TY - GEN
T1 - Advantages of digital holographic microscopy for real-time full field absolute phase imaging
AU - Colomb, Tristan
AU - Charrière, Florian
AU - Kühn, Jonas
AU - Marquet, Pierre
AU - Depeursinge, Christian
PY - 2008
Y1 - 2008
N2 - Different interferometric techniques were developed last decade to obtain full field, quantitative, and absolute phase imaging, such as phase-shifting, Fourier phase microscopy, Hilbert phase microscopy or digital holographic microscopy (DHM). Although, these techniques are very similar, DHM combines several advantages. In contrast, to phase shifting, DHM is indeed capable of single-shot hologram recording allowing a real-time absolute phase imaging. On the other hand, unlike to Fourier phase or Hilbert phase microscopy, DHM does not require to record in focus images of the specimen on the digital detector (CCD or CMOS camera), because a numerical focalization adjustment can be performed by a numerical wavefront propagation. Consequently, the depth of view of high NA microscope objectives is numerically extended. For example, two different biological cells, floating at different depths in a liquid, can be focalized numerically from the same digital hologram. Moreover, the numerical propagation associated to digital optics and automatic fitting procedures, permits vibrations insensitive full-field phase imaging and the complete compensation for a priori any image distortion or/and phase aberrations introduced for example by imperfections of holders or perfusion chamber. Examples of real-time full field phase images of biological cells have been demonstrated.
AB - Different interferometric techniques were developed last decade to obtain full field, quantitative, and absolute phase imaging, such as phase-shifting, Fourier phase microscopy, Hilbert phase microscopy or digital holographic microscopy (DHM). Although, these techniques are very similar, DHM combines several advantages. In contrast, to phase shifting, DHM is indeed capable of single-shot hologram recording allowing a real-time absolute phase imaging. On the other hand, unlike to Fourier phase or Hilbert phase microscopy, DHM does not require to record in focus images of the specimen on the digital detector (CCD or CMOS camera), because a numerical focalization adjustment can be performed by a numerical wavefront propagation. Consequently, the depth of view of high NA microscope objectives is numerically extended. For example, two different biological cells, floating at different depths in a liquid, can be focalized numerically from the same digital hologram. Moreover, the numerical propagation associated to digital optics and automatic fitting procedures, permits vibrations insensitive full-field phase imaging and the complete compensation for a priori any image distortion or/and phase aberrations introduced for example by imperfections of holders or perfusion chamber. Examples of real-time full field phase images of biological cells have been demonstrated.
KW - Aberration compensation
KW - Absolute phase measurement
KW - Digital holography
KW - Microscopy
UR - http://www.scopus.com/inward/record.url?scp=42149155464&partnerID=8YFLogxK
U2 - 10.1117/12.763284
DO - 10.1117/12.763284
M3 - Conference contribution
AN - SCOPUS:42149155464
SN - 9780819470362
T3 - Progress in Biomedical Optics and Imaging - Proceedings of SPIE
BT - Three-Dimensional and Multidimensional Microscopy
T2 - Three-Dimensional and Multidimensional Microscopy: Image Acquisition and Processing XV
Y2 - 21 January 2008 through 24 January 2008
ER -