6533b82efe1ef96bd1293c7d
RESEARCH PRODUCT
Compressed Particle Methods for Expensive Models With Application in Astronomy and Remote Sensing
Gustau Camps-vallsJavier López-santiagoLuca MartinoVictor Elvirasubject
FOS: Computer and information sciencesComputer scienceAstronomyModel selectionBayesian inferenceMonte Carlo methodBayesian probabilityAerospace EngineeringAstronomyInferenceMachine Learning (stat.ML)Context (language use)Bayesian inferenceStatistics - ComputationComputational Engineering Finance and Science (cs.CE)remote sensingimportance samplingStatistics - Machine Learningnumerical inversionparticle filteringElectrical and Electronic EngineeringUncertainty quantificationApproximate Bayesian computationComputer Science - Computational Engineering Finance and ScienceComputation (stat.CO)description
In many inference problems, the evaluation of complex and costly models is often required. In this context, Bayesian methods have become very popular in several fields over the last years, in order to obtain parameter inversion, model selection or uncertainty quantification. Bayesian inference requires the approximation of complicated integrals involving (often costly) posterior distributions. Generally, this approximation is obtained by means of Monte Carlo (MC) methods. In order to reduce the computational cost of the corresponding technique, surrogate models (also called emulators) are often employed. Another alternative approach is the so-called Approximate Bayesian Computation (ABC) scheme. ABC does not require the evaluation of the costly model but the ability to simulate artificial data according to that model. Moreover, in ABC, the choice of a suitable distance between real and artificial data is also required. In this work, we introduce a novel approach where the expensive model is evaluated only in some well-chosen samples. The selection of these nodes is based on the so-called compressed Monte Carlo (CMC) scheme. We provide theoretical results supporting the novel algorithms and give empirical evidence of the performance of the proposed method in several numerical experiments. Two of them are real-world applications in astronomy and satellite remote sensing.
| year | journal | country | edition | language |
|---|---|---|---|---|
| 2021-01-01 | IEEE Transactions on Aerospace and Electronic Systems |