Active optics

Last updated August 06, 2022

Active optics is a technology used with reflecting telescopes developed in the 1980s,^[1] which actively shapes a telescope's mirrors to prevent deformation due to external influences such as wind, temperature, and mechanical stress. Without active optics, the construction of 8 metre class telescopes is not possible, nor would telescopes with segmented mirrors be feasible.

In astronomy

Most modern telescopes are reflectors, with the primary element being a very large mirror. Historically, primary mirrors were quite thick in order to maintain the correct surface figure in spite of forces tending to deform it, like wind and the mirror's own weight. This limited their maximum diameter to 5 or 6 metres (200 or 230 inches), such as Palomar Observatory's Hale telescope.

A new generation of telescopes built since the 1980s uses thin, lighter weight mirrors instead. They are too thin to maintain themselves rigidly in the correct shape, so an array of actuators is attached to the rear side of the mirror. The actuators apply variable forces to the mirror body to keep the reflecting surface in the correct shape over repositioning. The telescope may also be segmented into multiple smaller mirrors, which reduce the sagging due to weight that occurs for large, monolithic mirrors.

The combination of actuators, an image quality detector, and a computer to control the actuators to obtain the best possible image, is called active optics.

The name active optics means that the system keeps a mirror (usually the primary) in its optimal shape against environmental forces such as wind, sag, thermal expansion, and telescope axis deformation. Active optics compensate for distorting forces that change relatively slowly, roughly on timescales of seconds. The telescope is therefore actively still, in its optimal shape.

Comparison with adaptive optics

Active optics should not be confused with adaptive optics, which operates on a much shorter timescale to compensate for atmospheric effects, rather than for mirror deformation. The influences that active optics compensate (temperature, gravity) are intrinsically slower (1 Hz) and have a larger amplitude in aberration. Adaptive optics on the other hand corrects for atmospheric distortions that affect the image at 100–1000 Hz (the Greenwood frequency,^[4] depending on wavelength and weather conditions). These corrections need to be much faster, but also have smaller amplitude. Because of this, adaptive optics uses smaller corrective mirrors. This used to be a separate mirror not integrated in the telescope's light path, but nowadays this can be the second,^[5]^[6] third or fourth^[7] mirror in a telescope.

Other applications

Complicated laser set-ups and interferometers can also be actively stabilized.

A small part of the beam leaks through beam steering mirrors and a four-quadrant-diode is used to measure the position of a laser beam and another in the focal plane behind a lens is used to measure the direction. The system can be sped up or made more noise-immune by using a PID controller. For pulsed lasers the controller should be locked to the repetition rate. A continuous (non-pulsed) pilot beam can be used to allow for up to 10 kHz bandwidth of stabilization (against vibrations, air turbulence, and acoustic noise) for low repetition rate lasers.

Sometimes Fabry–Pérot interferometers have to be adjusted in length to pass a given wavelength. Therefore, the reflected light is extracted by means of a Faraday rotator and a polarizer. Small changes of the incident wavelength generated by an acousto-optic modulator or interference with a fraction of the incoming radiation delivers the information whether the Fabry Perot is too long or too short.

Long optical cavities are very sensitive to the mirror alignment. A control circuit can be used to peak power. One possibility is to perform small rotations with one end mirror. If this rotation is about the optimum position, no power oscillation occurs. Any beam pointing oscillation can be removed using the beam steering mechanism mentioned above.

X-ray active optics, using actively deformable grazing incidence mirrors, are also being investigated.^[8]

Related Research Articles

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The Overwhelmingly Large Telescope (OWL) was a conceptual design by the European Southern Observatory (ESO) organization for an extremely large telescope, which was intended to have a single aperture of 100 meters in diameter. Because of the complexity and cost of building a telescope of this unprecedented size, ESO has elected to focus on the 39-meter diameter Extremely Large Telescope instead.

Interferometry Measurement method using interference of waves

Interferometry is a technique which uses the interference of superimposed waves to extract information. Interferometry typically uses electromagnetic waves and is an important investigative technique in the fields of astronomy, fiber optics, engineering metrology, optical metrology, oceanography, seismology, spectroscopy, quantum mechanics, nuclear and particle physics, plasma physics, remote sensing, biomolecular interactions, surface profiling, microfluidics, mechanical stress/strain measurement, velocimetry, optometry, and making holograms.

W. M. Keck Observatory Astronomical observatory located in Hawaii

The W. M. Keck Observatory is a two-telescope astronomical observatory at an elevation of 4,145 meters (13,600 ft) near the summit of Mauna Kea in the U.S. state of Hawaii. Both telescopes have 10 m (33 ft) aperture primary mirrors, and when completed in 1993 and 1996 were the largest astronomical telescopes in the world. They are currently the 3rd and 4th largest.

