research-article

Compressed sensing and Bayesian experimental design

Authors:

Matthias W. Seeger,

Hannes NickischAuthors Info & Claims

ICML '08: Proceedings of the 25th international conference on Machine learning

Pages 912 - 919

https://doi.org/10.1145/1390156.1390271

Published: 05 July 2008 Publication History

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Abstract

We relate compressed sensing (CS) with Bayesian experimental design and provide a novel efficient approximate method for the latter, based on expectation propagation. In a large comparative study about linearly measuring natural images, we show that the simple standard heuristic of measuring wavelet coefficients top-down systematically outperforms CS methods using random measurements; the sequential projection optimisation approach of (Ji & Carin, 2007) performs even worse. We also show that our own approximate Bayesian method is able to learn measurement filters on full images efficiently which outperform the wavelet heuristic. To our knowledge, ours is the first successful attempt at "learning compressed sensing" for images of realistic size. In contrast to common CS methods, our framework is not restricted to sparse signals, but can readily be applied to other notions of signal complexity or noise models. We give concrete ideas how our method can be scaled up to large signal representations.

References

[1]

Candès, E., & Romberg, J. (2004). Practical signal recovery from random projections. Proceedings of SPIE.

Google Scholar

[2]

Candès, E., Romberg, J., & Tao, T. (2006). Robust uncertainty principles: Exact signal reconstruction from highly incomplete frequency information. IEEE Trans. Inf. Theo., 52, 489--509.

Digital Library

Google Scholar

[3]

Donoho, D. (2006). Compressed sensing. IEEE Trans. Inf. Theo., 52, 1289--1306.

Digital Library

Google Scholar

[4]

Duarte, M., Davenport, M., Takhar, D., Laska, J., Sun, T., Kelly, K., & Baraniuk, R. (2008). Single pixel imaging via compressive sampling. To appear in IEEE Signal Processing Magazine.

Google Scholar

[5]

Elad, M. (2007). Optimized projections for compressed sensing. IEEE Transactions on Signal Processing.

Digital Library

Google Scholar

[6]

Gerwinn, S., Macke, J., Seeger, M., & Bethge, M. (2008). Bayesian inference for spiking neuron models with a sparsity prior. Advances in NIPS 20.

Google Scholar

[7]

Ji, S., & Carin, L. (2007). Bayesian compressive sensing and projection optimization. Proceedings of ICML 24.

Digital Library

Google Scholar

[8]

Minka, T. (2001). Expectation propagation for approximate Bayesian inference. Uncertainty in AI 17.

Digital Library

Google Scholar

[9]

Seeger, M. (2008). Bayesian inference and optimal design in the sparse linear model. To appear in Journal of Machine Learning Research.

Digital Library

Google Scholar

[10]

Seeger, M., Steinke, F., & Tsuda, K. (2007). Bayesian inference and optimal design in the sparse linear model. AI and Statistics 11.

Google Scholar

[11]

Simoncelli, E. (1999). Modeling the joint statistics of images in the Wavelet domain. Proceedings 44th SPIE (pp. 188--195).

Google Scholar

[12]

Tipping, M. (2001). Sparse Bayesian learning and the relevance vector machine. J. M. Learn. Res., 1, 211--244.

Digital Library

Google Scholar

[13]

Weiss, Y., Chang, H., & Freeman, W. (2007). Learning compressed sensing. Snowbird Learning Workshop, Allerton, CA.

