SU1052854A1 - Method and apparatus for inspecting optical cat's eye - Google Patents

Abstract

1. A method of controlling optical retroreflectors, which are based on the fact that a comparison is made of the light flux reflected by the light reflector in the direction of the radiation source, and the light flux incident on the retroreflector, due to the fact that , in order to ensure the possibility of separate control of light transmission and manufacturing errors of the retro-reflectors, the total reflected light flux is recorded and the ratio of this flux to the flux incident on the retroreflector, which is judged And the ratio of luminous flux reflected by the reflectors in the direction of the radiation source to the total reflected light beam, on which is judged on fabrication errors. 2. A device for monitoring optical light reflectors, comprising successively located one optical axis a illuminator, a beam splitter, a pinhole and an objective, and two photodetectors optically coupled to a beam splitter, characterized in that it is provided with a second beam splitter installed during the reflected light flux between a diaphragm and a lens; and a third photocapture optically coupled to a second beam splitter.

Description

The invention relates to a measuring technique and can be used to control optical light reflectors (reflectors), such as, for example, CORNER (prism and hollow), mirror-lens and others. There is a method of controlling optical light reflectors based on measuring the ratio of energy the intensity of the light reflected in the direction of the radiation source to the energy flux in the plane of the entrance pupil of the light reflector 1 3. The disadvantage of this method is the absence of the possibility of separate control. ol light transmittance (transparency) and inaccuracies IZGOTOB laziness reflectors, as axial energy force of the reflected light depends on the radiation losses due to absorption within the material and reflection on c nitsah section and the angular distribution of the radiation due Nogo geometrical inaccuracy of manufacture - reflectors. This does not allow identifying the cause limiting the quality of the retroreflector and determining the ways of its elimination. The closest to the proposed technical essence is the control of the optical retroreflectors, which consists in comparing the light flux reflected by the retroreflector and the light source. of the flux incident on the light returning C 2. A disadvantage of the known method is also the impossibility of separate control of the light transmission and errors and the preparation (deviations by geometrically predetermined shape) light ™ returners. A device for controlling optical light reflectors, made in the form of an autocollimator Cl, is known. The closest to the proposed / Goma technical essence is a device for controlling optical light reflectors, containing successively located on the same optical axis the illuminator, a beam splitter, a pinhole and an objective, and two optically coupled photodetectors with a beam splitter G. J A disadvantage of the known devices is the impossibility of separating, full control of light transmission and errors in the manufacture of light reflectors. The purpose of the invention is to ensure the possibility of separate control of light transmission and errors in the manufacture of light reflectors. This goal is achieved in that according to the method of controlling optical light reflectors, which consists in comparing the light flux reflected by the light reflector in the direction of the radiation source, and the light flux incident on the light reflector, register the full reflected Color flow and measure the ratio of this flux to the flux incident on the retroreflector by which light transmittance is judged, and the relation of the luminous flux reflected by the retroreflector in the direction of the source is emitted and, to the total reflected light flux, from which manufacturing errors are judged. This goal is achieved by the fact that the device for controlling optical optical reflectors, containing successively on one optical axis, an illuminator, a splitter; a point aperture and a lens, and two photodetectors, optically coupled to the beam splitter, are equipped with a second beam splitter, installed during the reflected light beam between the diaphragm and lens, and a third photodetector, optically coupled to the second beam splitter. The drawing shows a schematic diagram of a device that implements a method for controlling optical optical-optical receivers. The device comprises an illuminator sequentially located on the same optical axis, comprising a radiation source 1 and a capacitor 2, a light divider 3, a point mirror 4, a light divider 5 and a lens b, photodetectors 7 and 8 optically connected to the light divider 3, and a third photodetector 9 optically coupled to the beam splitter 5. The method for monitoring the optical light reflectors is carried out as follows. The luminous flux of the