Product Code Database
An Uppendahl prismD.R. Patent Nr. 195467, 7. Februar 1907 is an erecting prism, i.e. a special reflection prism that is used to invert an image (rotation by 180°). The erecting system consists of three partial prisms made of optical glass with a high refractive index cemented together to form a symmetric assembly and isR. Liebmann: Geradsichtige Feldstecher-Prismenumkehrsysteme ohne oder mit nur geringem Achsversatz, In: Optik Nr. 26, Heft 3, 1967/1968, Seite 264. used in microscopy as well as in binoculars technology.
In the past the Uppendahl prism system, for example in the Trinovid binoculars series from Leitz (since 1986 Leica Camera), PROPERTIES AND PERFORMANCE OF THE NEW LEICA TRINOVID 7X35B (=HERE NAMED RETROVID) COMPARED WITH OLDER LEITZ-LEICA TRINOVIDS AND WITH BINOCULARS FROM BECK, FOTON AND THE NEW KOWA 6,5X32. February 2020 by Dr. Gijs van Ginkel was commercially offered in some binoculars. The Trinovid series binoculars were introduced in 1958 and used at the time patented moving internal optical lenses between the ocular lens group and the prism assembly within the housing for focusing. US Patent US3484149A Center focusing prism binocular and reticle Like the much more common optical lenses located between the objective lens group and the prism assembly method, this central internal focussing method does not change the volume of the binoculars. Bausch & Lomb Elite and Browning 7×35 binoculars, both made in Japan during the late 1980s to early 1990s, also used Uppendahl prisms.
In the early 2020s the commercial market share of Uppendahl prism type standard binoculars was nil. Binoculars dealer summary, showing 1,011 listed binoculars that all use other optical designs in September 2022 The Leica Geovid R (laser) rangefinder binoculars series and 7×24 Rangemaster monocular using a (modified) Uppendahl prism system were still commercially available. LEICA GEOVID R Technical Data, August 2022
An advantage of this prism system is that the light beam only passes two transitions between air and glass, which minimizes losses in the form of Fresnel reflections. The relatively strong folding of the beam path in the Uppendahl prism, which is only comparable with the compact Schmidt–Pechan prism system, supports the construction of compact optical instruments with short overall lengths.
The transmission of the prism can be further improved by using a dielectric coating rather than a metallic mirror coating. This causes the prism surfaces to act as a dielectric mirror. A well-designed dielectric coating can provide a reflectivity of over 99% across the visible light spectrum. This reflectivity is much improved compared to either an aluminum or silver mirror coating and the performance of the Uppendahl prism is similar to the Porro prism or the Abbe–Koenig prism.
The necessary mirror coating not only adds a manufacturing step, but it makes the Uppendahl roof prism lossier than the other image erectors using Porro prism or Abbe–Koenig prism that rely only on total internal reflections. A dielectric mirror coating is comparable in reflection effectivity, but makes the Uppendahl more expensive.
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