SEARCH

SEARCH BY CITATION

References

  • 1
    Allen, R.D., David, G.B., Nomarski, G. (1969) The Zeiss–Nomarski differential interference equipment for transmitted light microscopy. Z. Wiss. Mikrosk. 69, 193 221.
  • 2
    Barer, R. (1952) Interference microscopy and mass determination. Nature, 169, 366 367.
  • 3
    Barer, R. & Smith, F. (1972) Microscope for weighing bits of cells. New Scientist, 24, 380 383.
  • 4
    Cogswell, C.J. & Sheppard, C.J.R. (1992) Confocal differential interference contrast (DIC) microscopy: including a theoretical analysis of conventional and confocal dic imaging. J. Microsc. 165, 81 101.
  • 5
    Davies, H.G. & Wilkins, M.H.F. (1952) Interference microscopy and mass determination. Nature, 169, 541.
  • 6
    Ellenberger, S.L. & Young, I.T. (1997) Measurement-based depth-of-focus. SPIE Proc. 2982, 476 484.
  • 7
    Van Munster, E.B., Van Vliet, L.J., Aten, J.A. (1997) Reconstruction of optical pathlength distributions from images obtained by a wide-field differential interference contrast microscope. J. Microsc. 188, 149 157.
  • 8
    Padawer, J. (1968) The Nomarski interference microscope: an experimental basis for image interpretation. J. R. Microsc. Soc. 88, 305 349.
  • 9
    Preza, C., Van Munster, E.B., Aten, J.A., Snyder, D.L., Rosenberger, F.U. (1998) Determination of direction-independent optical pathlength distribution of cells using rotational-diversity transmitted light DIC images. SPIE Proc. 3261, in press.
  • 10
    Preza, C., Snyder, D.L., Conchello, J. (1997) Image reconstruction for three-dimensional transmitted-light DIC microscopy. SPIE Proc. 2984, 220 231.
  • 11
    Spiegel, M.R. (1968) Mathematical Handbook. McGraw-Hill, New York.
  • 12
    Svensson, G. (1957)A scanning interference microphotometer. Exp. Cell Res. 12, 406 409.