CQFD - 2018 - Annual activity report

CQFD

CQFD - 2018

Project-Team Cqfd

Team, Visitors, External Collaborators

Overall Objectives

Presentation

Research Program

Application Domains

Dependability and safety

New Software and Platforms

New Results

A new characterization of the jump rate for piecewise-deterministic Markov processes with discrete transitions
Estimation of the average number of continuous crossings for non-stationary non-diffusion processes
ClustGeo: an R package for hierarchical clustering with spatial constraints
Change-point detection for Piecewise Deterministic Markov Processes
A sharp first order analysis of Feynman–Kac particle models, Part I: Propagation of chaos
A sharp first order analysis of Feynman–Kac particle models, Part II: Particle Gibbs samplers
Exponential mixing properties for time inhomogeneous diffusion processes with killing
Investigation of asymmetry in E. coli growth rate
Design of estimators for restoration of images degraded by haze using genetic programming
Controlling IL-7 injections in HIV-infected patients
Stochastic Control of Observer Trajectories in Passive Tracking with Acoustic Signal Propagation Optimization
Computable approximations for average Markov decision processes in continuous time
Zero-Sum Discounted Reward Criterion Games for Piecewise Deterministic Markov Processes
Approximation of discounted minimax Markov control problems and zero-sum Markov games using Hausdorff and Wasserstein distances
On the expected total cost with unbounded returns for Markov decision processes
Applying Genetic Improvement to a Genetic Programming library in C++

Bilateral Contracts and Grants with Industry

Bilateral Contracts with Industry

Partnerships and Cooperations

Dissemination

Bibliography

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Section: New Results

A sharp first order analysis of Feynman–Kac particle models, Part I: Propagation of chaos

This article provides a new theory for the analysis of forward and backward particle approximations of Feynman–Kac models. Such formulae are found in a wide variety of applications and their numerical (particle) approximation is required due to their intractability. Under mild assumptions, we provide sharp and non-asymptotic first order expansions of these particle methods, potentially on path space and for possibly unbounded functions. These expansions allow one to consider upper and lower bound bias type estimates for a given time horizon $n$ and particle number $N$ ; these non-asymptotic estimates are $O (n ∕ N)$ . Our approach is extended to tensor products of particle density profiles, leading to new sharp and non-asymptotic propagation of chaos estimates. The resulting upper and lower bound propagations of chaos estimates seem to be the first result of this kind for mean field particle models.

Authors: Pierre Del Moral (Inria CQFD) and Ajay Jasrab.

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