizes cells' behaviour, derive the socalled kinetic (mesoscopic) equations, which describe the approximate system density. Properties of the solutions to the mesoscopic equations (in particular, their long-time behaviour) reflect statistical characteristics of the whole system and demonstrate the corresponding dependence on the system parameters.

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Section: Moving Cellsmentioning

confidence: 95%

Stochastic models of tumour development and related mesoscopic equations

Finkelshtein

2015

Мiждисциплiнарнi дослiдження складних систем

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“…It is necessary and sufficient that k t is positive definite in the sense of Lennard, see [KK02] and the references therein. Such a positivity property was studied for particular models in [FKK13a,BKK15], while a general result based on semigroup methods was obtained in [FK16]. As a consequence, using the theory of semigroups one is able to obtain existence of solutions to (1.3), while uniqueness holds among all solutions µ t for which the associated sequence of correlation functions k µt is a classical solution to (1.4).…”

Section: Introduction 1motivationmentioning

confidence: 99%

Linear evolution equations in scales of Banach spaces

Friesen

2019

Journal of Functional Analysis

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A variant of the abstract Cauchy-Kovalevskaya theorem is considered. We prove existence and uniqueness of classical solutions to the nonlinear, non-autonomous initial value problemin a scale of Banach spaces. Here A(t) is the generator of an evolution system acting in a scale of Banach spaces and B(u, t) obeys an Ovcyannikov-type bound. Continuous dependence of the solution with respect to A(t), B(u, t) and x is proved. The results are applied to the Kimura-Maruyama equation for the mutation-selection balance model. This yields a new insight in the construction and uniqueness question for nonlinear Fokker-Planck equations related with interacting particle systems in the continuum.

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Evolution of States of a Continuum Jump Model with Attraction

Kozitsky

2017

Trends in Mathematics

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We study a model of an infinite system of point particles in R d performing random jumps with attraction. The system's states are probability measures on the space of particle configurations, and their evolution is described by means of Kolmogorov and Fokker-Planck equations. Instead of solving these equations directly we deal with correlation functions evolving according to a hierarchical chain of differential equations, derived from the Kolmogorov equation. Under quite natural conditions imposed on the jump kernels -and analyzed in the paperwe prove that this chain has a unique classical sub-Poissonian solution on a bounded time interval. This gives a partial answer to the question whether the sub-Poissonicity is consistent with any kind of attraction. We also discuss possibilities to get a complete answer to this question.1991 Mathematics Subject Classification. 34G10; 47D06; 60J80.

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Markov Jump Dynamics with Additive Intensities in Continuum: State Evolution and Mesoscopic Scaling

Cited by 4 publications

References 29 publications

Stochastic models of tumour development and related mesoscopic equations

Stochastic models of tumour development and related mesoscopic equations

Linear evolution equations in scales of Banach spaces

Evolution of States of a Continuum Jump Model with Attraction

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