Mangin mirror explained

In optics, a Mangin mirror is a negative meniscus lens with the reflective surface on the rear side of the glass forming a curved mirror that reflects light without spherical aberration if certain conditions are met. This reflector was invented in 1874[1] by a French officer Alphonse Mangin[2] [3] as an improved catadioptric reflector for search lights and is also used in other optical devices.

Description

The Mangin mirror's construction consists of a concave (negative meniscus) lens made of crown glass with spherical surfaces of different radii with the reflective coating on the shallower rear surface. The spherical aberration normally produced by the simple spherical mirror surface is canceled out by the opposite spherical aberration produced by the light traveling through the negative lens. Since light passes through the glass twice, the overall system acts like a triplet lens.[4] The Mangin mirror was invented in 1874 by a French military engineer named Colonel Alphonse Mangin as a substitute for the more difficult to manufacture parabolic reflecting mirror for use in searchlights. Since the catadioptric design eliminated most of the off-axis aberration found in parabolic mirrors, Mangin mirrors had the added advantage of producing a nearly true parallel beam of light. They saw use in the late 19th century as reflectors for naval search lights. Its use in military applications was limited, since glass reflectors of any kind were thought to be too fragile and susceptible to enemy gunfire.[5]

Applications

Mangin mirrors are used in illumination and image forming optics such as search lights, headlamps, aircraft gunsights and head-mounted displays. Many catadioptric telescopes use negative lenses with a reflective coating on the back surface that are referred to as "Mangin mirrors", although they are not single-element objectives like the original Mangin, and some, like the Hamiltonian telescope, predate the Mangin's invention by over 60 years.[6] Catadioptric mirrors similar to the Mangin are found in the Klevtsov–Cassegrain, Argunov–Cassegrain telescopes, and Ludwig Schupmann's Schupmann medial telescope.[7] They are also used in compact catadioptric photographic lens designs that save on mass since aberration can be corrected by the mirror, itself.[8] Mangin mirrors are also used in null correctors, which are used to fabricate large aspheric mirrors.[9]

External links

Notes and References

  1. Book: Laussedat . Aimé . Sur la Télégraphie Optique . Compte Rendu de la 3me Session . Association Française pour l'Avancement des Sciences . Lille . 17 August 1874 . 1290 . https://books.google.com/books?id=ulc3AQAAMAAJ&dq=parabolique&pg=PA1290 . 7 May 2023.
  2. 0710.2165 . Terebizh . V. Yu. . Wide-field telescopes with a Mangin mirror . 2007 . astro-ph .
  3. http://www.britannica.com/EBchecked/topic/361986/Alphonse-Mangin Britannica
  4. https://books.google.com/books?id=i35NCLLiglIC&dq=mangin+mirror+was+invented+by&pg=PA65 Optical design fundamentals for infrared systems By Max J. Riedl
  5. https://books.google.com/books?id=TZBRAAAAMAAJ&dq=mangin+mirror+french+search+light&pg=PA62 Jean Alexandre Rey, John Henry Johnson, The range of electric searchlight projectors, 1917 - page 62
  6. http://www.telescope-optics.net/catadioptric_telescopes.htm Vladimir Sacek, telescope-optics.net, Notes on AMATEUR TELESCOPE OPTICS, CATADIOPTRIC TELESCOPES, 10.2.1
  7. Web site: Sacek. Vladimir. 11.1.2. Schupmann "medial" telescope. Telescope Optics. Vladimir Sacek. 2006-07-14. 2009-07-05.
  8. http://www.adaptall-2.org/lenses/55B.html About adaptall-2.org – the 500mm F/8 Tele-Macro Catadioptric
  9. Web site: Advanced Techniques for Measuring Primary Mirrors for Astronomical Telescopes . Burge, J.H. . 1993 . Ph.D. Thesis, University of Arizona . p. 168.