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Optoacoustic image reconstruction and system analysis for finite-aperture detectors under the wavelet-packet framework.
J. Biomed. Opt. 21:16002 (2016)
In optoacoustic tomography, detectors with relatively large areas are often employed to achieve high detection sensitivity. However, spatial-averaging effects over large detector areas may lead to attenuation of high acoustic frequencies and, subsequently, loss of fine features in the reconstructed image. Model-based reconstruction algorithms improve image resolution in such cases by correcting for the effect of the detector's aperture on the detected signals. However, the incorporation of the detector's geometry in the optoacoustic model leads to a significant increase of the model matrix memory cost, which hinders the application of inversion and analysis tools such as singular value decomposition (SVD). We demonstrate the use of the wavelet-packet framework for optoacoustic systems with finite-aperture detectors. The decomposition of the model matrix in the wavelet-packet domain leads to sufficiently smaller model matrices on which SVD may be applied. Using this methodology over an order of magnitude reduction in inversion time is demonstrated for numerically generated and experimental data. Additionally, our framework is demonstrated for the analysis of inversion stability and reveals a new, nonmonotonic dependency of the system condition number on the detector size. Thus, the proposed framework may assist in choosing the optimal detector size in future optoacoustic systems.
Impact Factor
Scopus SNIP
Web of Science
Times Cited
Times Cited
Scopus
Cited By
Cited By
Altmetric
2.556
1.181
10
9
Anmerkungen
Besondere Publikation
Auf Hompepage verbergern
Publikationstyp
Artikel: Journalartikel
Dokumenttyp
Wissenschaftlicher Artikel
Schlagwörter
Inverse Problems ; Optoacoustic Tomography ; Photoacoustic Tomography ; Reconstruction Algorithms ; Regularization ; Wavelet Packet; Photoacoustic Tomography; In-vivo; Regularization; Ultrasound; Inversion
Sprache
Veröffentlichungsjahr
2016
HGF-Berichtsjahr
2016
ISSN (print) / ISBN
1083-3668
e-ISSN
1560-2281
Zeitschrift
Journal of Biomedical Optics
Quellenangaben
Band: 21,
Heft: 1,
Artikelnummer: 16002
Verlag
SPIE
Verlagsort
Bellingham
Begutachtungsstatus
Peer reviewed
POF Topic(s)
30205 - Bioengineering and Digital Health
Forschungsfeld(er)
Enabling and Novel Technologies
PSP-Element(e)
G-505500-001
WOS ID
WOS:000380036500016
Scopus ID
84954174088
PubMed ID
26747476
Erfassungsdatum
2016-01-11