MATHICSE Technical Report : Analysis of a class of Multi-Level Markov Chain Monte Carlo algorithms based on Independent Metropolis-Hastings

Juan Pablo Madrigal Cianci, Fabio Nobile
MATHICSE, 2021
Rapport ou document de travail

Résumé

In this work, we present, analyze, and implement a class of Multi-Level Markov chain Monte Carlo (ML-MCMC) algorithms based on independent Metropolis-Hastings proposals for Bayesian inverse problems. In this context, the likelihood function involves solving a complex differential model, which is then approximated on a sequence of increasingly accurate discretizations. The key point of this algorithm is to construct highly coupled Markov chains together with the standard Multi-level Monte Carlo argument to obtain a better cost-tolerance complexity than a single-level MCMC algorithm. Our method extends the ideas of Dodwell, et al. "A hierarchical multilevel Markov chain Monte Carlo algorithm with applications to uncertainty quantification in subsurface flow," SIAM/ASA Journal on Uncertainty Quantification 3.1 (2015): 1075-1108, to a wider range of proposal distributions. We present a thorough convergence analysis of the ML-MCMC method proposed, and show, in particular, that (i) under some mild conditions on the (independent) proposals and the family of posteriors, there exists a unique invariant probability measure for the coupled chains generated by our method, and (ii) that such coupled chains are uniformly ergodic. We also generalize the cost-tolerance theorem of Dodwell et al., to our wider class of ML-MCMC algorithms. Finally, we propose a self-tuning continuation-type ML-MCMC algorithm (C-ML-MCMC). The presented method is tested on an array of academic examples, where some of our theoretical results are numerically verified. These numerical experiments evidence how our extended ML-MCMC method is robust when targeting some pathological posteriors, for which some of the previously proposed ML-MCMC algorithms fail.

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Juan Pablo Madrigal Cianci, Fabio Nobile
MATHICSE, 2021
Rapport ou document de travail

Résumé

Official source

https://infoscience.epfl.ch/record/285467?ln=fr

À propos de ce résultat

Concepts associés (20)

Concepts associés

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Publications associées (17)

Publications associées

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This thesis is devoted to the construction, analysis, and implementation of two types of hierarchical Markov Chain Monte Carlo (MCMC) methods for the solution of large-scale Bayesian Inverse Problems (BIP).The first hierarchical method we present is based on the idea of parallel tempering and is well-suited for BIP whose underlying posterior measure is multi-modal or concentrates around a lower-dimensional, non-linear manifold. In particular, we present two generalizations of the Parallel Tempering algorithm in the context of discrete-time Markov chain Monte Carlo methods for Bayesian inverse problems. These generalizations use state-dependent swapping rates and are inspired by the so-called continuous-time Infinite Swapping algorithm presented in Plattner et al. [J Chem Phys 135(13):134111, 2011]. We present a thorough analysis of the convergence of our proposed methods and show that they are reversible and geometrically ergodic. Numerical experiments conducted over an array of BIP show that our proposed algorithms significantly improve sampling efficiency over competing methodologies. Our second hierarchical method is based on multi-level MCMC (ML-MCMC) techniques. In this setting, instead of sampling directly from a sufficiently accurate (and computationally expensive) posterior measure, one introduces a sequence of accuracy levels for the solution of the underlying computational model, which induces a hierarchy of posterior measures with increasing accuracy and cost to sample from. The key point of this algorithm is to construct highly coupled Markov chains together with the standard Multi-level Monte Carlo argument to obtain a better cost-tolerance complexity than a single-level MCMC algorithm. We present two types of multi-level MCMC algorithms which can be thought of as an extension of the ideas presented in Dodwell, et al. [SIAM-ASA J. Uncertain. Quantif (2015): 1075-1108]. Our first ML-MCMC method extends said ideas to a setting where a wider class of Independent Metropolis-Hastings (IMH) proposals are considered. We provide a thorough theoretical analysis and provide sufficient conditions on the proposals and the family of posteriors so that there exists a unique invariant probability measure for the coupled chains generated by our method, and the convergence to it is uniformly ergodic. We also generalize the cost-tolerance theorem of Dodwell et al., to our setting, and propose a self-tuning continuation-type ML-MCMC algorithm. Our second ML-MCMC method presents an algorithm that admits state-dependent proposals by using a maximal coupling approach. This is desirable, from a methodological perspective, whenever it is difficult to construct suitable IMH proposals, or when the empirical measure resulting from samples from the posterior at the previous level does not satisfy the assumptions required for convergence of the ML-MCMC method. We present a theoretical analysis of the method at hand and show that this new method has an invariant probability measure and converges to it with geometric ergodicity. We also extend the cost-tolerance theorem of Dodwell et. al. to this algorithm, albeit with quite restrictive assumptions. We illustrate both of the proposed ML-MCMC methodologies on several numerical examples.

