Abstract

This paper discusses methods of enhancing the efficiency of ground-based optoelectronic viewing complexes, based on the use of supplementary revealing signs of objects and the spectral adaptation of the channels of the complexes. It is concluded that it is expedient to implement an active-pulse range–brightness channel in these complexes that records the three-dimensional shape of objects and the retroreflected radiation of their optoelectronic systems.

© 2012 OSA

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  1. N. N. Mordvin and G. N. Popov, “Concept of the construction of universal-type optoelectronic observation devices,” Izv. Vyssh. Uchebn. Zaved. Ser. Prib. No. 2, 13 (2007).
  2. G. Filatov, S. Yakubson, and N. Beglova, “Development of mobile ground-based complexes of optoelectronic facilities for reconnaissance of land forces abroad,” Zarub. Voen. Oboz. No. 1–2, 17 (2002).
  3. V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.
  4. Yu. I. Belousov, “Optical characteristics of the radiation of targets and backgrounds—the physical basis for creating optoelectronic apparatus,” Opt. Zh. No. 10, 88 (2006). [J. Opt. Technol. 73, 734 (2006)].
  5. S. A. Pokotilo, “Adaptive optoelectronic remote-sensing facilities,” Zarub. Radioélek. No. 6, 37 (1994).
  6. V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).
  7. L. Novotny and B. Hecht, Principles of Nanooptics (Cambridge Univ. Press, 2006; Fizmatlit, Moscow, 2009).
  8. P. Andersson, “Long-range three-dimensional imaging using range-dated laser radar images,” Opt. Eng. No. 3, 034301 (2006).
    [CrossRef]
  9. F. Lapaz and L. Canevet, “Validation of a target acquisition model for active imager using perception experiment,” Proc. SPIE 6737, 67370G (2007).
    [CrossRef]
  10. R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).
  11. V. P. Ivanov, V. I. Kurt, V. A. Ovsyannikov, and V. L. Filippov, Modelling and Evaluation of Modern Thermal Viewers (Otechestvo, Kazan, 2006).
  12. Nuclear Arms Technology, 1990’s (New York, 1988), pp. 149–164.
  13. L. Ya. Grinchenko, V. P. Ponomarenko, and A. M. Filachev, “Modern status and prospects of IR photoelectronics,” Prikl. Fiz. No. 2, 57 (2009).
  14. K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).
  15. V. G. Volkov, “Night-vision devices for detecting flashing elements,” Spets. Tekhnika No. 2, 3 (2004).
  16. F. Sadjadi and C. Chun, “Remote sensing using passive IR Stokes parameters,” Opt. Eng. No. 10, 2283 (2004).
    [CrossRef]
  17. Y. Takiguchi, M. Nakayama, M. Kubota, and J. Yamazaki, “New color TV cameras for UV, near-IR and visible light,” IEEE Trans. 44, 123 (1998).
  18. V. V. Korolev, I. I. Padusenko, M. V. Tantashev, and V. S. Yatsyk, “Conditions for the remote detection of high-temperature radiation sources in the ultraviolet region,” Opt. Zh. No. 1, 28 (2005). [J. Opt. Technol. 72, 23 (2005)].
  19. L. Yablonskiĭ, E. Voronin, and V. Kashin, “Foreign military programs for space-based visible reconnaissance,” Zarub. Voen. Oboz. No. 7, 29 (2002).
  20. R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).
  21. V. Ivanov, V. Kozlov, and V. Philippov, “Laser spectrofluorescent technology of monitoring of the natural environment,” in SPIE Meetings, Barcelona, Sept. 2003.
  22. V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).
  23. A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).
  24. P. Richardson and B. Miller, “Third-generation FLIR simulation at NVESD,” Proc. SPIE 6543, 65430K (2007).
    [CrossRef]
  25. D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
    [CrossRef]

2009

L. Ya. Grinchenko, V. P. Ponomarenko, and A. M. Filachev, “Modern status and prospects of IR photoelectronics,” Prikl. Fiz. No. 2, 57 (2009).

2007

R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).

N. N. Mordvin and G. N. Popov, “Concept of the construction of universal-type optoelectronic observation devices,” Izv. Vyssh. Uchebn. Zaved. Ser. Prib. No. 2, 13 (2007).

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

F. Lapaz and L. Canevet, “Validation of a target acquisition model for active imager using perception experiment,” Proc. SPIE 6737, 67370G (2007).
[CrossRef]

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).

