SU1649303A1 - Photometric reducer - Google Patents

Abstract

The invention relates to photometry and can be used in conducting energy tests of optoelectronic and photometric instruments. The aim of the invention is to expand the dynamic depth of the luminance factor. Optical radiation through the input diaphragm hole 2 and the first diffuse scattering screen 4 hits the reflecting faces of the reflecting cavity - pyramid 1. After multiple reflections, the radiation hits the adjustable aperture 6 and the transparent scattering screen 7. The change in the size of the aperture 6 allows the attenuation of the photometric attenuator to be adjusted . Again, repeatedly re-repelling from the edges of the pyramid 1 in the second part of it, the radiation through the diffuse screen 8 and the outlet 2 comes out of the attenuator. 1 il. % And

Description

about

about

//

t

F

with about

Soo

The invention relates to photometry and can be used when conducting energy tests of optoelectronic and photometric instruments.

The purpose of the invention is to expand the dynamic range of the attenuation coefficient of the brightness.

The drawing shows a diagram of the photometric attenuator.

In the reflecting popsicle 1 with the input 2 and output 3 diaphragm holes, there are successively scattering screens 4 and 5, between which there is a variable diaphragm 6 and a transparent scattering screen 7. The reflecting cavity 1 is made in the form of a pyramid with specular edges. The axes of symmetry of the mirror pyramid, the diaphragm holes, the screens and the diaphragms lie on the same straight line that passes along the 0-0 optical axis of the attenuator.

The operation of the device is as follows.

Optical radiation, the brightness of the rays of which, Lee, x, through the input diaphragm hole 2 and the first diffusely scattering screen 4 hits the mirror edges of the reflecting cavity-pyramid J, after repeated re-reflections from which passes through the aperture 6 and the transparent scattering screen 7. Then again many times reflected from the faces of the pyramid 1 in the second part of it and through the second screen 6 and the output diaphragm hole 2, the radiation comes out of the attenuator

Example. The specific implementation of the proposed device was carried out on the basis of the construction of two blocks connected in series with each other with a minimum gap. Each block consists of four flat mirrors of the same size (10x1 Ox xl00 mm3) interconnected along the largest sides perpendicular to one another, forming a four-sided pyramid with an internal mirror surface, the faces of which are the reflecting surfaces of the mirrors. In the first block to the entrance

five

0

five

0

five

0

five

0

five

A transparent screen of matted fluorite is mounted, on which the input diaphragm $ is attached. 10 mm. In the second block, similar screens are glued to the end of the inlet and outlet. The output diaphragm of $ 10 mm is glued to the screen at the exit of the unit. Between the blocks (into the gap) a replaceable diaphragm is inserted along the guides. The diameter of the diaphragm is 1,2,4,5,8, 10 mm, which provides the range of the attenuation coefficient for the radiation of an LG-66 laser (A 0.6328 µm; $ 5 mm bundle); K 2.7s1SG2- 0.5. °

An additional advantage of the proposed attenuator is that it provides a uniform illumination of the output diaphragm orifice and, therefore, of the receiving surface of the next element of the optical circuit (the installation or device in which it is used). This allows the attenuator to be used as a diffuser, a diffusor (at a brightness attenuation factor of about 1.0) directly in front of the radiation receiver to eliminate the zone sensitivity of the latter. When using the device as a diffuser, the irregularity of the illumination over the sensitive area of the radiation receiver, of a size of 10x10 mm, is no more than 0.5%.

Claims (1)

Invention Formula A photometric attenuator made in the form of a reflecting cavity with inlet and outlet diaphragm holes with diffusely reflecting screens located on the optical axis of the attenuator, characterized in that, in order to broaden the dynamic range of the attenuation coefficient, the reflecting cavity is made in the form of a pyramid with mirrored edges , inside which an optical diaphragm and a diffusing screen are installed on the optical axis at an equal distance from the input and output diaphragms, with all the screens in full transparency.