Optimal designs for indirect regression
Optimal designs for indirect regression
In many real life applications, it is impossible to observe the feature of interest directly. For example, scientists in Materials Science may be interested in detecting cracks inside objects, not visible from the outside. Similarly, non-invasive medical imaging techniques such as Positrone Emission Tomography rely on indirect observations to reconstruct an image of the patient's internal organs. In this paper, we investigate optimal designs for such indirect regression problems. We determine designs minimizing the integrated mean squared error of estimates of the regression function obtained by Tikhonov or spectral
cut-off regularization. We use the optimal designs as benchmarks to investigate the efficiency of the uniform design commonly used in applications. Several examples are discussed to illustrate the results, in most of which the uniform design or a simple modification thereof is demonstrated to be very efficient for the estimation of the regression function. Our designs provide guidelines to
scientists regarding the experimental conditions at which the indirect observations should be taken in order to obtain an accurate estimate for the object of
interest.
indirect regression, optimal design, uniform design, integrated mean squared error criterion, Tikhonov regularization, spectral cut-off, regularization, radon transform
105003
Biedermann, Stefanie
fe3027d2-13c3-4d9a-bfef-bcc7c6415039
Bissantz, Nicolai
79220ce3-703b-4ca5-96d1-6d56aaa1ed1f
Dette, Holger
8c7b1c2e-3adc-45df-acfc-9e76509a228e
Jones, Edmund
91ea44d9-14f3-4242-9f71-19de2cf84f48
16 September 2011
Biedermann, Stefanie
fe3027d2-13c3-4d9a-bfef-bcc7c6415039
Bissantz, Nicolai
79220ce3-703b-4ca5-96d1-6d56aaa1ed1f
Dette, Holger
8c7b1c2e-3adc-45df-acfc-9e76509a228e
Jones, Edmund
91ea44d9-14f3-4242-9f71-19de2cf84f48
Biedermann, Stefanie, Bissantz, Nicolai, Dette, Holger and Jones, Edmund
(2011)
Optimal designs for indirect regression.
Inverse Problems, 27 (10), .
(doi:10.1088/0266-5611/27/10/105003).
Abstract
In many real life applications, it is impossible to observe the feature of interest directly. For example, scientists in Materials Science may be interested in detecting cracks inside objects, not visible from the outside. Similarly, non-invasive medical imaging techniques such as Positrone Emission Tomography rely on indirect observations to reconstruct an image of the patient's internal organs. In this paper, we investigate optimal designs for such indirect regression problems. We determine designs minimizing the integrated mean squared error of estimates of the regression function obtained by Tikhonov or spectral
cut-off regularization. We use the optimal designs as benchmarks to investigate the efficiency of the uniform design commonly used in applications. Several examples are discussed to illustrate the results, in most of which the uniform design or a simple modification thereof is demonstrated to be very efficient for the estimation of the regression function. Our designs provide guidelines to
scientists regarding the experimental conditions at which the indirect observations should be taken in order to obtain an accurate estimate for the object of
interest.
Text
s3ri-workingpaper-M10-10.pdf
- Author's Original
More information
Published date: 16 September 2011
Keywords:
indirect regression, optimal design, uniform design, integrated mean squared error criterion, Tikhonov regularization, spectral cut-off, regularization, radon transform
Organisations:
Statistics, Southampton Statistical Research Inst.
Identifiers
Local EPrints ID: 163499
URI: http://eprints.soton.ac.uk/id/eprint/163499
ISSN: 0266-5611
PURE UUID: 4571ef9a-1ba5-4bd2-bd80-774edf9798f8
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Date deposited: 09 Sep 2010 09:08
Last modified: 14 Mar 2024 02:51
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Contributors
Author:
Nicolai Bissantz
Author:
Holger Dette
Author:
Edmund Jones
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