KR20090028044A - System for measuring surface vibration using interferometer and method therefor - Google Patents

Abstract

A surface vibration measurement system using an interferometer and a method thereof are provided to lower volume by comprising minimum optical and electrical components and applying the system on the other measuring meter or sensor besides surface acoustic wave. A surface vibration measurement system using an interferometer comprises: a light generating unit(10) generating the light; an optical fiber(20) proceeding the generated light; and an optical detection unit(30) detecting interference signals between the light again reflected in the end of the optical fiber and the light reflected in a medium in which surface acoustic wave progresses. The light generation unit is a laser diode. In the optical fiber, the end is reflected and coated.

Description

System for Measuring Surface Vibration using Interferometer and Method therefor}

The present invention relates to a surface vibration measurement system and method using an interferometer, and more particularly, to be applied to the measurement of the acoustic wave required for the development or characterization of the surface acoustic wave application device, the amplitude of the surface acoustic wave using the principle of the optical interferometer The present invention relates to a surface vibration measurement system and method using an interferometer that can effectively measure information such as frequency, phase, or the like with a minimum configuration.

Surface acoustic wave (SAW) devices are devices that use sound waves that propagate through a solid surface, and are widely used as electric band pass filters, acoustic optical devices, or pressure sensors.

1 shows a basic structure of a surface acoustic wave device. A comb-shaped interdigital transducer (hereinafter referred to as IDT) is fabricated on a substrate made of a piezoelectric material, and an electric signal is applied to the substrate. Sound waves proceed. This sound wave signal is converted back to an electrical signal at the second electrode.

At this time, the conversion efficiency of the electric-sound wave or the sound-wave-electricity is influenced by the frequency of the electric signal, the period of the IDT electrode, or the speed of the sound wave, and can be converted efficiently only at a frequency satisfying the phase matching condition.

Therefore, only a specific frequency among the various frequency components of the input electrical signal is detected at the output stage, and the other frequency components are converted to heat or reflected back. This is the principle of electrical bandpass filters.

In addition, even when a signal of a constant frequency is input, when another object comes into contact with the piezoelectric material or when the pressure or temperature condition changes, the sound wave velocity of the piezoelectric material changes, so that the phase matching condition is changed and the signal size at the output terminal is changed. The surface acoustic wave sensor is applied to this phenomenon.

On the other hand, in the optical element using the surface acoustic wave, the optical waveguide structure is also fabricated on the substrate itself to control the wavelength or polarization of the transmitted light by allowing the light traveling through the waveguide to react with the sound wave.

In the case of a non-destructive inspection for inspecting a defect of a specific object, a surface acoustic wave is sent to the object to be inspected, and a sound wave reflected by the surface defect or the like is measured.

Since surface acoustic waves were discovered by Lord Rayleigh in 1887, a great deal of research has been done on the measurement of surface acoustic waves.

As one of them, there is a light diffraction method by surface waves as shown in FIG. As shown in FIG. 2, the reflection angle of the laser light obliquely incident on the surface is changed by the momentum of the acoustic wave. In other words, by measuring the angle of reflection or transmission and the intensity of the light, it is possible to predict the period and amplitude of the acoustic wave.

However, in order to obtain the absolute value of the period and amplitude of the acoustic wave, a lot of additional information such as refractive index and diffraction efficiency of the medium is required. In particular, the analysis is very complicated when the elastic wave itself is composed of several frequency components.

Another measuring method is a method using a Doppler Vibrometer for measuring the Doppler frequency shift value of reflected light. This method can measure the amplitude or velocity of a vibrating object, and it is possible to obtain information in a two-dimensional region through a laser scan.

However, there is also a problem that can be measured only for the vibration of a single frequency, the vibration of several MHz or more has a problem that the measurement is difficult and expensive measuring equipment.

In addition, there is a method of measuring the reflection angle of the laser by the acoustic wave using a short laser pulse, but since the equipment is expensive and indirectly calculates information about the displacement, it is difficult to put to practical use because it is inaccurate.

The problem to be solved by the present invention is to solve the above problems, and is suitable for the case where the displacement is smaller than the wavelength of light and the vibration frequency is high (100 kHz or more), such as surface acoustic waves, and has better performance than the prior art. It is to provide a surface vibration measuring system and method.

