SU1318974A1 - Device for observing images recorded as diffraction stripes with different angular orientations - Google Patents

Abstract

The invention relates to devices for obtaining JI optical image analysis. The purpose of the invention is to improve the performance of the device by obtaining images for all directions of the diffraction bands of an object. The mask 6 is made in the form of an opaque disk with a transparent sector with a corner angle of 90. The optical density of a sector changes in the direction of its arc. The radiation from source 1 transmitted through the forming optical system 2, mirror 3 and projection optical system 4 undergoes diffraction on object 5. Rotation of the radiation intensity from all local areas of object 5 by means of mask 8 of mask 6 round the optical axis. 9 fixing the position of the mask 6 provides, with a corresponding position, a signal for reading. On the recorder 7, a halftone image of the diffraction grating recorded on object 5 is formed. f-ly, I ill. c (L Measurement of transparency oo 00 QO 4

Description

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The invention relates to devices for obtaining and analyzing optical fibers.

The purpose of the invention is to increase productivity by acquiring images for all directions of diffraction bands simultaneously.

The drawing shows a diagram of a device for observing images.

The device contains radiation source 1 arranged along the radiation, forming the optical system 2, mirror 3, projection optical system in the form of a focusing of his objective 4, object 5, on which the optical image is recorded in the form of diffraction bands with different orientations, the mask 6 installed in the image plane the focusing lens 4, the recorder 7, the means 8 for discrete rotation of the mask 6 around the optical axis by 180 ° and the means 9 for fixing the position of the mask 6.

The mask 6 is made in the form of an opaque disk, provided with a sector 10 with an apex angle of 90, the transparency of which varies along the arc of the sector. Forming optical system 2, mask 6 and projection optical system 4 lie on the same optical axis.

The radiation source 1 can be made either as a coherent radiation source — a laser, or as a source with a continuous spectrum equipped with a narrowband light filter. The recorder 7 can be made in the form of photographic film or in the form of an ocular window through which visual observations can be made.

The means 8 of rotation of the mask 6 around the optical axis by 180 can be performed as an analog — continuous rotation and as a discrete x45 half-tone image of a diffraction, and if necessary, synchronization of the registration moments and the angular position of the mask 6 can be introduced.

The means 9 for fixing the position of the mask 6 with the sector 1 O can be made in the form of an optocoupler pair.

The change in transparency along the arc of sector 10 of mask 6 can be carried out both discretely and continuously from full transmission to full absorption (maximum optical density).

The device works as follows.

Radiation from the source 1 of the visible range, such as a Type-LG-56 laser (63 µm), is fed through a forming optical system 2, a mirror 3 and a projection optical system 4 to an object 5 on which an optical image (for example, a spatial structure of a coherent beam) is recorded as diffraction bands having different orientations from O to 90.

 5 Radiation that has undergone diffraction from object 6 is collected by a focusing lens 4, guided into a plane and mask 6 is mounted. Mask 6 is rotated around the optical axis using rotation means 8. When radiation passes through mask 6 and the spatial position of sector 10 changes (its rotation around the optical axis) during rotation

 the mask 6 is produced by the modulation of radiation intensity from all local areas of the object 5, depending on the angles at which the radiation diffracted by the reflected object

0 5, and the angular position of the sector 10.

The intensity is modulated as a result of falling into a plane, the mask of 6 beams of radiation from

g local Site object 5 under

different diffraction angles to portions of sector 10, having transparency varying along the arc of the sector. As a consequence, on the recorder 7 of the jQ image, a picture of the picture recorded on the object 5 is built in the form of an integral for all directions of diffraction strips simultaneously. Thus, on the recorder 7

of the grating recorded on object 5 and depicted by diffraction bands on object 5, in which the difference in orientation of the diffraction bands is converted to the difference in the illumination of image points on the register, the torus, with this diffraction order of zero, does not fall on the recorder 7, but zarkalom 3. When measuring the illumination distribution in the plane of the recorder 7, it is necessary to take the ratio of local illumination with mask 6 installed in the device and without it.

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The rotation of the mask 10 eliminates the influence of the inhomogeneity of the radiation from source 1, as well as the inhomogeneity of the illumination of the diffraction grating of the object 5 and the variations of its diffraction ecch) of efficiency. The means 9 for fixing the position of the mask 6 with the sector 10 provides a signal for reading when the mask 6 is in the corresponding position.

Claims (2)

1. A device for observing images recorded in the form of diffraction strips with different angular orientation, containing an illumination system located along the optical axis in the form of a radiation source and a forming optical unit. Editor V. Danko Order 2508/40 Compiled by S. Shigalovich Tehred M. Khodanich Proofreader A.Zimokosov Circulation 521 Subscription VNIIPI USSR State Committee for inventions and discoveries 113035, Moscow, Zh-35, Raushsk nab., 4/5 Production and printing company, Uzhgorod, st. Project, 4 974 .4 holder of information carrier, as well as a mask and photo recorder in the form of a focusing lens and photodetector device, which differs 5 s that, in order to increase performance by simultaneously obtaining images for all directions of the diffraction bands of an object, the mask is installed with the possibility of discrete rotation at an angle of 180 in the image plane focusing lens and is made in the form of an opaque disk with a transparent sector, the angle of which at the apex is  5 90, while the sector is made with a varying optical plane in the direction of its arc. 2. A device according to claim 1, characterized in that it is provided with a means for fixing the position of the mask.