Abstract

This paper demonstrates that it is expedient to use two-dimensional radiation-detector arrays to solve the one-dimensional problem of measuring a plane angle. This assumption is illustrated by a theoretical analysis of the well-known nonmisadjustable optical system of a turning-angle sensor based on a collimator with an annular field. A specific example of such a sensor is considered.

© 2014 Optical Society of America

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  1. A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].
  2. Yu. E.  Dukarevich, M. Yu.  Dukarevich, “Absolute angle converter (Version),” Russian Federation Patent No. 2 419 060 (2009).
  3. A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “Angle-measuring device,” Russian Federation Patent No. 109 847 (2011).
  4. V. I.  Fedoseev, M. P.  Kolosov, Optoelectronic Devices for the Orientation and Navigation of Spacecraft (LOGOS, Moscow, 2007).
  5. V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].
  6. M. P.  Kolosov, “Optical system based on a collimator with an annular field,” Opt. Zh. No. 3, 30 (1990) [J. Opt. Technol. 57, 155 (1990)].
  7. M. P.  Kolosov, The Optics of Adaptive Goniometers (SKAN-1, Moscow, 1997).
  8. M. P.  Kolosov, The Optics of Adaptive Goniometers. Introduction to Design (LOGOS, Moscow, 2011).
  9. V. I.  Fedoseev, The Detection of Space–Time Signals in Optoelectronic Systems (Izd. Universitetskaya Kniga, Moscow, 2011).
  10. G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).
  11. P. A.  Pavlov, “Development and study of high-accuracy laser goniometric systems,” Author’s abstract of doctoral dissertation, St. Petersburg (2008).
  12. V. S.  Plotnikov, Geodesic Devices (Izd. Nedra, Moscow, 1987).

2012 (1)

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].

1995 (1)

V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].

1990 (1)

M. P.  Kolosov, “Optical system based on a collimator with an annular field,” Opt. Zh. No. 3, 30 (1990) [J. Opt. Technol. 57, 155 (1990)].

Abezgauz, G. G.

G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).

Dukarevich, M. Yu.

Yu. E.  Dukarevich, M. Yu.  Dukarevich, “Absolute angle converter (Version),” Russian Federation Patent No. 2 419 060 (2009).

Dukarevich, Yu. E.

Yu. E.  Dukarevich, M. Yu.  Dukarevich, “Absolute angle converter (Version),” Russian Federation Patent No. 2 419 060 (2009).

Fedoseev, V. I.

V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].

V. I.  Fedoseev, M. P.  Kolosov, Optoelectronic Devices for the Orientation and Navigation of Spacecraft (LOGOS, Moscow, 2007).

V. I.  Fedoseev, The Detection of Space–Time Signals in Optoelectronic Systems (Izd. Universitetskaya Kniga, Moscow, 2011).

Karelin, A. Yu.

V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].

Kolosov, M. P.

M. P.  Kolosov, “Optical system based on a collimator with an annular field,” Opt. Zh. No. 3, 30 (1990) [J. Opt. Technol. 57, 155 (1990)].

M. P.  Kolosov, The Optics of Adaptive Goniometers (SKAN-1, Moscow, 1997).

V. I.  Fedoseev, M. P.  Kolosov, Optoelectronic Devices for the Orientation and Navigation of Spacecraft (LOGOS, Moscow, 2007).

M. P.  Kolosov, The Optics of Adaptive Goniometers. Introduction to Design (LOGOS, Moscow, 2011).

Kopenkin, Yu. N.

G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).

Korolëv, A. N.

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “Angle-measuring device,” Russian Federation Patent No. 109 847 (2011).

Korotkova, E. L.

V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].

Korovina, I. A.

G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).

Lukin, A. Ya.

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “Angle-measuring device,” Russian Federation Patent No. 109 847 (2011).

Pavlov, P. A.

P. A.  Pavlov, “Development and study of high-accuracy laser goniometric systems,” Author’s abstract of doctoral dissertation, St. Petersburg (2008).

Plotnikov, V. S.

V. S.  Plotnikov, Geodesic Devices (Izd. Nedra, Moscow, 1987).

Polishchuk, G. S.

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “Angle-measuring device,” Russian Federation Patent No. 109 847 (2011).

Tron’, A. P.

G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).

Opt. Zh. (3)

V. I.  Fedoseev, A. Yu.  Karelin, E. L.  Korotkova, “Using stars to calibrate the goniometric optical devices of spacecraft,” Opt. Zh. 62, No. 9, 26 (1995) [J. Opt. Technol. 62, 586 (1995)].

M. P.  Kolosov, “Optical system based on a collimator with an annular field,” Opt. Zh. No. 3, 30 (1990) [J. Opt. Technol. 57, 155 (1990)].

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “New concept of angular measurement. Model and experimental studies,” Opt. Zh. 79, No. 6, 52 (2012) [J. Opt. Technol. 79, 352 (2012)].

Other (9)

Yu. E.  Dukarevich, M. Yu.  Dukarevich, “Absolute angle converter (Version),” Russian Federation Patent No. 2 419 060 (2009).

A. N.  Korolëv, A. Ya.  Lukin, G. S.  Polishchuk, “Angle-measuring device,” Russian Federation Patent No. 109 847 (2011).

V. I.  Fedoseev, M. P.  Kolosov, Optoelectronic Devices for the Orientation and Navigation of Spacecraft (LOGOS, Moscow, 2007).

M. P.  Kolosov, The Optics of Adaptive Goniometers (SKAN-1, Moscow, 1997).

M. P.  Kolosov, The Optics of Adaptive Goniometers. Introduction to Design (LOGOS, Moscow, 2011).

V. I.  Fedoseev, The Detection of Space–Time Signals in Optoelectronic Systems (Izd. Universitetskaya Kniga, Moscow, 2011).

G. G.  Abezgauz, A. P.  Tron’, Yu. N.  Kopenkin, I. A.  Korovina, Handbook on Probability Calculations (Voen. Izd. MO SSSR, Moscow, 1970).

P. A.  Pavlov, “Development and study of high-accuracy laser goniometric systems,” Author’s abstract of doctoral dissertation, St. Petersburg (2008).

V. S.  Plotnikov, Geodesic Devices (Izd. Nedra, Moscow, 1987).

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