Another problem to be solved by the present invention is to solve the above problems, to provide a measurement system with a small volume and economical consisting of a minimum of optical and electrical components.

Another problem to be solved by the present invention is to solve the above problems, using a simple feedback circuit having a fast response speed surface vibration measurement system and method that can directly read the displacement value due to vibration in real time To provide.

Another object of the present invention is to solve the above problems, and to provide a surface vibration measuring system and method that can be applied to other measurement systems or sensors in addition to surface acoustic waves.

The present invention relates to a surface vibration measurement system using an interferometer, comprising: light generating means for generating light; An optical fiber for propagating the generated light; Light detecting means for detecting an interference signal between the light reflected back from the end of the optical fiber and the light reflected from the medium through which the surface acoustic wave travels; It includes.

Preferably, the light generating means is characterized in that the laser diode (Laser Diode).

Also preferably, the optical fiber is characterized in that the end is coated with a reflection.

Also preferably, a collimator is mounted at the end of the optical fiber.

Also preferably, the light detecting means may include a function of measuring a distance between the end of the optical fiber and the medium using the detected interference signal.

Also preferably, it further comprises any one of an optical coupler (Coupler) and an optical circulator (Optical Circulator).

Also preferably, feedback means for analyzing the interference signal and transmitting a distance adjustment signal between the end of the optical fiber and the surface of the medium such that the light output is expressed as a linear function of the vibration displacement of the medium; And an actuator configured to receive the distance control signal to adjust a distance between the optical fiber end and the surface of the medium. It characterized in that it further comprises.

Also preferably, the feedback means feeds back the maximum magnitude of the alternating current component of the interference signal.

Also preferably, the linear function is a linear function represented by the following equation.

In the above equation, I (t) represents the intensity of light, R ₁ and R ₂ represent the reflectance at the end of the optical fiber and the actual reflectance when the light is reflected from the medium and re-entered into the optical fiber, and A (t ) Represents the displacement of the acoustic wave.)

Also preferably, the actuator is characterized in that the piezoelectric element that can adjust the length of the optical fiber according to the applied voltage.

And preferably, the actuator includes a function of scanning the wavelength between the optical fiber end and the surface of the medium by a quarter wavelength or more to obtain an absolute value of the vibration displacement by standardizing the light output.

On the other hand, the present invention relates to a surface vibration measurement system using an interferometer, the light generating means for generating light; Ray separating means for separating the generated light; A lens for refracting a part of light separated by the light beam separating means to be reflected in a medium in which surface acoustic waves travel; Reflecting means for reflecting back the other part of the light separated by said light separating means; And light detecting means for detecting an interference signal between the light reflected back from the reflecting means and the light reflected from the medium through which the surface acoustic wave travels; It includes.

Preferably, feedback means for analyzing the interference signal and transmitting a position adjustment signal of the reflecting means such that the light output is expressed as a linear function of the vibration displacement of the medium; And an actuator configured to receive the position adjustment signal and adjust the position of the reflecting means. It characterized in that it further comprises.

Also preferably, the feedback means feeds back the maximum magnitude of the alternating current component of the interference signal.

And preferably, the actuator comprises a function of scanning the position of the reflecting means by a quarter wavelength or more to obtain the absolute value of the vibration displacement by standardizing the light output.

On the other hand, the present invention relates to a surface vibration measurement method using an interferometer, (a) by generating light to proceed to the inside of the optical fiber, the light reflected back from the optical fiber end and the light reflected from the medium through which the surface acoustic wave proceeds Causing interference; (b) detecting the interfering signal; (c) using the detected interference signal to adjust the distance between the optical fiber tip and the surface of the medium such that the light output is expressed as a first-order function of vibration displacement of the medium; And (d) outputting surface acoustic wave information; It includes.

Preferably, the step (c) comprises the steps of: (c-1) feeding back the maximum amount of the alternating current component of the interference signal; Characterized in that it comprises a.

And preferably, in the step (c), (c-2) scanning the distance between the optical fiber ends and the surface of the medium by 1/4 wavelength or more to obtain the absolute value of the vibration displacement by normalizing the light output (c-2) step; Characterized in that it comprises a.

According to the present invention, an effect is suitable when the displacement is smaller than the wavelength of light, such as surface acoustic waves, and the vibration frequency is high (100 kHz or more).

