Bayesclumpy: Bayesian Inference with Clumpy Dusty Torus Models

Bayesclumpy: Bayesian Inference with Clumpy Dusty Torus Models

Our aim is to present a fast and general Bayesian inference framework based on the synergy between machine learning techniques and standard sampling methods and apply it to infer the physical properties of clumpy dusty torus using infrared photometric high spatial resolution observations of active g...

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Bibliographic Details
Published in:The Astrophysical journal Vol. 696; no. 2; pp. 2075 - 2085
Main Authors: Asensio Ramos, A, Ramos Almeida, C
Format: Journal Article
Language:English
Published: Bristol IOP Publishing 10-05-2009
IOP
Subjects:
Astronomy
Earth, ocean, space
Exact sciences and technology
Data analysis
galaxies: Seyfert
infrared: galaxies
methods: data analysis
Statistical method
Seyfert galaxies
methods: statistical
Tori
Galaxy nuclei
Infrared galaxies
Models
Bayes methods
galaxies: nuclei
Online Access:Get full text
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Summary:Our aim is to present a fast and general Bayesian inference framework based on the synergy between machine learning techniques and standard sampling methods and apply it to infer the physical properties of clumpy dusty torus using infrared photometric high spatial resolution observations of active galactic nuclei. We make use of the Metropolis-Hastings Markov Chain Monte Carlo algorithm for sampling the posterior distribution function. Such distribution results from combining all a priori knowledge about the parameters of the model and the information introduced by the observations. The main difficulty resides in the fact that the model used to explain the observations is computationally demanding and the sampling is very time consuming. For this reason, we apply a set of artificial neural networks that are used to approximate and interpolate a database of models. As a consequence, models not present in the original database can be computed ensuring continuity. We focus on the application of this solution scheme to the recently developed public database of clumpy dusty torus models. The machine learning scheme used in this paper allows us to generate any model from the database using only a factor of 10-4 of the original size of the database and a factor of 10-3 in computing time. The posterior distribution obtained for each model parameter allows us to investigate how the observations constrain the parameters and which ones remain partially or completely undetermined, providing statistically relevant confidence intervals. As an example, the application to the nuclear region of Centaurus A shows that the optical depth of the clouds, the total number of clouds, and the radial extent of the cloud distribution zone are well constrained using only six filters. The code is freely available from the authors.
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ISSN:0004-637X
1538-4357
DOI:10.1088/0004-637X/696/2/2075