SU1078396A1 - Coherent optical radiation splitting and modulation method - Google Patents

Abstract

THE METHOD OF SPLITTING AND MODULATING COHERENT OPTICAL RADIATION, including the operation of the excitation in the light-acoustic duct of a traveling ultrasonic wave propagating at an angle to the light flux, tl and h ay; u and so that, in order to increase the splitting angle while maintaining the same difference in the frequencies of the diffracted beams, the second ultrasonic traveling wave, directed towards the first one, is excited at the angle equal to the two Bragg angles, while ®1 2 /. where 2 first and second Bragg angles respectively.

Description

g 3. :

u in (If) JfVv) ZvM JfCtr ff)

This invention relates to acoustooptics and is intended for splitting and modulating coherent optical radiation in laser Doppler instruments measuring the speed of gas and liquid streams.

A known method of uncoupling and modulating coherent optical radiation consists in exciting a traveling ultrasonic wave propagating at the Bragg angle to the light flux in the light-sound duct. In this case, the Brzgg diffraction occurs and the light beam is split into two, diverging under the ANGLE, the value of which is determined by the ratio of the wavelengths of light and sound. At the same time, the frequency modulation of the diffracted beam occurs by an amount equal to the sound frequency,.:.

The disadvantage of the known method is that in order to increase the splitting angle, it is necessary to increase the ultrasound frequency, which leads to an increase in the frequency difference between the split beams. .

The purpose of the invention is to increase the splitting angle while maintaining the same frequency difference of the diffracted beams. . V

This goal is achieved in that according to the method of splitting and modulating coherent optical radiation, which includes the operation of the excitation in the light-acoustic duct of the traveling ultrasonic sound wave propagating at a Bragg angle to the light flux, the second traveling ultrasonic wave, directed in the opposite direction by the angle, is excited by the angle of the light beam, and directed by the angle at the angle of the light beam, the second traveling ultrasonic wave, directed in the opposite direction by the angle, is excited by the angle of the light beam, and the second traveling ultrasonic wave, directed in the opposite direction by the angle of the light beam, excites the second traveling ultrasonic wave directed towards the light beam with an angle that is angled with an angle of the light beam, directed towards the light flux. m sum of two Bragg angles, and U2 where Q and bl - the first and second Bragg angles, respectively ..

 The drawing shows a scheme for implementing the method.

In the drawing it is indicated: 1 - light-eukopgh) of waters, 2 - piezoelectric transducers / 3 - absorbers of ultrasonic vibrations.

In the light and sound circuit 1 using

Piezo transducers 2 excite two ultrasonic waves propagating towards each other at an angle equal to the sum of the angles в and Q, where ff and Q are the angles between the direction of propagation of the light flux and the wave fronts of the first and second ultrasonic waves, respectively, Bragg angles. At the same time, 0% Absorbers 3 ensure 5 k) T mode of traveling ultrasonic wave.

The light beam JQ (v) incident on the light-sound conductor is split into three beams: undifferentiated

Q Jq and diffracted j 4 and. In addition, each diffracted beam is modulated by the corresponding frequency of ultrasonic vibrations. , Choosing the frequency of ultrasound

5 oscillations are quite high with a small difference between them, it is possible to obtain a large splitting angle, while maintaining a small difference in the frequencies of the diffracted beams.

For example, in the manufacture of an optical glass optical fiber STF-3, to obtain a splitting angle of 2 for a modulation frequency difference of 10 MHz, ultrasound frequencies equal to

5 80-90 MHz.

A split-angle of 5 was obtained on the KS-5 light-sound duct with a modulation frequency difference of 5 MHz and an ultrasound frequency of 60-65 MHz. Di-

The fractional efficiency of split beams in both cases was 30%.

The present invention makes it possible to obtain a large mezwid angle with split light beams with a small difference in the frequencies of their modulation.

Claims (1)

THE METHOD OF SPLITTING AND MODULATION OF COHERENT OPTICAL RADIATION, including the operation of excitation of a traveling ultrasonic wave propagating at the Bragg angle to the light flux in the light and sound pipe, differs; in order to increase the splitting angle., while maintaining the same difference in the frequencies of the diffracted beams, a second traveling ultrasonic wave is excited in the light guide, directed towards the first at an angle equal to the sum of the two Bragg angles, 4 ®2 where G ^ and Q ₂ are the first and second Bragg angles, respectively.