radiation source 1 is collected when the capacitor 2 is switched on, the beam splitter 3 passes and J) OKycHpyeTCH into the hole aperture 4 installed in the focal plane of the lens b. A part of the radiation incident on the beam splitter 3 is directed to the photodetector 7 optically coupled to it. With the known reflection factors of the beam splitter E, the transparency of the after part of the optical layout of the device and the area of the working aperture of the light reflector 10 is proportional to the light flux or luminous intensity coming into the hole of the pinhole 4, or the light flux, falling to the frame on the retroreflector 10. The radiation coming out of the hole of the dot dT of afragma 4 passes the light divider 5, count The lens 6 is chosen to be limited by a parallel beam to a controlled retroreflector 10. The diameter of the lens 6 is chosen larger than the transverse size of the working aperture of the retroreflector 10. The luminous flux reflected by the retroreflector 10 passes the objective b and reaches the beam splitter 5, which has transverse dimensions exceeding The aperture of the reflected beam in its plane. A part of the total reflected by the light reflector radiation, taking into account the reflection coefficient of the beam splitter 5, is directed to the optical Him photo detector 9 and registers Ruets them. The output signal H2 of the photo detector 9 is proportional to the entire European flux reflected by the returning light 10. The measured ratio K1 of the signal I2 proportional to the reflected flux to the signal I1 proportional to the light flux, 1padc) to the retroreflector 10, determines the transparency or light transmission of the monitored retroreflector 10, t . light transmission K1 Another part of the reflected light flux passes through the beam splitter 5 and hits the pinhole 4. If the light reflector 10 does not have manufacturing defects, the reflected rays propagate parallel to the incident light and all the reflected radiation passes through the hole of the point diaphragm 4. It returns light back 10 has defects from izgoto, then this leads to an angular redistribution (change in the direction of the line) of the energy of the reflected beam and then a part of the rays (Rays A and B), distributed at angles greater than Chimie than the angle that is with the optical axis of the beam exiting the aperture at the point of pinhole 4, misses the pinhole aperture 4 and zkranirovan its opaque portion. The aperture sizes of the pinhole 4 are chosen from the condition of the required accuracy of controlling the retroreflectors, since they oppose the permissible deviations of the reflected rays from the direction of the paddy rays, which, in turn, are related to the production of the retroreflectors, and also determine the correlation of energy rays transmitted and shielded by the diaphragm. The rays reflected in the direction of the radiation source, i.e. Those that have passed through the hole of the pinhole 4 are transmitted by the beam splitter 3 to the photodetector 8 optically coupled to it. reflected by the retroreflector, which does not have errors (within the limits of the accuracy of the experiment) and its application. Then, control the ratio of K2 signals OF and I2, i.e. K2 IZ .., P ° portions of the light fluxes reflected in the direction of the radiation source 1 and the total reflected light flux can be judged on the accuracy of manufacturing the retroreflector 10. The magnitude K2 does not depend on the light transmission K1, since its transmission affects the reflected light equally streams. Detected by signals I2 and IZ. Thus, the proposed method and device, realizing this method, makes it possible to identify the causes, limiting the quality of the light reflectors and to determine the ways of their elimination. This reduces the cost of production of light reflectors and provides an objective assessment of their quality.

Claims (2)

1. The method of control of optical retroreflectors, which consists in comparing the light flux reflected by the retroreflector in the direction of the radiation source and the light flux incident on the retroreflector, characterized in that, in order to provide the possibility of separate control of light transmission and manufacturing errors of retroreflectors, register the total reflected luminous flux and measure the ratio of this flux to the flux incident on the light returning device, which judges the light transmission, and the ratio s light flux reflected by the reflectors in the direction of the radiation source to the total reflected light beam, on which judge the manufacturing errors. 2. A device for monitoring optical retroreflectors, comprising a illuminator, a beam splitter, a pinhole and a lens, and two photodetectors optically coupled to a beam splitter, which is equipped with a second beam splitter installed during the reflected light flux between a diaphragm and a lens, and a third photodetector optically coupled to a second beam splitter.