P. Richardson and B. Miller, “Third-generation FLIR simulation at NVESD,” Proc. SPIE 6543, 65430K (2007).
[CrossRef]

2006

P. Andersson, “Long-range three-dimensional imaging using range-dated laser radar images,” Opt. Eng. No. 3, 034301 (2006).
[CrossRef]

Yu. I. Belousov, “Optical characteristics of the radiation of targets and backgrounds—the physical basis for creating optoelectronic apparatus,” Opt. Zh. No. 10, 88 (2006). [J. Opt. Technol. 73, 734 (2006)].

K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).

2005

V. V. Korolev, I. I. Padusenko, M. V. Tantashev, and V. S. Yatsyk, “Conditions for the remote detection of high-temperature radiation sources in the ultraviolet region,” Opt. Zh. No. 1, 28 (2005). [J. Opt. Technol. 72, 23 (2005)].

2004

V. G. Volkov, “Night-vision devices for detecting flashing elements,” Spets. Tekhnika No. 2, 3 (2004).

F. Sadjadi and C. Chun, “Remote sensing using passive IR Stokes parameters,” Opt. Eng. No. 10, 2283 (2004).
[CrossRef]

2003

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

2002

L. Yablonskiĭ, E. Voronin, and V. Kashin, “Foreign military programs for space-based visible reconnaissance,” Zarub. Voen. Oboz. No. 7, 29 (2002).

G. Filatov, S. Yakubson, and N. Beglova, “Development of mobile ground-based complexes of optoelectronic facilities for reconnaissance of land forces abroad,” Zarub. Voen. Oboz. No. 1–2, 17 (2002).

1998

Y. Takiguchi, M. Nakayama, M. Kubota, and J. Yamazaki, “New color TV cameras for UV, near-IR and visible light,” IEEE Trans. 44, 123 (1998).

1994

S. A. Pokotilo, “Adaptive optoelectronic remote-sensing facilities,” Zarub. Radioélek. No. 6, 37 (1994).

1993

V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).

Abrams, W.

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

Andersson, P.

P. Andersson, “Long-range three-dimensional imaging using range-dated laser radar images,” Opt. Eng. No. 3, 034301 (2006).
[CrossRef]

Balcerak, R.

R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).

Baloev, V. A.

V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.

Beglova, N.

G. Filatov, S. Yakubson, and N. Beglova, “Development of mobile ground-based complexes of optoelectronic facilities for reconnaissance of land forces abroad,” Zarub. Voen. Oboz. No. 1–2, 17 (2002).

Belousov, Yu. I.

Yu. I. Belousov, “Optical characteristics of the radiation of targets and backgrounds—the physical basis for creating optoelectronic apparatus,” Opt. Zh. No. 10, 88 (2006). [J. Opt. Technol. 73, 734 (2006)].

Canevet, L.

F. Lapaz and L. Canevet, “Validation of a target acquisition model for active imager using perception experiment,” Proc. SPIE 6737, 67370G (2007).
[CrossRef]

Chun, C.

F. Sadjadi and C. Chun, “Remote sensing using passive IR Stokes parameters,” Opt. Eng. No. 10, 2283 (2004).
[CrossRef]

Defietas, A.

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

Driggers, R.

K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).

Espinola, R.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

Filachev, A. M.

L. Ya. Grinchenko, V. P. Ponomarenko, and A. M. Filachev, “Modern status and prospects of IR photoelectronics,” Prikl. Fiz. No. 2, 57 (2009).

Filatov, G.

G. Filatov, S. Yakubson, and N. Beglova, “Development of mobile ground-based complexes of optoelectronic facilities for reconnaissance of land forces abroad,” Zarub. Voen. Oboz. No. 1–2, 17 (2002).

Filippov, V. L.

V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).

V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.

V. P. Ivanov, V. I. Kurt, V. A. Ovsyannikov, and V. L. Filippov, Modelling and Evaluation of Modern Thermal Viewers (Otechestvo, Kazan, 2006).

Freyvogel, K.

R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).

Grinchenko, L. Ya.

L. Ya. Grinchenko, V. P. Ponomarenko, and A. M. Filachev, “Modern status and prospects of IR photoelectronics,” Prikl. Fiz. No. 2, 57 (2009).

Halford, C.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).

K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).

Hecht, B.

L. Novotny and B. Hecht, Principles of Nanooptics (Cambridge Univ. Press, 2006; Fizmatlit, Moscow, 2009).

Hodgkin, A.