Adaptive optics (AO) is a technology used to improve the performance of optical systems by reducing the effect of incoming wavefront distortions by deforming a mirror in order to compensate for the distortion. It is used in astronomical telescopes and laser communication systems to remove the effects of atmospheric distortion, in microscopy, optical fabrication and in retinal imaging systems to reduce optical aberrations. Adaptive optics works by measuring the distortions in a wavefront and compensating for them with a device that corrects those errors such as a deformable mirror or a liquid crystal array.

A reflecting telescope is a telescope that uses a single or a combination of curved mirrors that reflect light and form an image. The reflecting telescope was invented in the 17th century by Isaac Newton as an alternative to the refracting telescope which, at that time, was a design that suffered from severe chromatic aberration. Although reflecting telescopes produce other types of optical aberrations, it is a design that allows for very large diameter objectives. Almost all of the major telescopes used in astronomy research are reflectors. Reflecting telescopes come in many design variations and may employ extra optical elements to improve image quality or place the image in a mechanically advantageous position. Since reflecting telescopes use mirrors, the design is sometimes referred to as a catoptric telescope.

The Nordic Optical Telescope (NOT) is an astronomical telescope located at Roque de los Muchachos Observatory, La Palma in the Canary Islands. The telescope saw first light in 1988, and was officially inaugurated during September 1989. Regular observing started in 1990. It is funded by Denmark, Sweden, Norway, Finland, and Iceland. Access is provided directly to astronomers of the funding countries, and of all nationalities through international time allocation committees.

The New Technology Telescope or NTT is a 3.58-metre Ritchey–Chrétien telescope operated by the European Southern Observatory. It began operations in 1989. It is located in Chile at the La Silla Observatory and was an early pioneer in the use of active optics. The telescope and its enclosure were built to a revolutionary design for optimal image quality.

The Galileo National Telescope, is a 3.58-meter Italian telescope, located at the Roque de los Muchachos Observatory on the island of La Palma in the Canary Islands, Spain. The TNG is operated by the "Fundación Galileo Galilei, Fundación Canaria", a non-profit institution, on behalf of the Italian National Institute of Astrophysics (INAF). The telescope saw first light in 1998 and is named after the Italian Renaissance astronomer Galileo Galilei.

A laser guide star is an artificial star image created for use in astronomical adaptive optics systems, which are employed in large telescopes in order to correct atmospheric distortion of light. Adaptive optics (AO) systems require a wavefront reference source of light called a guide star. Natural stars can serve as point sources for this purpose, but sufficiently bright stars are not available in all parts of the sky, which greatly limits the usefulness of natural guide star adaptive optics. Instead, one can create an artificial guide star by shining a laser into the atmosphere. Light from the beam is reflected by components in the upper atmosphere back into the telescope. This star can be positioned anywhere the telescope desires to point, opening up much greater amounts of the sky to adaptive optics.

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The Extremely Large Telescope (ELT) is an astronomical observatory currently under construction. When completed, it is planned to be the world's largest optical/near-infrared extremely large telescope. Part of the European Southern Observatory (ESO) agency, it is located on top of Cerro Armazones in the Atacama Desert of northern Chile.

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A segmented mirror is an array of smaller mirrors designed to act as segments of a single large curved mirror. The segments can be either spherical or asymmetric. They are used as objectives for large reflecting telescopes. To function, all the mirror segments have to be polished to a precise shape and actively aligned by a computer-controlled active optics system using actuators built into the mirror support cell.

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A null corrector is an optical device used in the testing of large aspheric mirrors. A spherical mirror of any size can be tested relatively easily using standard optical components such as laser, mirrors, beamsplitters, and converging lenses. One method of doing this using a Shack cube is shown at the right, and many other setups are possible. An interferometer test such as this one generates a contour map of the deviation of the surface from a perfect sphere, with the contours in units of half the wavelength used. This is called a null test because when the mirror is perfect, the result is null. If the result is not null, then the mirror is not perfect, and the pattern shows where the optician should polish the mirror to improve it.

Boston Micromachines Corporation is a US company operating out of Cambridge, Massachusetts. Boston Micromachines manufactures and develops instruments based on MEMS technology to perform open and closed-loop adaptive optics. The technology is applied in astronomy, beam shaping, vision science, retinal imaging, microscopy, laser communications, and national defense. The instruments developed at Boston Micromachines include deformable mirrors, optical modulators, and retinal imaging systems, all of which utilize adaptive optics technology to enable wavefront manipulation capabilities which enhance the quality of the final image.

ALPAO is a company which manufactures a range of adaptive optics products for use in research and industry, including deformable mirrors with large strokes, wavefront sensors, and adaptive optics loops. These products are designed for astronomy, vision science, microscopy, wireless optical communications, and laser applications.

