One-dimensional random field Kac's model: weak large deviations principle

AbstractWe study a model of active particles that perform a simple random walk and on top of that have a preferred direction determined by an internal state which is modelled by a stationary Markov process. First we calculate the limiting diffusion coefficient. Then we show that the ‘active part’ of the diffusion coefficient is in some sense maximal for reversible state processes. Further, we obtain a large deviations principle for the active particle in terms of the large deviations rate function of the empirical process corresponding to the state process. Again we show that the rate function and free energy function are (pointwise) optimal for reversible state processes. Finally, we show that in the case with two states, the Fourier–Laplace transform of the distribution, the moment generating function and the free energy function can be computed explicitly. Along the way we provide several examples.

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Correlation functions of the one-dimensional random-field Ising model at zero temperature

Physical Review B ◽

10.1103/physrevb.48.9508 ◽

1993 ◽

Vol 48 (13) ◽

pp. 9508-9514 ◽

Cited By ~ 7

Author(s):

Edward Farhi ◽

Sam Gutmann

Keyword(s):

Ising Model ◽

Random Field ◽

Correlation Functions ◽

Zero Temperature ◽

Random Field Ising Model ◽

One Dimensional ◽

The One

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A large‐deviations principle for all the cluster sizes of a sparse Erdős–Rényi graph

Random Structures and Algorithms ◽

10.1002/rsa.21007 ◽

2021 ◽

Author(s):

Luisa Andreis ◽

Wolfgang König ◽

Robert I. A. Patterson

Keyword(s):

Large Deviations ◽

Large Deviations Principle

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On Approximate Large Deviations for 1D Diffusion

Georgian Mathematical Journal ◽

10.1515/gmj.2003.381 ◽

2003 ◽

Vol 10 (2) ◽

pp. 381-399

Author(s):

A. Yu. Veretennikov

Keyword(s):

Differential Equation ◽

Exact Solution ◽

Large Deviations ◽

Stochastic Differential Equation ◽

Approximation Scheme ◽

Sufficient Conditions ◽

Rate Function ◽

Euler Approximation ◽

One Dimensional

Abstract We establish sufficient conditions under which the rate function for the Euler approximation scheme for a solution of a one-dimensional stochastic differential equation on the torus is close to that for an exact solution of this equation.

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Large Deviations for a Class of Multivariate Heavy-Tailed Risk Processes Used in Insurance and Finance

Journal of Risk and Financial Management ◽

10.3390/jrfm14050202 ◽

2021 ◽

Vol 14 (5) ◽

pp. 202

Author(s):

Miriam Hägele ◽

Jaakko Lehtomaa

Keyword(s):

Large Deviations ◽

Risk Sharing ◽

Dependence Structure ◽

Large Deviations Principle ◽

Shape Constraint ◽

Multiple Components ◽

Insurance Portfolio ◽

Heavy Tailed ◽

Tail Events ◽

Risk Processes

Modern risk modelling approaches deal with vectors of multiple components. The components could be, for example, returns of financial instruments or losses within an insurance portfolio concerning different lines of business. One of the main problems is to decide if there is any type of dependence between the components of the vector and, if so, what type of dependence structure should be used for accurate modelling. We study a class of heavy-tailed multivariate random vectors under a non-parametric shape constraint on the tail decay rate. This class contains, for instance, elliptical distributions whose tail is in the intermediate heavy-tailed regime, which includes Weibull and lognormal type tails. The study derives asymptotic approximations for tail events of random walks. Consequently, a full large deviations principle is obtained under, essentially, minimal assumptions. As an application, an optimisation method for a large class of Quota Share (QS) risk sharing schemes used in insurance and finance is obtained.

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Large deviations for randomly connected neural networks: II. State-dependent interactions

Advances in Applied Probability ◽

10.1017/apr.2018.43 ◽

2018 ◽

Vol 50 (3) ◽

pp. 983-1004 ◽

Cited By ~ 2

Author(s):

Tanguy Cabana ◽

Jonathan D. Touboul

Keyword(s):

Neural Networks ◽

Large Deviations ◽

Rate Function ◽

Network Size ◽

Kuramoto Model ◽

Empirical Measure ◽

Large Deviations Principle ◽

Stochastic Version ◽

State Dependent ◽

Spatially Extended

Abstract We continue the analysis of large deviations for randomly connected neural networks used as models of the brain. The originality of the model relies on the fact that the directed impact of one particle onto another depends on the state of both particles, and they have random Gaussian amplitude with mean and variance scaling as the inverse of the network size. Similarly to the spatially extended case (see Cabana and Touboul (2018)), we show that under sufficient regularity assumptions, the empirical measure satisfies a large deviations principle with a good rate function achieving its minimum at a unique probability measure, implying, in particular, its convergence in both averaged and quenched cases, as well as a propagation of a chaos property (in the averaged case only). The class of model we consider notably includes a stochastic version of the Kuramoto model with random connections.

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Large Deviations for the Single-Server Queue and the Reneging Paradox

Mathematics of Operations Research ◽

10.1287/moor.2021.1127 ◽

2021 ◽

Author(s):

Rami Atar ◽

Amarjit Budhiraja ◽

Paul Dupuis ◽

Ruoyu Wu

Keyword(s):

Large Deviations ◽

Decay Rate ◽

Sample Path ◽

Arrival Rate ◽

Rate Function ◽

Service Rate ◽

Single Server ◽

Large Deviations Principle ◽

Long Run ◽

The Individual

For the M/M/1+M model at the law-of-large-numbers scale, the long-run reneging count per unit time does not depend on the individual (i.e., per customer) reneging rate. This paradoxical statement has a simple proof. Less obvious is a large deviations analogue of this fact, stated as follows: the decay rate of the probability that the long-run reneging count per unit time is atypically large or atypically small does not depend on the individual reneging rate. In this paper, the sample path large deviations principle for the model is proved and the rate function is computed. Next, large time asymptotics for the reneging rate are studied for the case when the arrival rate exceeds the service rate. The key ingredient is a calculus of variations analysis of the variational problem associated with atypical reneging. A characterization of the aforementioned decay rate, given explicitly in terms of the arrival and service rate parameters of the model, is provided yielding a precise mathematical description of this paradoxical behavior.

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