Bayesian Experimental Design of Magnetic Resonance Imaging Sequences
We show how improved sequences for magnetic resonance imaging can be found through automated optimization of Bayesian design scores. Combining recent advances in approximate Bayesian inference and natural image statistics with high-performance numerical computation, we propose the first scalable Bayesian experimental design framework for this problem of high relevance to clinical and brain research. Our solution requires approximate inference for dense, non-Gaussian models on a scale seldom addressed before. We propose a novel scalable variational inference algorithm, and show how powerful methods of numerical mathematics can be modified to compute primitives in our framework. Our approach is evaluated on a realistic setup with raw data from a 3T MR scanner.
| Author(s): | Seeger, MW. and Nickisch, H. and Pohmann, R. and Schölkopf, B. |
| Book Title: | Advances in neural information processing systems 21 |
| Journal: | Advances in neural information processing systems 21 : 22nd Annual Conference on Neural Information Processing Systems 2008 |
| Pages: | 1441-1448 |
| Year: | 2009 |
| Month: | June |
| Day: | 0 |
| Editors: | D Koller and D Schuurmans and Y Bengio and L Bottou |
| Publisher: | Curran |
| Bibtex Type: | Conference Paper (inproceedings) |
| Address: | Red Hook, NY, USA |
| Event Name: | 22nd Annual Conference on Neural Information Processing Systems (NIPS 2008) |
| Event Place: | Vancouver, BC, Canada |
| Digital: | 0 |
| Electronic Archiving: | grant_archive |
| ISBN: | 978-1-605-60949-2 |
| Language: | en |
| Organization: | Max-Planck-Gesellschaft |
| School: | Biologische Kybernetik |
| Links: | |
BibTex
@inproceedings{5392,
title = {Bayesian Experimental Design of Magnetic Resonance Imaging Sequences},
journal = {Advances in neural information processing systems 21 : 22nd Annual Conference on Neural Information Processing Systems 2008},
booktitle = {Advances in neural information processing systems 21},
abstract = {We show how improved sequences for magnetic resonance imaging can be found through automated optimization of Bayesian design scores. Combining recent advances in approximate Bayesian inference and natural image statistics with high-performance numerical computation, we propose the first scalable Bayesian experimental design framework for this problem of high relevance to clinical and brain research. Our solution requires approximate inference for dense, non-Gaussian models on a scale seldom addressed before. We propose a novel scalable variational inference algorithm, and show how powerful methods of numerical mathematics can be modified to compute primitives in our framework. Our approach is evaluated on a realistic setup with raw data from a 3T MR scanner.},
pages = {1441-1448},
editors = {D Koller and D Schuurmans and Y Bengio and L Bottou},
publisher = {Curran},
organization = {Max-Planck-Gesellschaft},
school = {Biologische Kybernetik},
address = {Red Hook, NY, USA},
month = jun,
year = {2009},
slug = {5392},
author = {Seeger, MW. and Nickisch, H. and Pohmann, R. and Sch{\"o}lkopf, B.},
month_numeric = {6}
}