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dc.contributor.author Choi, K
dc.contributor.author Horisaki, R
dc.contributor.author Hahn, J
dc.contributor.author Lim, S
dc.contributor.author Marks, DL
dc.contributor.author Schulz, TJ
dc.contributor.author Brady, DJ
dc.coverage.spatial United States
dc.date.accessioned 2011-06-21T17:27:38Z
dc.date.issued 2010-12-01
dc.identifier http://www.ncbi.nlm.nih.gov/pubmed/21124522
dc.identifier 202544
dc.identifier.citation Appl Opt, 2010, 49 (34), pp. H1 - 10
dc.identifier.uri http://hdl.handle.net/10161/4203
dc.description.abstract We propose an estimation-theoretic approach to the inference of an incoherent 3D scattering density from 2D scattered speckle field measurements. The object density is derived from the covariance of the speckle field. The inference is performed by a constrained optimization technique inspired by compressive sensing theory. Experimental results demonstrate and verify the performance of our estimates.
dc.format.extent H1 - 10
dc.language ENG
dc.language.iso en_US en_US
dc.relation.ispartof Appl Opt
dc.title Compressive holography of diffuse objects.
dc.title.alternative en_US
dc.type Journal Article
dc.description.version Version of Record en_US
duke.date.pubdate 2010-12-1 en_US
duke.description.endpage H10 en_US
duke.description.issue 34 en_US
duke.description.startpage H1 en_US
duke.description.volume 49 en_US
dc.relation.journal Applied Optics en_US
pubs.author-url http://www.ncbi.nlm.nih.gov/pubmed/21124522
pubs.issue 34
pubs.organisational-group /Duke
pubs.organisational-group /Duke/Pratt School of Engineering
pubs.organisational-group /Duke/Pratt School of Engineering/Electrical and Computer Engineering
pubs.publication-status Published
pubs.volume 49
dc.identifier.eissn 1539-4522

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