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001 on1105928331
003 OCoLC
005 20241121072751.0
006 m d
007 cr cnu---unuuu
008 190627s2019 enka ob 001 0 eng d
040 _aN$T
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020 _a9781316403938
_qelectronic book
020 _a1316403939
_qelectronic book
020 _a9781108696616
_qelectronic book
020 _a1108696619
_qelectronic book
020 _z9781107124127
_qhardcover
020 _z1107124123
_qhardcover
035 _a2112104
_b(N$T)
035 _a(OCoLC)1105928331
050 4 _aRE79.I42
_bW38 2019
060 1 4 _aWN 195
072 7 _aHEA
_x039000
_2bisacsh
072 7 _aMED
_x014000
_2bisacsh
072 7 _aMED
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072 7 _aMED
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072 7 _aMED
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082 0 4 _a616.07/545
_223
049 _aMAIN
245 0 0 _aWavefront shaping for biomedical imaging /
_cedited by Joel Kubby, Sylvain Gigan, Meng Cui.
264 1 _aCambridge, United Kingdom ;
_aNew York, NY :
_bCambridge University Press,
_c[2019]
300 _a1 online resource :
_billustrations.
336 _atext
_btxt
_2rdacontent
337 _acomputer
_bc
_2rdamedia
338 _aonline resource
_bcr
_2rdacarrier
490 1 _aAdvances in microscopy and microanalysis
504 _aIncludes bibliographical references and index.
505 8 _aMachine generated contents note: Part I. Adaptive Optical Microscopy for Biological Imaging: 1. Adaptive optical microscopy using image-based wavefront sensing Jacopo Antonello, D�ebora M. Andrade and Martin J. Booth; 2. Adaptive optical microscopy using guide-star based direct wavefront sensing Xiaodong Tao, Oscar Azucena and Joel Kubby; Part II. Deep Tissue Microscopy: 3. Deep tissue fluorescence microscopy Meng Cui; 4. Zonal adaptive optical microscopy for deep tissue imaging Cristina Rodr�iguez and Na Ji; Part III. Focusing Light through Turbid Media using the Scattering Matrix: 5. Transmission matrix approach to light control in complex media Sylvain Gigan; 6. Coupling optical wavefront shaping and photoacoustics Emmanuel Bossy; 7. Imaging and controlling light propagation deep within scattering media using time-resolved reflection matrix Youngwoon Choi, Sungsam Kang and Wonshik Choi; Part IV. Focusing Light through Turbid Media using Feedback Optimization: 8. Feedback-based wavefront shaping Ivo M. Vellekoop; 9. Focusing light through scattering media using a micro-electro-mechanical systems spatial light modulator Yang Lu and Hari P. Paudel; 10. Computer-generated holographic techniques to control light propagating through scattering media using a digital-mirror-device spatial light modulator Antonio M. Caravaca-Aguirre and Rafael Piestun; 11. Transmission matrix correlations Roarke Horstmeyer, Ivo M. Vellekoop and Benjamin Judkewitz; Part V. Time Reversal, Optical Phase Conjugation: 12. Reflection matrix approaches in scattering media: from detection to imaging Amaury Badon, Alexandre Aubry and Mathias Fink; 13. Wavefront-engineered optical focusing into scattering media using ultrasound- or perturbation-based guide stars: TRUE, TRAP, SEWS, and PAWS Xiao Xu, Cheng Ma, Puxiang Lai and Lihong V. Wang; Part VI. Shaped Beams for Light Sheet Microscopy: 14. Light-sheet microscopy with wavefront shaped beams: looking deeper into objects and increasing image contrast Alexander Rohrbach; 15. Shaped beams for light sheet imaging and optical manipulation Tom Vettenburg and Kishan Dholakia; Part VII. Tomography: 16. Incoherent illumination tomography and adaptive optics Peng Xiao, Mathias Fink and A. Claude Boccara; 17. Computational adaptive optics for broadband optical interferometric tomography of biological tissue Nathan D. Shemonski, Yuan-Zhi Liu, Fredrick A. South and Stephen A. Boppart.
520 _a"The most common approach to adaptive optics (AO), as originally employed in astronomical telescopes, has been to use a wavefront sensor to measure directly aberrations. In situations where such sensing provides reliable measurement, this is clearly the ideal method (see Chapter 2), but this approach has limitations, and particularly so in the context of microscopy. In order to understand this, one should consider the constraints the use of a wavefront sensor places on the nature of the optical conguration. A wavefront is only well de ned in particular situations, for example when light is emitted by a small or distant, point-like object, such as a star for a telescope or a minuscule bead in a microscope. In these situations, a wavefront sensor provides a clear and reliable measurement and this phenomenon has been used to great effect, as explained in Chapter 2. However, not all sources of light have these necessary properties. For example, a large luminous object comprises an arrangement of individual emitters, each of which produces its associated wavefront. In this case, a wavefront sensor would respond to all of the light impinging upon it, thus giving potentially ambiguous measurements. In an extreme case, such as where light is emitted throughout the volume of the specimen, the sensor would be swamped with light and thus be un-able to provide sensible aberration measurement. For this reason, in microscopy, direct wavefront sensing has been e ective where point-like sources have been employed, either through the introduction of uorescent beads [1, 2], or using localised uorescent markers [3] and non-linear excited guide stars [4, 5, 6]"--Provided by publisher.
588 _aDescription based on online resource; title from digital title page (viewed on July 10, 2019).
590 _aMaster record variable field(s) change: 050
650 0 _aOptical images.
_911858
650 0 _aMicroscopy
_xMethods.
_911859
650 0 _aLight.
_911860
650 0 _aImage analysis
_xData processing.
_911861
650 0 _aElectron microscopy.
_911862
650 1 2 _aOptical Imaging.
_911863
650 2 2 _aMicroscopy
_xmethods.
_911864
650 2 2 _aLight.
_911860
650 2 2 _aImage Interpretation, Computer-Assisted
_xmethods.
_911865
650 7 _aHEALTH & FITNESS / Diseases / General
_2bisacsh
650 7 _aMEDICAL / Clinical Medicine
_2bisacsh
650 7 _aMEDICAL / Diseases
_2bisacsh
650 7 _aMEDICAL / Evidence-Based Medicine
_2bisacsh
650 7 _aMEDICAL / Internal Medicine
_2bisacsh
655 4 _aElectronic books.
_93907
700 1 _aKubby, Joel A.,
_eeditor.
_911866
700 1 _aGigan, Sylvain,
_eeditor.
_911867
700 1 _aCui, Meng,
_eeditor.
_911868
776 0 8 _iPrint version:
_tWavefront shaping for biomedical imaging.
_dCambridge, United Kingdom ; New York, NY : Cambridge University Press, 2019
_z9781107124127
_w(DLC) 2018057968
_w(OCoLC)1078161165
830 0 _aAdvances in microscopy and microanalysis.
_911869
856 4 0 _3EBSCOhost
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