A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).

Ivanov, V.

V. Ivanov, V. Kozlov, and V. Philippov, “Laser spectrofluorescent technology of monitoring of the natural environment,” in SPIE Meetings, Barcelona, Sept. 2003.

Ivanov, V. P.

V. P. Ivanov, V. I. Kurt, V. A. Ovsyannikov, and V. L. Filippov, Modelling and Evaluation of Modern Thermal Viewers (Otechestvo, Kazan, 2006).

Iyengar, M.

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

Jacobs, E.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

Jeaney, B.

K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).

Jofsted, H.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

Kaplan, V. G.

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

Kashin, V.

L. Yablonskiĭ, E. Voronin, and V. Kashin, “Foreign military programs for space-based visible reconnaissance,” Zarub. Voen. Oboz. No. 7, 29 (2002).

Korolev, V. V.

V. V. Korolev, I. I. Padusenko, M. V. Tantashev, and V. S. Yatsyk, “Conditions for the remote detection of high-temperature radiation sources in the ultraviolet region,” Opt. Zh. No. 1, 28 (2005). [J. Opt. Technol. 72, 23 (2005)].

Kozlov, V.

V. Ivanov, V. Kozlov, and V. Philippov, “Laser spectrofluorescent technology of monitoring of the natural environment,” in SPIE Meetings, Barcelona, Sept. 2003.

Kozlov, V. K.

V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).

Krapels, K.

K. Krapels, R. Driggers, B. Jeaney, and C. Halford, “Handheld threat object identification performance of 2-D visible imagery versus 3-D visible imagery,” Opt. Eng. No. 6, 63201 (2006).

Krasil’nikov, D. M.

V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).

Kubota, M.

Y. Takiguchi, M. Nakayama, M. Kubota, and J. Yamazaki, “New color TV cameras for UV, near-IR and visible light,” IEEE Trans. 44, 123 (1998).

Kurt, V. I.

V. P. Ivanov, V. I. Kurt, V. A. Ovsyannikov, and V. L. Filippov, Modelling and Evaluation of Modern Thermal Viewers (Otechestvo, Kazan, 2006).

Lane, R.

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

Lange, D.

D. Lange, W. Abrams, M. Iyengar, R. Lane, and A. Defietas, “The Goodrich DB-110 system: multiband operation,” Proc. SPIE 5109, 22 (2003).
[CrossRef]

Lapaz, F.

F. Lapaz and L. Canevet, “Validation of a target acquisition model for active imager using perception experiment,” Proc. SPIE 6737, 67370G (2007).
[CrossRef]

Lipatov, V. V.

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

Maurer, T.

A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).

Miller, B.

P. Richardson and B. Miller, “Third-generation FLIR simulation at NVESD,” Proc. SPIE 6543, 65430K (2007).
[CrossRef]

Mordvin, N. N.

N. N. Mordvin and G. N. Popov, “Concept of the construction of universal-type optoelectronic observation devices,” Izv. Vyssh. Uchebn. Zaved. Ser. Prib. No. 2, 13 (2007).

Nakayama, M.

Y. Takiguchi, M. Nakayama, M. Kubota, and J. Yamazaki, “New color TV cameras for UV, near-IR and visible light,” IEEE Trans. 44, 123 (1998).

Navrazhnykh, V. A.

V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.

Nepogodin, I. A.

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.

Nguyen, Q.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

Novotny, L.

L. Novotny and B. Hecht, Principles of Nanooptics (Cambridge Univ. Press, 2006; Fizmatlit, Moscow, 2009).

Ovsyannikov, V. A.

V. P. Ivanov, V. I. Kurt, V. A. Ovsyannikov, and V. L. Filippov, Modelling and Evaluation of Modern Thermal Viewers (Otechestvo, Kazan, 2006).

V. A. Baloev, V. L. Filippov, V. A. Ovsyannikov, I. A. Nepogodin, V. A. Navrazhnykh, and V. S. Yatsyk, “On the development of multispectral optoelectronic reconnaissance systems,” in The Twenty-First All-Russia Interuniversity Scientific–Engineering Conference on Electromechanical and Intracamera Processes in Power Apparatus, Jet Acoustics and Diagnostics, Devices and Methods for Monitoring Natural Media, Substances, Materials, and Items. Abstracts of Reports, Kazan, KVVKU, 2009, pp. 225–227, chap. 2.

