000 | a | ||
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999 |
_c30255 _d30255 |
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008 | 210616b xxu||||| |||| 00| 0 eng d | ||
020 | _a9780817683726 | ||
082 |
_a515.63 _bCAS |
||
100 | _aCasazza, Peter G. ed. | ||
245 | _aFinite frames : theory and applications | ||
260 |
_bBirkhauser, _c2013 _aBoston : |
||
300 |
_axvi, 483 p. ; _bill., _c25 cm |
||
365 |
_b139.99 _cEUR _d92.90 |
||
490 | _aApplied and numerical harmonic analysis | ||
504 | _aIncludes bibliographical references and index. | ||
520 | _aHilbert space frames have long served as a valuable tool for signal and image processing due to their resilience to additive noise, quantization, and erasures, as well as their ability to capture valuable signal characteristics. More recently, finite frame theory has grown into an important research topic in its own right, with a myriad of applications to pure and applied mathematics, engineering, computer science, and other areas. The number of research publications, conferences, and workshops on this topic has increased dramatically over the past few years, but no survey paper or monograph has yet appeared on the subject. Edited by two of the leading experts in the field, Finite Frames aims to fill this void in the literature by providing a comprehensive, systematic study of finite frame theory and applications. With carefully selected contributions written by highly experienced researchers, it covers topics including: Finite Frame Constructions; Optimal Erasure Resilient Frames; Quantization of Finite Frames; Finite Frames and Compressed Sensing; Group and Gabor Frames; Fusion Frames. | ||
650 | _aMathematics | ||
650 | _aFourier analysis | ||
650 | _aComputer vision | ||
650 | _aOperator theory | ||
650 | _aFinite element method | ||
650 | _aStructural frames | ||
650 | _aVector analysis | ||
710 | _aKutyniok, Gitta ed. | ||
942 |
_2ddc _cBK |