Google Scholar

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Chen WZhang LXing XWen XZhang Q(2024)Sub-Nyquist SAR Imaging and Error Correction Via an Optimization-Based AlgorithmSensors10.3390/s2409284024:9(2840)Online publication date: 29-Apr-2024
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Chen WGeng JMeng FZhang L(2024)Pseudo-L0-Norm Fast Iterative Shrinkage Algorithm Network: Agile Synthetic Aperture Radar Imaging via Deep Unfolding NetworkRemote Sensing10.3390/rs1604067116:4(671)Online publication date: 13-Feb-2024
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Index Terms

Compressed sensing and Bayesian experimental design
1. Computing methodologies

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Information & Contributors

Information

Published In

ICML '08: Proceedings of the 25th international conference on Machine learning

July 2008

1310 pages

ISBN:9781605582054

DOI:10.1145/1390156

General Chair:
William Cohen
Carnegie Mellon University
,
Program Chairs:
Andrew McCallum
University of Massachusetts Amherst
,
Sam Roweis
University of Toronto and Google

Permission to make digital or hard copies of all or part of this work for personal or classroom use is granted without fee provided that copies are not made or distributed for profit or commercial advantage and that copies bear this notice and the full citation on the first page. Copyrights for components of this work owned by others than ACM must be honored. Abstracting with credit is permitted. To copy otherwise, or republish, to post on servers or to redistribute to lists, requires prior specific permission and/or a fee. Request permissions from [email protected]

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Association for Computing Machinery

New York, NY, United States

Publication History

Published: 05 July 2008

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Research-article

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ICML '08

Sponsor:

Microsoft Research
Intel
IBM

ICML '08: The 25th Annual International Conference on Machine Learning held in conjunction with the 2007 International Conference on Inductive Logic Programming

July 5 - 9, 2008

Helsinki, Finland

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Overall Acceptance Rate 140 of 548 submissions, 26%

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Cited By

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Chen WZhang LXing XWen XZhang Q(2024)Sub-Nyquist SAR Imaging and Error Correction Via an Optimization-Based AlgorithmSensors10.3390/s2409284024:9(2840)Online publication date: 29-Apr-2024
https://doi.org/10.3390/s24092840
Chen WGeng JMeng FZhang L(2024)Pseudo-L0-Norm Fast Iterative Shrinkage Algorithm Network: Agile Synthetic Aperture Radar Imaging via Deep Unfolding NetworkRemote Sensing10.3390/rs1604067116:4(671)Online publication date: 13-Feb-2024
https://doi.org/10.3390/rs16040671
Jin WLyu WChen YGuo QDeng ZXu W(2024)Efficient Sparse Bayesian Learning Model for Image Reconstruction Based on Laplacian Hierarchical Priors and GAMPElectronics10.3390/electronics1315303813:15(3038)Online publication date: 1-Aug-2024
https://doi.org/10.3390/electronics13153038
Jha AAshwood ZPillow J(2024)Active Learning for Discrete Latent Variable ModelsNeural Computation10.1162/neco_a_0164636:3(437-474)Online publication date: 16-Feb-2024
https://doi.org/10.1162/neco_a_01646
Shan HWu QLi CZhang L(2024)Sparse Overcomplete Representation Fault Location Model in Distribution Networks and Efficient Solution Using FastLaplace BayesianIEEE Transactions on Instrumentation and Measurement10.1109/TIM.2024.338130273(1-11)Online publication date: 2024
https://doi.org/10.1109/TIM.2024.3381302
Wang ZSun SLi YYue ZDing Y(2023)Distributed Compressive Sensing for Wireless Signal Transmission in Structural Health Monitoring: An Adaptive Hierarchical Bayesian Model-Based ApproachSensors10.3390/s2312566123:12(5661)Online publication date: 17-Jun-2023
https://doi.org/10.3390/s23125661
Courcoux-Caro MVanwynsberghe CHerzet CBaussard A(2022)Sequential sensor selection for the localization of acoustic sources by sparse Bayesian learningThe Journal of the Acoustical Society of America10.1121/10.0014001152:3(1695-1708)Online publication date: 19-Sep-2022
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Zhang YQi XJiang YLi HLiu Z(2022)Image Reconstruction for Low-Oversampled Staggered SAR Based on Sparsity Bayesian Learning in the Presence of a Nonlinear PRI Variation StrategyIEEE Transactions on Geoscience and Remote Sensing10.1109/TGRS.2022.318344160(1-24)Online publication date: 2022
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