Large Deviations for 2D Primitive Equations Driven by Multiplicative Lévy Noises

AbstractWe consider the hydrostatic Boussinesq equations of global ocean dynamics, also known as the “primitive equations”, coupled to advection–diffusion equations for temperature and salt. The system of equations is closed by an equation of state that expresses density as a function of temperature, salinity and pressure. The equation of state TEOS-10, the official description of seawater and ice properties in marine science of the Intergovernmental Oceanographic Commission, is the most accurate equations of state with respect to ocean observation and rests on the firm theoretical foundation of the Gibbs formalism of thermodynamics. We study several specifications of the TEOS-10 equation of state that comply with the assumption underlying the primitive equations. These equations of state take the form of high-order polynomials or rational functions of temperature, salinity and pressure. The ocean primitive equations with a nonlinear equation of state describe richer dynamical phenomena than the system with a linear equation of state. We prove well-posedness for the ocean primitive equations with nonlinear thermodynamics in the Sobolev space $${{\mathcal {H}}^{1}}$$ H 1 . The proof rests upon the fundamental work of Cao and Titi (Ann. Math. 166:245–267, 2007) and also on the results of Kukavica and Ziane (Nonlinearity 20:2739–2753, 2007). Alternative and older nonlinear equations of state are also considered. Our results narrow the gap between the mathematical analysis of the ocean primitive equations and the equations underlying numerical ocean models used in ocean and climate science.

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On the ineffectiveness of constant rotation in the primitive equations and their symmetry analysis

Communications in Nonlinear Science and Numerical Simulation ◽

10.1016/j.cnsns.2021.105885 ◽

2021 ◽

pp. 105885

Author(s):

Elsa Dos Santos Cardoso-Bihlo ◽

Roman O. Popovych

Keyword(s):

Symmetry Analysis ◽

Primitive Equations

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Precise Large Deviations for Sums of Claim-size Vectors in a Two-dimensional Size-dependent Renewal Risk Model

Acta Mathematicae Applicatae Sinica English Series ◽

10.1007/s10255-021-1030-z ◽

2021 ◽

Vol 37 (3) ◽

pp. 539-547

Author(s):

Ke-ang Fu ◽

Xin-mei Shen ◽

Hui-jie Li

Keyword(s):

Large Deviations ◽

Risk Model ◽

Claim Size ◽

Two Dimensional ◽

Precise Large Deviations ◽

Renewal Risk Model ◽

Size Dependent ◽

Renewal Risk

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Run-and-Tumble Motion: The Role of Reversibility

Journal of Statistical Physics ◽

10.1007/s10955-021-02787-1 ◽

2021 ◽

Vol 183 (3) ◽

Author(s):

Bart van Ginkel ◽

Bart van Gisbergen ◽

Frank Redig

Keyword(s):

Free Energy ◽

Diffusion Coefficient ◽

Large Deviations ◽

Energy Function ◽

Internal State ◽

Rate Function ◽

Free Energy Function ◽

Large Deviations Principle ◽

Preferred Direction ◽

State Process

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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Weighted approximate Bayesian computation via Sanov’s theorem

Computational Statistics ◽

10.1007/s00180-021-01093-4 ◽

2021 ◽

Author(s):

Cecilia Viscardi ◽

Michele Boreale ◽

Fabio Corradi

Keyword(s):

Large Deviations ◽

Posterior Distribution ◽

Approximate Bayesian Computation ◽

Bayesian Computation ◽

Information Theoretic ◽

Discrete Random Variables ◽

Positive Weights ◽

Approximate Bayesian ◽

Information Theoretic Method ◽

Computational Resources

AbstractWe consider the problem of sample degeneracy in Approximate Bayesian Computation. It arises when proposed values of the parameters, once given as input to the generative model, rarely lead to simulations resembling the observed data and are hence discarded. Such “poor” parameter proposals do not contribute at all to the representation of the parameter’s posterior distribution. This leads to a very large number of required simulations and/or a waste of computational resources, as well as to distortions in the computed posterior distribution. To mitigate this problem, we propose an algorithm, referred to as the Large Deviations Weighted Approximate Bayesian Computation algorithm, where, via Sanov’s Theorem, strictly positive weights are computed for all proposed parameters, thus avoiding the rejection step altogether. In order to derive a computable asymptotic approximation from Sanov’s result, we adopt the information theoretic “method of types” formulation of the method of Large Deviations, thus restricting our attention to models for i.i.d. discrete random variables. Finally, we experimentally evaluate our method through a proof-of-concept implementation.

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