According to the present invention, while having a minimum optical and electrical components, it has an excellent performance than the prior art, and has the effect of providing a small and economical measurement system.

According to the present invention, there is an effect of directly reading the displacement value due to vibration in real time using a simple feedback circuit having a fast reaction speed.

According to the present invention, there is also an effect that can be applied to other measuring systems or sensors in addition to the surface acoustic wave.

Before describing the details for carrying out the present invention, it should be noted that configurations that are not directly related to the technical gist of the present invention are omitted within the scope of not distracting the technical gist of the present invention.

In addition, the terms or words used in the present specification and claims are consistent with the technical spirit of the present invention on the basis of the principle that the inventor can appropriately define the concept of the term in order to explain the invention in the best way. It should be interpreted as meaning and concept.

Hereinafter, the measuring principle of the surface vibration using the optical fiber interferometer according to the present invention will be described with reference to FIGS.

FIG. 3 is a schematic diagram illustrating a measurement principle of surface vibration using an optical fiber interferometer according to an embodiment of the present invention, and FIG. 4 is an exemplary diagram of displacement and output signal measurement results over time.

As shown in FIG. 3, in an embodiment of the present invention, a fiber interferometer is used to directly measure the displacement of the surface acoustic wave over time.

Part of the laser light generated from the laser diode is reflected back at the glass-air interface at the end of the single mode fiber, and part is reflected at the surface of the medium through which the surface acoustic wave propagates. The interference signal of the two lights is detected by a detector, and the distance d between the optical fiber and the medium is measured therefrom.

The single mode optical fiber is an optical fiber designed to transmit a single beam of light, and has a low data loss compared to a multi mode optical fiber, and thus is mainly used for long distance signal transmission.

In the present invention, there is little signal processing by keeping the average distance between the single mode optical fiber and the medium at a constant value through an appropriate feedback circuit at all times. This method is very effective when the displacement is always smaller than the wavelength, such as surface acoustic waves, so that the displacement information can be converted into the intensity of the output light as it is.

4 shows an example of the measurement result, it can be seen that the final signal obtained at the output of the measurement system shows the displacement of the surface acoustic wave over time as it is. This means that the existing measuring devices can show the information of displacement over time as it is, unlike the average displacement, the center frequency, or the center wavelength of the seismic wave.

In addition, since the interferometer structure in the present invention as shown in FIG. 3 has a structure in which two interfering light passes through an optical fiber of exactly the same path except for the air layer having a thickness d, the change in polarization that is experienced here is exactly matched. The size is always kept at maximum. That is, the polarization passing through the optical fiber is easily changed so that the problem of unstable visibility of the interference signal does not occur.

Therefore, the surface acoustic wave measuring system according to the present invention has a minimum optical and electrical configuration and is a device for directly reading the displacement of the surface acoustic wave, and in addition to the elastic wave of a constant frequency, the amplitude of the randomly changing elastic wave can be read in real time. have.

The wavelength information of the acoustic wave can be obtained by scanning the optical fiber probe in the direction of the elastic wave, and in this case, the wavelength can be measured not only with the average wavelength but also with each position, thereby maximizing usefulness. In particular, since the probe of the measurement system is made of a flexible fiber, the accessibility to the measurement target is excellent, and the reliability of the measurement result is improved by minimizing the influence of ambient electromagnetic waves.

Hereinafter, the configuration of the surface vibration measurement system using the optical fiber interferometer according to an embodiment of the present invention will be described with reference to FIGS.

5 is an overall configuration diagram of a surface vibration measurement system using an optical fiber interferometer according to an embodiment of the present invention, Figure 6 is an enlarged view of a portion of the optical fiber probe according to an embodiment of the present invention.

As shown in FIG. 5, the surface vibration measuring system using the optical fiber interferometer according to an embodiment of the present invention includes a light generating means 10, a single mode optical fiber 20, a 50/50 coupler 21, and a photodetector. Means 30, feedback means 40, actuators 50, mounts 51 and output means 60.

The light generating means 10 is a step of generating the interference light, and generates light to proceed into the single-mode optical fiber 20.

The light generating means 10 is preferably a laser diode (Laser Diode) for generating a laser light.

The laser light may be implemented as a semiconductor waveguide laser such as a vertical cavity surface emitting laser or a distributed feedback laser (DFB laser).

