SU744296A1 - Apparatus for investigating optical irregularities - Google Patents

Description

The dyons of the zones through amplifiers with variable gain factors are pairwise connected to the inputs of subtractive circuits, the outputs of which are connected to the inputs of the recording device and to the inputs of executive mechanisms. The invention is illustrated in the drawing, which shows a block diagram of the device. It consists of a light source I, a slit light diaphragm 2, a condenser (photosensitive zones) 3, a collimator 4, a receiving lens 5, a shadow knife 6, a photographic lens 7, a television transmitting camera 8, amplifiers with adjustable gain factors 9-12, difference schemes 13 and 14, matching amplifiers 15 and 16, actuators 17 and 18, and the recorder 19. The device operates as follows. A parallel beam of light from the collimator 4 passes through the medium under study (material) and enters the input of the receiving lens 5. In the back focal plane of lens 5, an image of the light diaphragm 1 is formed. This image is formed on the working surface of the shadow knife 6 and blocks the photosensitive zones 3. Light flux received by the photosensitive zones, is converted into an electrical signal, which is fed to the inputs of amplifiers with adjustable gain factors 9-12, from the outputs of which the signals are received n and the inputs of the difference circuits 13, 14. The outputs of the circuits 13, 14 form the difference signals equal to:, (8, K, -8, /,}, where Ef) is the illumination of the photoconductive zone; в - sensitivity of the photoconductor; S (2) is the area of overlap of zone 3 of the image of the light diaphragm 2; 1 (2) - transfer factors of amplifiers 9-12. These signals through the matching amplifiers 15, 16 are fed to the input of the recording device 19 and to the actuators 17, 18, which move the knife in the corresponding directions until the difference signals become zero. This position corresponds to the optimal adjustment of the instrument and is roughly determined by the size of the photoconductive zones. The fine adjustment is performed by varying the transmit gains of the amplifiers 9, 12.. 1 the modulation of the light flux transmitted through the medium manifests itself in a change in the image of the light aperture 2, which corresponds to obtaining images of irregularities on the screen of the recording device 19. The time for changing the image shape of the light diaphragm is much smaller than the response time of the actuators 17, 18, therefore the instrument allows such irregularities to be recorded as images. When extensive inhomogeneities get into the working volume or when exposed to temperature, hydrostatic and other interference, there is a long or constant displacement of the image of the light diaphragm relative to the photoconductive zones 3, which leads to the formation of difference signals and triggering of actuators 17, 18. The difference signals from extended inhomogeneities are usually much higher frequencies than signals caused by temperature and hydrostatic interference, so they are easily separated into matching x preamplifier 15, and 16 are input to the recording device 19, and low-frequency signals are supplied to actuators 17, 18 which keep the width of the open part of the image light aperture equal initial setup of the device for maximum sensitivity. High frequency signal. reflecting extended inhomogeneities from the output of the matching amplifier 15, 16, enters the recording device 19, where it is converted into a one-dimensional signal. Thus, eliminating the influence of interference on sensitivity, the device allows to increase the case rate of recording heterogeneity with dimensions smaller than the diameter of the inlet opening of the obtktivktivktiv 5 in the form of images and group heterogeneities with dimensions of bbc less than the input diameter of the lens 5 in the form of one-dimensional signal. The device replaces a shadow device with larger lens input diameters, which reduces the weight and reduces the cost of the device. Formula and 3 b) f e and A Device for studying optical inhomogeneities, comprising a light source, a condenser, a light diaphragm, a collimator, a receiving lens, a knife, a photographic lens transmitting a television camera, a recorder, in order to increase reliability of control of inhomogeneities; photoconductive zones are applied to the working surface of the knife, the shape, size and orientation of which are consistent with the shape, size and orientation of the image of the light diaphragm, and the outputs of the zones through variable amplifiers In terms of gain factors, pairwise subcontracts to the inputs of subtractive circuits, the outputs of which are connected to the inputs of the recording device and to the inputs of executive mechanisms.

Sources of information taken into account in the examination 1. USSR author's certificate

No. 296950, cl. G 01N 21/46, 1970.

2. L. A. Vasilyev. Shadow methods, M., “Science, 1968, p. 196-201 (prototype).

Claims (1)

Claim A device for studying optical inhomogeneities, containing a light source, a condenser, a light diaphragm, a collimator, a receiving lens, a knife, a photographic lens transmitting a television camera, a recorder, characterized in that, in order to increase the reliability of monitoring the inhomogeneities, photoconductive zones are applied to the knife’s working surface , the shape, size and orientation of which are consistent with the shape, size and orientation of the image of the light diaphragm, and the outputs of the zones through amplifiers with variable gains pairwise connected to inputs of the subtracting circuits whose outputs are connected to inputs of the recording device and to the inputs of the actuators.