References

↑ Hardy, John W. (June 1977). "Active optics: A new technology for the control of light". IEEE Proceedings. Proceedings of the IEEE. 66: 110. Bibcode:1978IEEEP..66..651H. Archived from the original on 2015-12-22. Retrieved 2011-06-01.
↑ Andersen, T.; Andersen, T.; Larsen, O. B.; Owner-Petersen, M.; Steenberg, K. (April 1992). Ulrich, Marie-Helene (ed.). Active Optics on the Nordic Optical Telescope. ESO Conference and Workshop Proceedings. Progress in Telescope and Instrumentation Technologies. pp. 311–314. Bibcode:1992ESOC...42..311A.
↑ "ESO Awards Contract for E-ELT Adaptive Mirror Design Study". ESO Announcements. Retrieved 25 May 2012.
↑ Greenwood, Darryl P. (March 1977). "Bandwidth specification for adaptive optics systems" (PDF). Journal of the Optical Society of America. 67 (3): 390–393. Bibcode:1977JOSA...67..390G. doi:10.1364/JOSA.67.000390.
↑ Riccardi, Armando; Brusa, Guido; Salinari, Piero; Gallieni, Daniele; Biasi, Roberto; Andrighettoni, Mario; Martin, Hubert M (February 2003). "Adaptive secondary mirrors for the Large Binocular Telescope" (PDF). Proceedings of the SPIE. Adaptive Optical System Technologies II. 4839: 721–732. Bibcode:2003SPIE.4839..721R. CiteSeerX 10.1.1.70.8438 . doi:10.1117/12.458961. Archived from the original (PDF) on 2011-08-23.
↑ Salinari, P.; Del Vecchio, C.; Biliotti, V. (August 1994). A Study of an Adaptive Secondary Mirror. ESO Conference and Workshop Proceedings. Active and adaptive optics. Garching, Germany: ESO. pp. 247–253. Bibcode:1994ESOC...48..247S.
↑ Crépy, B.; et al. (June 2009). The M4 adaptive unit for the E-ELT. 1st AO4ELT conference – Adaptative Optics for Extremely Large Telescopes Proceedings. Paris, France: EDP Sciences. Bibcode:2010aoel.confE6001C. doi: 10.1051/ao4elt/201006001 .
↑ "Research Partnership Advances X-ray Active Optics". adaptiveoptics.org. March 2005. Archived from the original on March 11, 2007. Retrieved 2 June 2011. Alt URL

External links

An introduction to active & adaptive optics (European Southern Observatory web-site)
Active optics on ESO's NTT.
Active optics at the Gran Telescopio Canarias.

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[1] Hardy, John W. (June 1977). "Active optics: A new technology for the control of light". IEEE Proceedings. Proceedings of the IEEE. 66: 110. Bibcode:1978IEEEP..66..651H. Archived from the original on 2015-12-22. Retrieved 2011-06-01.

[2] Andersen, T.; Andersen, T.; Larsen, O. B.; Owner-Petersen, M.; Steenberg, K. (April 1992). Ulrich, Marie-Helene (ed.). Active Optics on the Nordic Optical Telescope. ESO Conference and Workshop Proceedings. Progress in Telescope and Instrumentation Technologies. pp. 311–314. Bibcode:1992ESOC...42..311A.

[3] "ESO Awards Contract for E-ELT Adaptive Mirror Design Study". ESO Announcements. Retrieved 25 May 2012.

[4] Greenwood, Darryl P. (March 1977). "Bandwidth specification for adaptive optics systems" (PDF). Journal of the Optical Society of America. 67 (3): 390–393. Bibcode:1977JOSA...67..390G. doi:10.1364/JOSA.67.000390.

[5] Riccardi, Armando; Brusa, Guido; Salinari, Piero; Gallieni, Daniele; Biasi, Roberto; Andrighettoni, Mario; Martin, Hubert M (February 2003). "Adaptive secondary mirrors for the Large Binocular Telescope" (PDF). Proceedings of the SPIE. Adaptive Optical System Technologies II. 4839: 721–732. Bibcode:2003SPIE.4839..721R. CiteSeerX 10.1.1.70.8438 . doi:10.1117/12.458961. Archived from the original (PDF) on 2011-08-23.

[6] Salinari, P.; Del Vecchio, C.; Biliotti, V. (August 1994). A Study of an Adaptive Secondary Mirror. ESO Conference and Workshop Proceedings. Active and adaptive optics. Garching, Germany: ESO. pp. 247–253. Bibcode:1994ESOC...48..247S.

[7] Crépy, B.; et al. (June 2009). The M4 adaptive unit for the E-ELT. 1st AO4ELT conference – Adaptative Optics for Extremely Large Telescopes Proceedings. Paris, France: EDP Sciences. Bibcode:2010aoel.confE6001C. doi: 10.1051/ao4elt/201006001 .

[8] "Research Partnership Advances X-ray Active Optics". adaptiveoptics.org. March 2005. Archived from the original on March 11, 2007. Retrieved 2 June 2011. Alt URL

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