The distributed feedback laser is a laser having a resonator that has a wavelength selectivity by allowing an optical waveguide to have a periodic structure, and the speed of light transmitted inside the optical fiber is the same so that the signal waveform does not collapse.

Next, the single mode optical fiber 20 causes the light generated by the light generating means 10 to proceed therein, so that a part of the propagated light is reflected back at the glass-air interface at the end, and the other part is a surface. The acoustic waves are reflected at the surface of the traveling medium.

In an embodiment of the present invention, the optical fiber is set as the single mode optical fiber 20, but the technical spirit of the present invention is not limited thereto.

Preferably, the reflectance may be increased by applying an appropriate reflective coating to the end of the single mode optical fiber 20.

In addition, by mounting a collimator (not shown in the figure) at the end of the single-mode optical fiber 20, the amount of light reflected from the surface of the medium through which the surface acoustic wave propagates back into the single-mode optical fiber 20 It is desirable to maximize.

The collimator is an optical device for forming parallel light rays, and when light is incident on the focal plane of the objective lens from the eyepiece side with a mark such as a slit, pinhole, or crosshair of the eyepiece, the light beam exits the objective lens and becomes a parallel light beam.

Next, the 50/50 coupler 21 distributes the light generated by the light generating means 10.

The 50/50 coupler 21 may be set as a conventional optical coupler (Coupler).

In order to maximize the size of the detected interference signal, the 50/50 coupler 21 preferably distributes the light by 50% based on the light intensity, but is not limited thereto.

In addition, the present invention may be implemented as an optical circulator (not shown in the figure) in order to distribute the light generated by the light generating means 10 instead of the 50/50 coupler 21. .

The optical circulator is a circulator using a Faraday effect in a transparent magnetic material. It arrange | positions like an optical insulator and it is common to comprise using a bipolar polarizing prism instead of a polarizing prism.

As shown in FIG. 5, when the 50/50 coupler 21 is used, the optical fiber is composed of four strands, so light loss occurs in one strand thereof. On the other hand, the optical circulator is generally composed of three optical fibers, there is an advantage that there is no loss of light.

Next, the light detecting means 30 detects the interference light from the single mode optical fiber 20.

Since the distance between the optical fiber end and the medium can be measured from the detected interference light, the principle of directly calculating the displacement of the surface acoustic wave using the measured distance between the optical fiber end and the medium will be described in detail.

When the interval between the end of the single mode optical fiber 20 and the medium is d, d may be expressed as Equation 1 below.

In Equation 1, d ₀ represents the distance between the end of the single-mode optical fiber 20 and the medium in the absence of the acoustic wave, and A (t) represents the displacement of the surface acoustic wave.

The intensity of the light output reaching the light detecting means 30 can be expressed by Equation 2 below.

In Equation 2, R ₁ and R ₂ respectively represent reflectances at the ends of the single mode optical fiber 20 and actual reflectances when reflected from the medium and re-entered into the single mode optical fiber 20.

At this time, in order to extract A (t), under the condition of A (t) < λ (in the case of surface acoustic waves, these conditions are generally satisfied). Equation 2 can be approximated as in Equation 4 below.

In Equation 4, since the intensity of the light output is expressed as a linear function of the surface acoustic wave amplitude, it can be seen that the displacement A (t) of the surface acoustic wave can be directly observed without special signal processing.

Next, the feedback means 40 analyzes and feeds back the signal detected from the photodetecting means 30 to maintain the condition of Equation (3).

When the condition of Equation 3 is satisfied, Equation 4 is established while the change amount of I (t) is maximum for a given A (t). By using this property, the distance control signal is transmitted to the actuator 50 in the direction in which the magnitude of the alternating current (AC) component of the signal detected from the photodetector 30 is maximized.

By moving the actuator 50 according to the transmitted distance control signal, the condition of Equation 3 can be maintained.

Since d ₀ is sensitive to ambient vibration or temperature change, it is preferable to operate the feedback loop at a speed of 10 Hz to 1000 Hz.

Next, the actuator 50 adjusts the distance between the single mode optical fiber 20 and the medium through which the surface acoustic wave travels.

Specifically, as described above, when the distance control signal is received from the feedback means 40 or when the absolute value of the displacement is obtained, the actuator 50 may adjust the distance between the single mode optical fiber 20 and the medium. Adjust.