EPFL2022

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Dynamical low rank approximation for uncertainty quantification of time-dependent problems

Eva Vidlicková

The quantification of uncertainties can be particularly challenging for problems requiring long-time integration as the structure of the random solution might considerably change over time. In this respect, dynamical low-rank approximation (DLRA) is very appealing. It can be seen as a reduced basis method, thus solvable at a relatively low computational cost, in which the solution is expanded as a linear combination of a few deterministic functions with random coefficients. The distinctive feature of the DLRA is that both the deterministic functions and random coefficients are computed on the fly and are free to evolve in time, thus adjusting at each time to the current structure of the random solution. This is achieved by suitably projecting the dynamics onto the tangent space of a manifold consisting of all random functions with a fixed rank. In this thesis, we aim at further analysing and applying the DLR methods to time-dependent problems.Our first work considers the DLRA of random parabolic equations and proposes a class of fully discrete numerical schemes.Similarly to the continuous DLRA, our schemes are shown to satisfy a discrete variational formulation.By exploiting this property, we establish the stability of our schemes: we show that our explicit and semi-implicit versions are conditionally stable under a ``parabolic'' type CFL condition which does not depend on the smallest singular value of the DLR solution; whereas our implicit scheme is unconditionally stable. Moreover, we show that, in certain cases, the semi-implicit scheme can be unconditionally stable if the randomness in the system is sufficiently small. The analysis is supported by numerical results showing the sharpness of the obtained stability conditions. The discrete variational formulation is further applied in our second work, which derives a-priori and a-posteriori error estimates for the discrete DLRA of a random parabolic equation obtained by the three newly-proposed schemes. Under the assumption that the right-hand side of the dynamical system lies in the tangent space up to a small remainder, we show that the solution converges with standard convergence rates w.r.t. the time, spatial, and stochastic discretization parameters, with constants independent of singular values.We follow by presenting a residual-based a-posteriori error estimation for a heat equation with a random forcing term and a random diffusion coefficient which is assumed to depend affinely on a finite number of independent random variables. The a-posteriori error estimate consists of four parts: the finite element method error, the time discretization error, the stochastic collocation error, and the rank truncation error. These estimators are then used to drive an adaptive choice of FE mesh, collocation points, time steps, and time-varying rank.The last part of the thesis examines the idea of applying the DLR method in data assimilation problems, in particular the filtering problem. We propose two new filtering algorithms. They both rely on complementing the DLRA with a Gaussian component. More precisely, the DLR portion captures the non-Gaussian features in an evolving low-dimensional subspace through interacting particles, whereas each particle carries a Gaussian distribution on the whole ambient space. We study the effectiveness of these algorithms on a filtering problem for the Lorenz-96 system.

EPFL2022

Chargement

We present a novel probabilistic finite element method (FEM) for the solution and uncertainty quantification of elliptic partial differential equations based on random meshes, which we call random mesh FEM (RM-FEM). Our methodology allows to introduce a probability measure on classical FEMs to quantify the uncertainty due to numerical errors either in the context of a-posteriori error quantification or for FE based Bayesian inverse problems. The new approach involves only a perturbation of the mesh and an interpolation that are very simple to implement We present a posteriori error estimators and a rigorous a posteriori error analysis based uniquely on probabilistic information for standard piecewise linear FEM. A series of numerical experiments illustrates the potential of the RM-FEM for error estimation and validates our analysis. We furthermore demonstrate how employing the RM-FEM enhances the quality of the solution of Bayesian inverse problems, thus allowing a better quantification of numerical errors in pipelines of computations. (C) 2021 Elsevier B.V. All rights reserved.

ELSEVIER SCIENCE SA2021

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EPFL2022

Dynamical low rank approximation for uncertainty quantification of time-dependent problems

Eva Vidlicková

EPFL2022