SU731863A1 - Acoustooptic device for deflecting optic radiation and shifting radiation frequency - Google Patents

Abstract

ACOUSTOPTIC DEVICE FOR THE DEFLECTION OF OPTICAL RADIATION AND SHIFT OF ITS FREQUENCY, including a crystal from a photoelastic material. At the opposite ends of which, in the first acoustic canape, the first piezoelectric transducer and absorber are located, differing in that, in order to increase the stability of the deflection angle of optical radiation in a wide temperature range, it additionally contains a second acoustic channel parallel to the first, as well as the second and third piezoelectric transducers located at the ends of the crystal in the second acoustic channel, an amplifier and a device for turning the frequency, and the input of the amplifier connect (L C to the third piezoelectric transducer, output to the second transducer, and through the device to turn the frequency to the first transducer. from 00 O) with

Description

This invention relates to acousto-optic devices designed to deflect optical radiation and shift its frequency in optical information processing systems, laser Doppler velocity meters, optical systems such as filtering, etc. The optical beam control devices are known f 1 J. The closest to the invention The technical solution is an acoustically optical device containing a crystal from a photoelastic material, on the opposite ends of which a piezoelectric is located in one acoustic channel transducer and absorber. A piezoelectric transducer is coupled to a high frequency oscillator. However, such a device has a relatively low stability of the angle of deviation associated, in particular, with the dependence of the speed of sound in a crystal on temperature and having, for example, a value of about 10 for TeO crystals, from deg. Here, it should be noted that in addition to the environment, the temperature of the crystal is influenced by the power output of the piezoelectric transducer, which in a continuous mode can reach values of the order of 3-5 watts. The various methods used for heat stabilization in this case lead to a complication and increase in the size of the acousto-optic device, which inevitably leads to a change in the optical path as a whole. At the same time, the stability of the deflection angle is a very important parameter in processing systems. formations, in laser doppler velocity gauges. The purpose of the invention is to increase the stability of the angle of deviation of optical radiation when the temperature changes over a wide range. The goal is achieved by the fact that the known device additionally contains a second acoustic channel parallel to the first, second and third piezoelectric transducers located at the indicated ends of the crystal in the second acoustic channel, an amplifier and a device for the frequency, and the amplifier input is connected to the third piezoelectric transducer , the output to the second transducer and through the device for increasing the frequency to the first transducer. A frequency multiplier, a heterodyne mixer, a tunable parametric oscillator connected in series with a frequency multiplier, etc. can be used as a device for increasing the frequency. The drawing shows the proposed device for bulk acoustic waves. The device contains a crystal of the photoresist material 1, the first piezoelectric transducer 2, the second piezoelectric transducer 3, the third piezoelectric transducer 4, the absorber 5, the amplifier 6 with a gain exceeding the conversion loss in the channel of the second 3 and third 4 transducers, frequency multiplier 7. The first transducer 2 and the absorber 5 are located in the first acoustic channel, the second 3 and third 4 transducers are located in the second acoustic channel parallel to the first one. The source of optical radiation is located under the Bragg angle to the direction of acoustic wave propagation in crystal 1 (in some cases this angle may be different, for example, in the Raman – NATO mode). The proposed device works as follows. When the amplifier 6 is turned on on the plate of the converter 3, a noise voltage arises, which is converted into acoustic oscillations propagating along the crystal 1 in the second acoustic channel and exciting an electric voltage on the converter 4. At the same time, the electric voltage coming from amplifier 6 through frequency multiplier 7 to converter 2, excites in crystal 1 another acoustic wave propagating in the first acoustic channel. At the end of the transient process, a standing acoustic wave is established in the amplifier circuit with a driving frequency f, and

Claims (1)

ACOUSTOPTIC DEVICE FOR DEFLECTING OPTICAL RADIATION AND SHIFT OF ITS FREQUENCY, including a crystal of photoelastic material, at the opposite ends of which in the first acoustic channel there is a first piezoelectric transducer and an absorber, characterized in that, in order to increase the stability of the angle of deviation of optical radiation in a wide range of optical radiation temperatures , it additionally contains a second acoustic channel parallel to the first, as well as the second and third piezoelectric transducers, located conjugated on the ends of the crystal in the second acoustic channel, an amplifier and a device for increasing Toty · hour, the amplifier input 'connected to the third piezoelectric transducer, the output - to the second transducer and through the device for increasing the frequency - the first inverter. SU „„ 731863