SU1195327A1 - Reflex camera - Google Patents

Abstract

A MIRRORAL PHOTO-EQUIPMENT containing a lens, a swiveling mirror, a viewfinder and an exposure meter with a photodetector. located behind the lens, in order to improve the accuracy of exposure determination by increasing the luminous flux incident on the photodetector and simplify the design, the swivel mirror is made in the form of a luminescent concentrator, the beam splitting coating is applied to the surface of the photodetector and the photodetector is installed at one of the ends of the luminescent concentrator. sl c: with QF1 CO e

Description

1 The invention relates to a photographic technique, namely to mirror cameras, whose exposure meter detects the luminous flux transmitted through the lens. The purpose of the invention is to improve the accuracy of exposure determination by increasing the luminous flux incident on the photodetector, and to simplify the design. FIG. 1 is a diagram of a mirror camera using a luminescent concentrator in an exposure metering system; in fig. 2-4 — Sizes of a luminescent concentrator of various designs. The camera contains a lens 1, a film channel 2, a viewfinder 3, a swivel mirror including a plate 4, a photodetector 5, the swivel mirror is made in the form of a thin plate 4 of transparent material, for example glass, which has a surface facing the lens 1J has a beam-splitting coating 6. A layer 7 of luminescent material is deposited on the dark side of the plate 4. All the ends of the plate 4 are stained, except for the lower end, opposite which in close proximity is the photodetector 5. The spectral characteristics of the emission of the luminescent layer 7 and the sensitivity of the photodetector 5 should coincide if possible. In another embodiment, the design of the swivel mirror plate 4 is made of silicate or organic glass with the addition of rhodamine or other dye. In this case, the luminescent layer 7 may be absent. FIG. 2 shows the principle of operation of a luminescent concentrator made in the form of a luminaire glass plate 4. When irradiated with light 8 of one of the numerous centers of 9 luminescence, it begins to radiate in all directions. The rays 10 and 11 of the luminescence emerge from the plate 4, and the rays 12 and 13 fall on the inner surfaces of the plate at angles exceeding the Brewster angle, and as a result begin to spread along the plate 4, eventually reaching the photodetector 5. The concentrator 72 can be made in the form of a plate 4 made of a transparent material, in which a layer 7 of luminescent material is applied on a dark (Fig. 3) or front (Fig. 4) surface. In all cases, the ends of the plate 4 have a mirrored layer 14, except for one end, which houses the photodetector 5. As a beam-splitting coating 6, a layer of metal, such as aluminum, can be used, the thickness of which determines the ratio of reflected and transmitted flows. This ratio may vary widely and is selected depending on the energy parameters of the exposure meter. An interference coating can also be used as a beam-splitting coating 6, the spectral characteristics of which are chosen in such a way that it transmits radiation corresponding spectrally to the absorption bands of the phosphor used in the luminescent concentrator, and the rest of the stream is reflected into the viewfinder 3. The device works as follows in a way. The radiation from the subject through the lens 1 falls on the beam-splitting coating 6. Most of the flux is reflected by layer 6 to the viewfinder 3. A small part of the radiation passes through layer 6 and causes the luminescence of Coating 7. Radiation from it propagates through plate 4, leaves the bottom end of the plate and falls on the photodetector 5 of the exposure device. If the camera works with a flash lamp, the radiation, the mined mirror 4, is reflected by the film or shutter curtain (lamellae) (not shown) and recorded by the same receiver 5. In real systems, depending on the purpose of the camera, its class, etc. . other modifications of the luminescent concentrator with the photodetector may be used. At the same time, the luminescent film (Fig. 3 and 4) or the luminescent additive (Fig. 2) may not occupy the entire area (or the entire volume), but only certain portions of the plate 4. Receiver 5 may be placed directly on the plate's free 3-layer layer 4 on optical contact, etc. Thus, the use of a mirror made in the form of a luminescent concentrator with a beam-splitting coating in the camera simplifies the system for diverting the radiant energy to the exposure meter, makes it more accurate, makes it possible to use the same receiver in systems that record the flow through the lens when normal lighting, and the stream reflected from the frame window when working with a flash lamp, also does not prevent the use of interchangeable viewfinders.

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Claims (1)

A MIRROR PHOTO APPARATUS containing a lens, a swivel mirror, a viewfinder and an exposure device with a photodetector located behind the lens, characterized in that, in order to increase the accuracy of determining exposure by increasing the light flux incident on the photodetector and simplifying the design, the rotary mirror is made in in the form of a luminescent concentrator with a beam splitting coating applied to the surface of the lens and a photodetector installed at one of the ends of the luminescent end trattoria. zj 5, ^ 7 Fig. 1