LEADER 01982aam  2200493I  450 
001 9910710529303321
005 20160922100247.0
024 8 $aGOVPUB-C13-18e6f8b04c5baea8df583f63c83ce583
035   $a(CKB)5470000002478006
035   $a(OCoLC)958933592
035   $a(EXLCZ)995470000002478006
100   $a20160922d2007      ua             0
101 0 $aeng
181   $2rdacontent
182   $2rdamedia
183   $2rdacarrier
200 10$aThermophysical properties measurements and models for rocket propellant RP-1 $ephase I /$fJoseph W. Magee; Thomas J. Bruno; Daniel G. Friend; Marcia L. Huber; Arno Laesecke; Eric W. Lemmon; Mark O. McLinden; Richard A. Perkins; Jorg Baranski; Jason A. Widegren
210  1$aGaithersburg, MD :$cU.S. Dept. of Commerce, National Institute of Standards and Technology,$d2007.
215   $a1 online resource
225 1 $aNISTIR ;$v6646
300   $a2007.
300   $aContributed record: Metadata reviewed, not verified. Some fields updated by batch processes.
300   $aTitle from PDF title page.
320   $aIncludes bibliographical references.
517   $aThermophysical properties measurements and models for rocket propellant RP-1 
700   $aMagee$b Joseph W$01418538
701   $aBaranski$b Jorg$01418539
701   $aBruno$b Thomas J$076413
701   $aFriend$b Daniel G$g(Daniel Gilbert)$01392175
701   $aHuber$b Marcia L$01394639
701   $aLaesecke$b Arno$01394640
701   $aLemmon$b Eric W$01394641
701   $aMagee$b Joseph W$01418538
701   $aMcLinden$b Mark Owen$01418540
701   $aPerkins$b Robert Allen$01412066
701   $aWidegren$b Jason A$01418541
712 02$aNational Institute of Standards and Technology (U.S.)
801  0$bNBS
801  1$bNBS
801  2$bGPO
906   $aBOOK
912   $a9910710529303321
996   $aThermophysical properties measurements and models for rocket propellant RP-1$93530265
997   $aUNINA

LEADER 03785oam  2200469   450 
001 9910299717703321
005 20190911112726.0
010   $a3-642-38398-X
024 7 $a10.1007/978-3-642-38398-4
035   $a(OCoLC)865652747
035   $a(MiFhGG)GVRL6XBJ
035   $a(EXLCZ)992670000000428490
100   $a20140410d2014      uy             0
101 0 $aeng
135   $aurun|---uuuua
181   $ctxt
182   $cc
183   $acr
200 00$aCompressed sensing & sparse filtering /$fAvishy Y. Carmi, Lyudmila S. Mihaylova, Simon J. Godsill, editors
205   $a1st ed. 2014.
210  1$aHeidelberg, Germany :$cSpringer,$d2014.
215   $a1 online resource (xii, 502 pages) $cillustrations (some color)
225 1 $aSignals and Communication Technology,$x1860-4862
300   $a"ISSN: 1860-4862."
311   $a3-642-38397-1 
320   $aIncludes bibliographical references.
327   $aIntroduction to Compressed Sensing and Sparse Filtering -- The Geometry of Compressed Sensing -- Sparse Signal Recovery with Exponential-Family Noise -- Nuclear Norm Optimization and its Application to Observation Model Specification -- Nonnegative Tensor Decomposition -- Sub-Nyquist Sampling and Compressed Sensing in Cognitive Radio Networks -- Sparse Nonlinear MIMO Filtering and Identification -- Optimization Viewpoint on Kalman Smoothing with Applications to Robust and Sparse Estimation -- Compressive System Identification -- Distributed Approximation and Tracking using Selective Gossip -- Recursive Reconstruction of Sparse Signal Sequences -- Estimation of Time-Varying Sparse Signals in Sensor Networks -- Sparsity and Compressed Sensing in Mono-static and Multi-static Radar Imaging -- Structured Sparse Bayesian Modelling for Audio Restoration -- Sparse Representations for Speech Recognition.
330   $aThis book is aimed at presenting concepts, methods and algorithms ableto cope with undersampled and limited data. One such trend that recently gained popularity and to some extent revolutionised signal processing is compressed sensing. Compressed sensing builds upon the observation that many signals in nature are nearly sparse (or compressible, as they are normally referred to) in some domain, and consequently they can be reconstructed to within high accuracy from far fewer observations than traditionally held to be necessary.  Apart from compressed sensing this book contains other related approaches. Each methodology has its own formalities for dealing with such problems. As an example, in the Bayesian approach, sparseness promoting priors such as Laplace and Cauchy are normally used for penalising improbable model variables, thus promoting low complexity solutions. Compressed sensing techniques and homotopy-type solutions, such as the LASSO, utilise l1-norm penalties for obtaining sparse solutions using fewer observations than conventionally needed. The book emphasizes on the role of sparsity as a machinery for promoting low complexity representations and likewise its connections to variable selection and dimensionality reduction in various engineering problems.  This book is intended for researchers, academics and practitioners with interest in various aspects and applications of sparse signal processing.  .
410  0$aSignals and communication technology.
606   $aSignal processing$xDigital techniques
615  0$aSignal processing$xDigital techniques.
676   $a621.382
676   $a621.3822
702   $aCarmi$b Avishy Y.
702   $aMihaylova$b Lyudmila
702   $aGodsill$b Simon J.$f1965-
801  0$bMiFhGG
801  1$bMiFhGG
906   $aBOOK
912   $a9910299717703321
996   $aCompressed Sensing & Sparse Filtering$91925279
997   $aUNINA