Mirror support cell explained

In astronomy, a mirror support cell - more commonly mirror cell - is a component of a reflecting telescope that supports the mirror in place to hold optical alignment, allow collimation adjustment, and protect it from falling out. The common usage of the word denotes the cell that holds the primary mirror (M1), however technically it could also be used to denote the support assembly (usually called a spider or strut) for the secondary mirror (M2) or other mirrors.

Overview

Basic cells

A basic mirror cell can be built using minimal calculation and simple materials.[1] Only slightly more complex are the wooden, plastic or metal cells which are often glued and which are either not user adjustable or which have only limited adjustment and which are used in lower end commercial telescopes and smaller amateur-built telescopes.

Cells for more sophisticated "small" telescopes

Telescope makers seeking to build larger "small" telescopes with thinner mirrors find simple designs inadequate so they must resort to more complex design methods which include possible use of multiaxis adjustment potential and floating whippletree[2] cell design, often optimimized using computer aided design programs.[3] [4] There remains a good deal of discussion in the amateur telescope making community over the use of glue and the addition of simple astatic devices in such cells.

Cells for large telescopes

Astronomical observatories require a much heavier and more complex mirror support cell. One notable example of the structure needed for such telescopes is the dual cell for the M1 mirrors of the 8.4 meter Large Binocular Telescope at Mount Graham International Observatory. This is a multiple beam and truss system which in turn supports a temperature maintenance and air flow system, six position actuators and the 160 pneumatic actuators which work its active optics system. This results in a huge assembly structure weighing about 28 tons without its mirrors. Such a mirror cell requires multiple mathematical steps of finite element analysis of its deformation under static and moving loading.[5] [6]

See also

External links

Notes and References

  1. Book: Pierce, J. M. . John M. Pierce. Albert G.. Ingalls . Albert Graham Ingalls. . Scientific American . 1926. 94–102 . A telescope that anyone can make .
  2. http://star.arm.ac.uk/history/instruments/Grubb-15inch.html
  3. Web site: Holm . Mark . Mirror Cells for Amateur Telescope Makers . https://web.archive.org/web/20060211013216/http://www.atmsite.org/contrib/Holm/Plop_optimized_cells/index.html . dead . February 11, 2006 . November 21, 2009 .
  4. Book: Kriege, David. Richard Berry. The Dobsonian Telescope, A Practical Manual for Building Large Aperture Telescopes. Willmann-Bell. June 1997. Chapter 5. 978-0-943396-55-2 .
  5. Web site: Miglietta. L.. The Final Design of the Large Binocular Telescope M1 Mirror Cells. Other LBT Publications. Proceedings of SPIE conference on Optical Telescopes of Today and Tomorrow, 2871, (1996). 1996. 2009-11-20. dead. https://archive.today/20040829201113/http://medusa.as.arizona.edu/lbto/tech/m1cellhv.htm. 2004-08-29.
  6. Web site: UA-95-02: Mirror Support System for Large Honeycomb Mirrors. Large Binocular Telescope Project Technical Memo. University of Arizona. 1995. 2009-11-20. dead. https://web.archive.org/web/20100703082028/http://medusa.as.arizona.edu/lbto/tech/ua9502.htm. 2010-07-03.