SU1370463A1 - Method of determining parameters of object oscillations - Google Patents

Abstract

The invention relates to a measurement technique and can be used to determine the parameters of an object's oscillations using holographic interferometry. The purpose of the invention is to increase the parameters to be determined by providing a measurement of the phase of the oscillations, expanding the range and increasing the accuracy of determining the amplitudes of the oscillations. During the time t chosen from the condition t; L: tn, rAe t. , t „- the times required to record a hologram in real time and with averaging in time, carry out the exposure of the reference and object waves of the photorefractive crystal 4. Simultaneously with the exposure, the crystal is illuminated with a wave directed towards the reference wave. As a result, a hologram is recovered during exposure. Using the photo recorder 5, the dependence of the intensity of the reconstructed wave on time is recorded, using the data obtained as a result of processing this dependence, the amplitude and phase of the oscillations of the object 6 are determined. 2 Il. (L

Description

00

one

The invention relates to a measurement technique and can be used to determine the parameters of an object's oscillations by the method of holographic interferometry.

The purpose of the invention is to increase the determined parameters of oscillations by providing -, measuring the phase of oscillations, expanding the range and increasing the accuracy of determining the amplitudes of oscillations of an object,

FIG. Figure 1 shows the optical layout of the device for carrying out the proposed method; in fig. 2 - dependence of the intensity of the recovered beam on time.

The optical scheme of the device for carrying out the method of the present invention comprises a source of coherent radiation 1, a mirror 2, a beam splitter 3, a photorefractive crystal 4, and a photographic recorder 5. At station 6, the oscillating object under study is marked.

The method is carried out as follows.

From coherent radiation source 1 via beam splitters

3 and mirrors 2 form the reference and object waves, which expose the photorefractive crystal 4, as a result of which a hologram is formed in the crystal 4. The exposure of the crystal 4 is carried out for a time t selected from the condition - t, where tj and t are the exposure times needed to obtain the hologram of the oscillating object, respectively, in real time and with time averaging. Simultaneously with the exposure the crystal is illuminated

4wave directed towards the reference wave. As a result, the hologram is restored and the reconstructed wave is recorded by the photoregistrate 5 as a dependence of its intensity over time (Fig. 2).

According to the data obtained as a result of processing this dependence, the amplitude Z of the object oscillations is determined from the ratios

 (n + 1) and / 4 +

I I

 . four

12

at Z

  four

Z a (cj t) b (a) i) I, with Zs

h

1370463 2

and the oscillation phase of the ratio

( one

 (one.

Z),

Where

 the number of fully formed local maxima, within one period of the time dependence of the intensity of the reconstructed beam; wavelength of the hologram recording light; the value of the last local maximum, measured relative to the previous minimum,

depending

about)

asi)) ib (i) 1)

the intensity of the recovered beam from time to time;

the value of the last local maximum, measured relative to the next minimum after it, depending on the intensity of the reconstructed beam on time; oscillation frequency;

the parameters of the linear portion of the dependence of the variable -component I of the normalized intensity I (t) of the reconstructed beam on the amplitude of oscillations Z, obtained by calculating the expression

Kt)

t-t

; r exp

expl

45G

. f (t Z) dt

where t is time variable; i - imaginary unit;

f (t | t) is the law of object oscillation; j is the position of the global maximum of the dependence of the intensity of the recovered beam on time;

tf (hSTG) is the cosinusoid phase with frequency u) oscillation corresponding to the position

one

Claims (1)

the global maximum of the calculated dependence of the normalized intensity I (t) in the recovered beam on time. Invention Formula The method of determining the vibration parameters of an object, which consists in exposing a photorefractive crystal to the reference and object waves, simultaneously illuminates the crystal with a wave directed toward the reference wave, restores the hologram from the crystal and records the reconstructed wave according to which the vibration parameters are defined, characterized in that, in order to increase the determined vibration parameters, expand the range and increase the accuracy of determining the vibration amplitudes of an object, exposure is performed during a time f selected from conditions Ts 1, hert t, the times needed to obtain a hologram of an oscillating object. respectively, in real time and averaged over time, and the reconstructed wave is recorded as a dependence of its intensity on time. Phie. 2