SU890854A1 - Acoustic device for shifting light irradiation frequency - Google Patents

Abstract

An ACOUTOPTICAL DEVICE FOR OPTICAL RADIATION FREQUENCY SHIFT, containing an acousto-optic cell, a tunable high-frequency oscillator, electrically connected to the said cell, and a polar, located on the optical output of the acousto-optic cell, which was removed by a problem, which was removed by a problem; the output of the device when changing the shift frequency and the ambient temperature, it additionally contains a second acousto-optic cell, similar to the first, electrically A ski connected to the generator, located at the output of the polaroid parallel to the first cell and rotated relative to it by 180 in the diffraction plane, with the polaroid i SL and the second acousto-optic cell located in the region of the minimum intersection of the diffracted and nondiffracted radiation at the output of the first cell .: 00 x about 00 ate 4

Description

2. Acousto-optic device according to Claim 1, characterized in that it comprises two high-frequency oscillation power controllers,

one of which is connected between the generator and the first acousto-optic cell, and the other between the generator and the second acousto-optic cell.

The invention relates to acousto-optical devices designed to shift the frequency of optical radiation in laser Doppler velocity measurement systems, devices operating on the principles of optical heterodyning, etc. Acousto-optical device for shifting the frequency of optical radiation containing a crystal from photoelastic material is known the opposite ends of which are the first and second piezoelectric transducer in the same acoustic channel and the third piezoelectric transducer and sound absorber another acoustic channel Cl. The closest in technical essence to the present invention. is an acousto-optic device for shifting the frequency of optical radiation, containing an acousto-optic cell, a tunable high-frequency oscillator, electrically connected to a cell, and a polaroid located on the optical output of the acousto-optic cell 2}. In this device, the frequency of the shear varies by oscillating the frequency of the oscillator, however, this leads to a change in the angle of deflection of the diffracted radiation. In addition, when the sound speed changes in the event of a change in the ambient temperature, there will also be a change in the deflection angle. A disadvantage of the known device is the presence of spatial and angular displacement of radiation when the shift frequency and the ambient temperature change. The aim of the invention is to eliminate the spatial and angular displacement of radiation when the device exits as the shear frequency and ambient temperature change. To achieve this goal, in a known acousto-optic device for shifting the frequency of optical radiation, containing an acousto-optic cell, a tunable high-frequency oscillator, an electric circuit connected to the cell, and a polaroid located on the optical output of the acousto-optic cell, an additional acousto-optic cell, similar to first electrically connected to the generator, located at the output of the polaroid parallel to the first cell and rotated relative to it and 180 in the diffraction plane, the floor roid and second acoustooptic cell is arranged in the region of minimum mutual divergence of the diffracted and non-diffracted radiation at the output of the first cell. The device may additionally contain two power regulators of high-frequency oscillations, one of which is connected between the generator and the first acousto-optic cell, and the other between the same generator and the second acousto-optic cell. FIG. 1 shows a diagram of the device, and FIG. 2 - vector diagram of anisotropic diffraction in paratellurite. The device contains a first acousto-optic (AO) cell 1, a second AO cell 2, a polaroid 3, a first power controller 4, a second power controller 5, a generator of 6 HF oscillations and an optical radiation source 7, in particular a laser located at the Bragg angle cell 1. AO cell 2 is located at the exit of pore roida 3 in the region of the minimum divergence of two light rays at the output of cell 1, i.e. the distance between the first and second cells is minimal. The device works as follows. The electric inputs of cells 1 and 2 from generator 6 are given an HF signal of frequency I. In this case, in both cells, slow shear sound waves are excited, propagating along the 110 axis cells from paratellurite in parallel and towards each other. When podchke on AO cell 1 flat-polarized radiation with a frequency W from the laser (7) it is anisotropic diffraction on the sound wave with the polarization plane of the diffracted radiation being rotated by 90. At the same time, the frequency of the diffracted radiation is shifted by the frequency UJ and propagated is under

Claims (2)

ACOUSTOPTIC DEVICE FOR SHIFTING THE FREQUENCY OF OPTICAL RADIATION, comprising an acousto-optic cell, a tunable high-frequency oscillator, electrically coupled to the named cell, and a polaroid located at the optical output of the acousto-optical cell, characterized in that, in order to eliminate spatial and angular radiation at the output device when changing the shear frequency and the ambient temperature, it further comprises a second acousto-optical cell, similar to the first, electrically linked to a generator located at the exit polarizer parallel to the first cell and rotated relative thereto through 180 ° in the diffraction plane, and a second polaroid acousto-optical cell arranged in the region of minimum mutual divergence of the diffracted and non-diffracted radiation at the output of the first cell. 2. The acousto-optic device according to claim 1, characterized in that it contains two power regulators of high-frequency oscillations, one of which is connected between the generator and the first acousto-optic cell, and the other between the generator and the second acousto-optic cell.