Abstract

This paper discusses the features of determining the coordinates of biological particles when digital holographic video is used. Experimental results are presented that show that it is possible to take into account rotational motion of a particle. The possibility of refining the coordinates of a particle by using a two-aspect holographic layout is experimentally investigated, taking into account the influence of the water–glass–air optical system.

© 2012 OSA

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  1. V. V. Demin and S. G. Stepanov, “Holographic studies of transparent microparticles,” Optika Atmos. Okeana 11, 671 (1998).
  2. D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.
  3. H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
    [CrossRef]
  4. V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).
  5. V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).
  6. V. V. Dyomin, J. Watson, and P. W. Benzie, “Reducing the aberrations of holographic images of underwater particles by using the off-axis scheme with normal incidence of object beam,” in Conf. Proc., Oceans’07, 2007, paper 070131-036.

2010 (1)

V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).

2008 (1)

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

2007 (1)

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

1998 (1)

V. V. Demin and S. G. Stepanov, “Holographic studies of transparent microparticles,” Optika Atmos. Okeana 11, 671 (1998).

Benzie, P. W.

V. V. Dyomin, J. Watson, and P. W. Benzie, “Reducing the aberrations of holographic images of underwater particles by using the off-axis scheme with normal incidence of object beam,” in Conf. Proc., Oceans’07, 2007, paper 070131-036.

Demin, V. V.

V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

V. V. Demin and S. G. Stepanov, “Holographic studies of transparent microparticles,” Optika Atmos. Okeana 11, 671 (1998).

Dyomin, V. V.

V. V. Dyomin, J. Watson, and P. W. Benzie, “Reducing the aberrations of holographic images of underwater particles by using the off-axis scheme with normal incidence of object beam,” in Conf. Proc., Oceans’07, 2007, paper 070131-036.

Dzyuba, E. V.

V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).

Hendry, D. C.

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

Katz, J.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

King, S. R.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

Malkiel, E.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

Mel’nik, N. G.

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

Naumova, E. Yu.

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

Ol’shukov, A. S.

V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

Pfitsch, D. W.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

Player, M. A.

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

Ronzhes, Y.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

Sheng, J.

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

Stepanov, S. G.

V. V. Demin and S. G. Stepanov, “Holographic studies of transparent microparticles,” Optika Atmos. Okeana 11, 671 (1998).

Sun, H.

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

Watson, J.

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

V. V. Dyomin, J. Watson, and P. W. Benzie, “Reducing the aberrations of holographic images of underwater particles by using the off-axis scheme with normal incidence of object beam,” in Conf. Proc., Oceans’07, 2007, paper 070131-036.

IEEE J. Ocean. Eng. (1)

H. Sun, D. C. Hendry, M. A. Player, and J. Watson, “In situ underwater electronic holographic camera for studies of plankton,” IEEE J. Ocean. Eng. 32, 373 (2007).
[CrossRef]

Izv. Vyssh. Uchebn. Zaved. Fiz. (1)

V. V. Demin, A. S. Ol’shukov, and E. V. Dzyuba, “Digital holographic video for the study of the dynamics of plankton,” Izv. Vyssh. Uchebn. Zaved. Fiz. 53, No. 8, 81 (2010).

Optika Atmos. Okeana (2)

V. V. Demin, A. S. Ol’shukov, E. Yu. Naumova, and N. G. Mel’nik, “Digital holography of plankton,” Optika Atmos. Okeana 64, 1089 (2008).

V. V. Demin and S. G. Stepanov, “Holographic studies of transparent microparticles,” Optika Atmos. Okeana 11, 671 (1998).

Other (2)

D. W. Pfitsch, E. Malkiel, Y. Ronzhes, S. R. King, J. Sheng, and J. Katz, “Development of a free-drifting submersible digital holographic imaging system,” in Proc. MTS/IEEE OCEANS, 2005, pp. 690–696.

V. V. Dyomin, J. Watson, and P. W. Benzie, “Reducing the aberrations of holographic images of underwater particles by using the off-axis scheme with normal incidence of object beam,” in Conf. Proc., Oceans’07, 2007, paper 070131-036.

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