Padusenko, I. I.

V. V. Korolev, I. I. Padusenko, M. V. Tantashev, and V. S. Yatsyk, “Conditions for the remote detection of high-temperature radiation sources in the ultraviolet region,” Opt. Zh. No. 1, 28 (2005). [J. Opt. Technol. 72, 23 (2005)].

Philippov, V.

V. Ivanov, V. Kozlov, and V. Philippov, “Laser spectrofluorescent technology of monitoring of the natural environment,” in SPIE Meetings, Barcelona, Sept. 2003.

Pokotilo, S. A.

S. A. Pokotilo, “Adaptive optoelectronic remote-sensing facilities,” Zarub. Radioélek. No. 6, 37 (1994).

Pol’skii, Yu. E.

V. K. Kozlov, D. M. Krasil’nikov, V. L. Filippov, and Yu. E. Pol’skiĭ, “Spectral analyzer and principles of the technique of fluorescence diagnosis of the state of biological tissue and its components,” Zh. Prikl. Spektrosk. No. 1, 21 (1993).

Ponomarenko, V. P.

L. Ya. Grinchenko, V. P. Ponomarenko, and A. M. Filachev, “Modern status and prospects of IR photoelectronics,” Prikl. Fiz. No. 2, 57 (2009).

Popov, G. N.

N. N. Mordvin and G. N. Popov, “Concept of the construction of universal-type optoelectronic observation devices,” Izv. Vyssh. Uchebn. Zaved. Ser. Prib. No. 2, 13 (2007).

Richardson, P.

P. Richardson and B. Miller, “Third-generation FLIR simulation at NVESD,” Proc. SPIE 6543, 65430K (2007).
[CrossRef]

Richwine, R.

R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).

Sadjadi, F.

F. Sadjadi and C. Chun, “Remote sensing using passive IR Stokes parameters,” Opt. Eng. No. 10, 2283 (2004).
[CrossRef]

Sood, A.

R. Richwine, A. Sood, R. Balcerak, and K. Freyvogel, “EO/IR sensor model for evaluating multispectral imaging system performance,” Proc. SPIE 6543, 65430W (2007).

Stepanov, V. A.

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

Takiguchi, Y.

Y. Takiguchi, M. Nakayama, M. Kubota, and J. Yamazaki, “New color TV cameras for UV, near-IR and visible light,” IEEE Trans. 44, 123 (1998).

Tantashev, M. V.

V. V. Korolev, I. I. Padusenko, M. V. Tantashev, and V. S. Yatsyk, “Conditions for the remote detection of high-temperature radiation sources in the ultraviolet region,” Opt. Zh. No. 1, 28 (2005). [J. Opt. Technol. 72, 23 (2005)].

Teaney, B.

R. Espinola, B. Teaney, Q. Nguyen, E. Jacobs, C. Halford, and H. Jofsted, “Active imaging system performance model for target acquisition,” Proc. SPIE 6543, 65430T (2007).

Tiranov, D. T.

V. S. Yatsyk, I. A. Nepogodin, V. V. Lipatov, V. G. Kaplan, V. A. Stepanov, and D. T. Tiranov, “Experimental research of the information content of the radiance and remote-radiance images of objects in the UV and IR regions,” Oboron. Tekh. No. 1–2, 56 (2007).

Volkov, V. G.

V. G. Volkov, “Night-vision devices for detecting flashing elements,” Spets. Tekhnika No. 2, 3 (2004).

Vollmerhausen, R.

A. Hodgkin, T. Maurer, C. Halford, and R. Vollmerhausen, “Impact of path radiance on MWIR and LWIR imaging,” Proc. SPIE 6543, 65430O (2007).

Voronin, E.

L. Yablonskiĭ, E. Voronin, and V. Kashin, “Foreign military programs for space-based visible reconnaissance,” Zarub. Voen. Oboz. No. 7, 29 (2002).

Yablonskii, L.

L. Yablonskiĭ, E. Voronin, and V. Kashin, “Foreign military programs for space-based visible reconnaissance,” Zarub. Voen. Oboz. No. 7, 29 (2002).

Yakubson, S.

G. Filatov, S. Yakubson, and N. Beglova, “Development of mobile ground-based complexes of optoelectronic facilities for reconnaissance of land forces abroad,” Zarub. Voen. Oboz. No. 1–2, 17 (2002).

Yamazaki, J.

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