Discovering Planetary Nebula Geometries: Explorations with a Hierarchy of Models
Discovering Planetary Nebula Geometries: Explorations with a Hierarchy of Models
Astronomical objects known as planetary nebulae (PNe) consist of a shell of gas expelled by an aging star. In cases where the gas shell can be assumed to be ellipsoidal, the PN can be easily modeled in three spatial dimensions. We utilize a model that joins the physics of PNe to this geometry and generates simulated nebular images. Hubble Space Telescope images of actual PNe provide data with which the model images may be compared. We employ Bayesian model estimation and search the parameter space for values that generate a match between observed and model images. The forward model is characterized by thirteen parameters; consequently model estimation requires the search of a 13-dimensional parameter space. The 'curse of dimensionality,' compounded by a computationally intense forward problem, makes forward searches extremely time-consuming and frequently causes them to become trapped in a local solution. We find that both the speed and quality of the search can be improved by reducing the dimensionality of the search space. Our basic approach utilizes a hierarchy of models of increasing complexity. Earlier studies establish that a hierarchical sequence converges more quickly, and to a better solution, than a search relying only on the most complex model. Here we report results for a hierarchy of five models. The first three models treat the nebula as a 2D image, estimating its position, angular size, orientation and rim thickness. The last two models explore its characteristics as a 3D object and enable us to characterize the physics of the nebula. This five-model hierarchy is applied to real ellipsoidal PNe to estimate their geometric properties and gas density profiles.
135-142
Huyser, Karen A.
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Knuth, Kevin H.
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Fischer, Bernd
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Schumann, Johann
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Granquist-Fraser, Domhnull
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Hajian, Arsen R.
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Fischer, R.
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Dose, V.
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2004
Huyser, Karen A.
06489f1a-e560-4463-8f04-daa09cddf370
Knuth, Kevin H.
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Fischer, Bernd
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Schumann, Johann
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Granquist-Fraser, Domhnull
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Hajian, Arsen R.
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Fischer, R.
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Dose, V.
3f5c26c3-a229-435c-9260-faf10ed1e361
Huyser, Karen A., Knuth, Kevin H., Fischer, Bernd, Schumann, Johann, Granquist-Fraser, Domhnull and Hajian, Arsen R.
(2004)
Discovering Planetary Nebula Geometries: Explorations with a Hierarchy of Models.
Fischer, R. and Dose, V.
(eds.)
Twentyfourth International Workshop on Bayesian Inference and Maximum Entropy Methods in Science and Engineering, Garching bei München, Germany.
25 - 30 Jul 2004.
.
Record type:
Conference or Workshop Item
(Paper)
Abstract
Astronomical objects known as planetary nebulae (PNe) consist of a shell of gas expelled by an aging star. In cases where the gas shell can be assumed to be ellipsoidal, the PN can be easily modeled in three spatial dimensions. We utilize a model that joins the physics of PNe to this geometry and generates simulated nebular images. Hubble Space Telescope images of actual PNe provide data with which the model images may be compared. We employ Bayesian model estimation and search the parameter space for values that generate a match between observed and model images. The forward model is characterized by thirteen parameters; consequently model estimation requires the search of a 13-dimensional parameter space. The 'curse of dimensionality,' compounded by a computationally intense forward problem, makes forward searches extremely time-consuming and frequently causes them to become trapped in a local solution. We find that both the speed and quality of the search can be improved by reducing the dimensionality of the search space. Our basic approach utilizes a hierarchy of models of increasing complexity. Earlier studies establish that a hierarchical sequence converges more quickly, and to a better solution, than a search relying only on the most complex model. Here we report results for a hierarchy of five models. The first three models treat the nebula as a 2D image, estimating its position, angular size, orientation and rim thickness. The last two models explore its characteristics as a 3D object and enable us to characterize the physics of the nebula. This five-model hierarchy is applied to real ellipsoidal PNe to estimate their geometric properties and gas density profiles.
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Published date: 2004
Additional Information:
Event Dates: July 25-30, 2004
Venue - Dates:
Twentyfourth International Workshop on Bayesian Inference and Maximum Entropy Methods in Science and Engineering, Garching bei München, Germany, 2004-07-25 - 2004-07-30
Organisations:
Electronic & Software Systems
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Local EPrints ID: 262937
URI: http://eprints.soton.ac.uk/id/eprint/262937
PURE UUID: 58b3ebd7-e94f-4edc-9b42-354267405a1b
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Date deposited: 02 Sep 2006
Last modified: 14 Mar 2024 07:21
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Contributors
Author:
Karen A. Huyser
Author:
Kevin H. Knuth
Author:
Bernd Fischer
Author:
Johann Schumann
Author:
Domhnull Granquist-Fraser
Author:
Arsen R. Hajian
Editor:
R. Fischer
Editor:
V. Dose
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