Abstract

A diffractive optical element is described that can be used to implement a very simple self-aligning electronic speckle-pattern interferometer and holographic interferometer that requires only a laser source and a camera in the optical setup.

© 2002 Optical Society of America

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References

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  1. R. Jones, C. Wykes, Holographic and Speckle Interferometry, 2nd ed. (Cambridge University, Cambridge, UK, 1985).
  2. S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).
  3. S. Martin, C. A. Feely, V. Toal, “Holographic characteristics of an acrylamide-based recording material,” Appl. Opt. 36, 5757–5769 (1997).
    [CrossRef] [PubMed]
  4. M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.
  5. P. P. Benham, F. V. Warnock, Mechanics of Solids and Structures, (Pitman, London, 1976).
  6. Wavin Ireland Limited, Wavinmain Pressure System, 2000.
  7. V. Petrov, B. Lau, “Electronic speckle pattern interferometry with a holographically generated reference wave,” Optical. Eng. 35, 2363–2370 (1996).
    [CrossRef]
  8. S. Reddy, V. Toal, S. Martin, in Opto-Ireland 2002: Optics and Photonics Technologies and Applications, T. J. Glynn, ed., Proc. SPIE4876, paper 173 (to be published).

1997 (1)

1996 (1)

V. Petrov, B. Lau, “Electronic speckle pattern interferometry with a holographically generated reference wave,” Optical. Eng. 35, 2363–2370 (1996).
[CrossRef]

1995 (1)

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

Benham, P. P.

P. P. Benham, F. V. Warnock, Mechanics of Solids and Structures, (Pitman, London, 1976).

Feely, C. A.

Forno, C.

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

Jones, R.

R. Jones, C. Wykes, Holographic and Speckle Interferometry, 2nd ed. (Cambridge University, Cambridge, UK, 1985).

Lau, B.

V. Petrov, B. Lau, “Electronic speckle pattern interferometry with a holographically generated reference wave,” Optical. Eng. 35, 2363–2370 (1996).
[CrossRef]

Leclere, P.

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

Lion, Y.

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

Martin, S.

S. Martin, C. A. Feely, V. Toal, “Holographic characteristics of an acrylamide-based recording material,” Appl. Opt. 36, 5757–5769 (1997).
[CrossRef] [PubMed]

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

S. Reddy, V. Toal, S. Martin, in Opto-Ireland 2002: Optics and Photonics Technologies and Applications, T. J. Glynn, ed., Proc. SPIE4876, paper 173 (to be published).

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

Neill, F. O

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

Petrov, V.

V. Petrov, B. Lau, “Electronic speckle pattern interferometry with a holographically generated reference wave,” Optical. Eng. 35, 2363–2370 (1996).
[CrossRef]

Reddy, S.

S. Reddy, V. Toal, S. Martin, in Opto-Ireland 2002: Optics and Photonics Technologies and Applications, T. J. Glynn, ed., Proc. SPIE4876, paper 173 (to be published).

Renotte, Y.

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

Toal, V.

S. Martin, C. A. Feely, V. Toal, “Holographic characteristics of an acrylamide-based recording material,” Appl. Opt. 36, 5757–5769 (1997).
[CrossRef] [PubMed]

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

S. Reddy, V. Toal, S. Martin, in Opto-Ireland 2002: Optics and Photonics Technologies and Applications, T. J. Glynn, ed., Proc. SPIE4876, paper 173 (to be published).

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

Warnock, F. V.

P. P. Benham, F. V. Warnock, Mechanics of Solids and Structures, (Pitman, London, 1976).

Whelan, M. P.

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

Wykes, C.

R. Jones, C. Wykes, Holographic and Speckle Interferometry, 2nd ed. (Cambridge University, Cambridge, UK, 1985).

Appl. Opt. (1)

Opt. Eng. (1)

S. Martin, P. Leclere, Y. Renotte, V. Toal, Y. Lion, “Characterisation of an acrylamide-based dry photopolymer holographic recording material,” Opt. Eng. 33, 3942–3946 (1995).

Optical. Eng. (1)

V. Petrov, B. Lau, “Electronic speckle pattern interferometry with a holographically generated reference wave,” Optical. Eng. 35, 2363–2370 (1996).
[CrossRef]

Other (5)

S. Reddy, V. Toal, S. Martin, in Opto-Ireland 2002: Optics and Photonics Technologies and Applications, T. J. Glynn, ed., Proc. SPIE4876, paper 173 (to be published).

R. Jones, C. Wykes, Holographic and Speckle Interferometry, 2nd ed. (Cambridge University, Cambridge, UK, 1985).

M. P. Whelan, C. Forno, S. Martin, F. O Neill, V. Toal, “Illumination systems using photopolymer gratings for speckle interferometry,” in Interferometry ’99 Applications, W. P. Jueptner, K. Patorski, eds., Proc. SPIE3745, International conference on optical metrology, techniques and technologies, Warsaw, Poland, September20th to 23rd, 1999.

P. P. Benham, F. V. Warnock, Mechanics of Solids and Structures, (Pitman, London, 1976).

Wavin Ireland Limited, Wavinmain Pressure System, 2000.

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Figures (5)

Fig. 1
Fig. 1

Recording a transmission hologram of a test object for holographic interferometry and out-of-plane sensitive ESPI.

Fig. 2
Fig. 2

Live holographic interferometric fringes of a radially expanding plastic cylinder using the arrangement of Fig. 1.

Fig. 3
Fig. 3

Subtraction fringes in an out-of-plane ESPI system using the transmission hologram to generate the reference wavefront.

Fig. 4
Fig. 4

Reflection hologram recording.

Fig. 5
Fig. 5

Subtraction ESPI fringes obtained from photopolymer reflection hologram. The object is a flat circular disk rotated in its own plane.

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