SU381057A1 - PHOTOELECTRIC AUTOCOLLIMATION DEVICE - Google Patents

Description

The invention relates to a measuring technique, and to photoelectric autocollimation devices.

Lime photoelectric autocollimation devices containing a Radiation source with switched luminous zones, a condenser, a lens and a mirror installed in the course of the rays, a photon receiver that imitates a beam of rays reflected from a mirror, and an electronic signal processing circuit from a photodetector.

In order to increase the sensitivity and accuracy of the measurement, the proposed device is equipped with lighting and receiving grids of alternating transparent and opaque strokes with uniform schag, installed in the focal plane of the lens, and in one of the halves of any lattice the strokes are shifted one relative to the other by Polo, one step, and a condenser the hook is set, that the image of one of the zones of the radiation source is projected on one half of the lighting grid, and the image of the second zone of the glow is on the other half at this lattice.

FIG. 1 shows schematically the proposed ycTpoiiCTLo; pas figs. 2 - the location of the strokes on the lighting and receiving grids.

The photoelectric autocolli M1a tion device contains a source of radiation 2 supplied with a power source 1 with alternating current switched zones of a spark 1: a condenser 3 installed during the rays, a mirror 4 and a lens 5 placed in the focal plane of the lens 6 and a receiving 7 grating perceiving a beam reflected from the mirror rays photodetector 8, the electronic signal processing circuit; a photodetector, including an amplifier 9 and a phase-sensitive rectifier 10, and a recording device //. The lighting and gratings are

from alternating transparent and opaque strokes with uniform pitch, in one of the halves of any lattice, the strokes are shifted one relative to the other by a half step. Condenser 3 is installed so that

the image of one of the luminescence zones of the radiation source 2 is projected onto one half of the lighting grid 6, and the image of the second luminescence zone onto the other half of this grid.

The device works as follows.

When the power source's radiation source 2 is turned on (a luminaire of a gleaming discharge) with an alternating current of the zone of negative cathode luminescence, it changes its position depending on the sign of the supply voltage. Accordingly, the halves of the lighting grid 6 are alternately illuminated by the radiation source. The autocollimator lens 5 projects the enlarged autocollimation image of the grid 6 into the ilkos of the receiving grids 7. In the steering position of the image of the dark strokes of the grid 6, the transparent strokes of the grid 7 half overlap the light streams from each of the halves of the grids equal in magnitude, and the signal at the output of the sensitive glow is half broken. is equal to zero, since the antiphase components of the signal are equal. When the mirror 4 is rotated from the zero position around the axis, parallel to the axis of the gratings, the image of the grating 6 is mixed in the focal plane of the objective 5, the perpendicular direction of the strokes. The luminous flux, aperture w, from one half of the lighting grid 6, increases and decreases from the other, which causes a change in the ratio of yush, compared to half-periods compared with a phase-sensitive rectifier. A signal appears at the output of the device. 5 10 15 20 25 proportional to the angle of the angle of the mirror. 4. Subject of the invention Photoelectric autocollimator device containing a radiation source with alternating current switched zones of light, a condenser, a lens and a mirror installed in the course of the rays, a photodetector, perceived, reflected from the mirror beam of and an electronic signal processing circuit from a photodetector, characterized in that, in order to increase the sensitivity and accuracy of measurement, it is equipped with lighting and receiving grids of alternating from transparent and opaque strokes with a uniform pitch, installed in the focal plane of the lens, with the strokes in one of the halves of any lattice shifted from one another by half of the schaga, and the condenser is installed so that the image of one of the glow zones of the radiation source is projected on one half of the lighting lattice and the image of the second zone of the glow is on the other half of this lattice.