In order to obtain the absolute value of the displacement, C ₁ and C ₂ in Equation 4 should be determined, which can be easily obtained by changing d ₀ . That is, in Equation 2, C ₁ and C ₂ may be determined from the maximum and minimum values of I (t) while changing d ₀ by at least 1/4 wavelength.

C ₁ and C ₂ Since the wavelength or reflectance of light or the like affecting the value is almost a fixed value, it is sufficient to determine the C ₁ and C ₂ by scanning d ₀ only once as necessary.

Preferably, the actuator 50 may be implemented as a piezoelectric element.

Since the actuator 50 according to the present embodiment has a small amount of movement such as moving on the wavelength scale of the surface acoustic wave, it is effective to use a piezoelectric element.

Next, the mount 51 performs a function of supporting the actuator 50.

Finally, the output means 60 outputs information on the surface acoustic wave by using the signal detected from the photodetecting means 30.

As described above, the output means 60 may output the distance between the single mode optical fiber 20 and the medium or directly display the displacement according to the time of the surface acoustic wave. Also, the absolute value of the surface acoustic wave displacement may be output, and the average wavelength information of the surface acoustic wave and the wavelength information according to the position of the medium may be output.

The output means 60 is preferably set to an oscilloscope.

Hereinafter, the experimental results of the surface vibration measurement system using the optical fiber interferometer according to an embodiment of the present invention will be described with reference to FIGS. 7A to 7B.

7A is a schematic configuration diagram of a vibration measurement experiment of a cone by a piezoelectric transducer (hereinafter referred to as PZT), and FIG. 7B is a graph showing the results of vibration measurement experiments.

A distributed feedback laser was used as a light source for generating the interference light, and a displacement of A (t) = A ₀ sin (wt) was given to the PZT by applying an electric signal of 1.4 MHz and 10 V.

And, as shown in Figure 7a, the vibration of the cone surface attached to the PZT disc (Disc) was measured. This cone is a sound wave generator used in fiber optic acoustooptics.

When the distance d ₀ between the fiber probe and the cone is changed using an XYZ translator, the waveform obtained on the oscilloscope in each case is shown in FIG. 7B.

In FIG. 7B, the average intensity and amplitude of the optical signal vary according to the change of the value of d ₀ , which is consistent with the result predicted by Equation 2 above. In particular, in the case of the waveform c shown in the center of FIG. 7B, the amplitude thereof is maximum, and the output waveform also appears closest to the sine function. This is the case where the condition of [Equation 3] is satisfied.

The vibration displacement of the seismic wave is measured at about 100 nm.

As described above, it can be seen that if the feedback circuit is configured such that the AC amplitude of the light output is maximized, the situation as in the waveform c of FIG. 7B can be stably maintained.

Meanwhile, the present invention may be implemented using a free space Michelson interferometer instead of the above-described optical fiber interferometer.

Hereinafter, a surface vibration measurement system using a free space Michelson interferometer according to another embodiment of the present invention will be described with reference to FIG. 8. It is to be noted that the components of the surface vibration measuring system using the optical fiber interferometer and the components having the same function or function are omitted as much as possible and the same identification numbers are assigned.

8 is a block diagram of a surface vibration measurement system using a free space Michelson interferometer according to another embodiment of the present invention.

As shown in FIG. 8, the surface vibration measurement system using the free space Michelson interferometer according to another embodiment of the present invention includes a light generating means 10, a light detecting means 30, a feedback means 40, and an actuator. 50, an output means 60, a light beam separating means 70, a lens 71 and a reflecting means 72.

The light detecting means 30 detects an interference signal between the light reflected back from the reflecting means 72 and the light reflected from the surface of the medium through which the surface acoustic wave travels.

Next, the actuator 50 is similar to the case of the embodiment of the present invention described above, by adjusting the position of the reflecting means 72, the light output of the light detecting means 30 is 1 of the vibration displacement of the medium. It can be expressed as a difference function.

Next, the light beam separating means 70 separates the light generated from the light generating means 10, so that a part of the separated light proceeds to the lens 71, and the other part of the light is the reflecting means 72. Proceed to).

In addition, the light separation means 70 refracts or reflects the light reflected from the surface of the medium through which the surface acoustic wave propagates through the lens 71 and the light reflected back from the reflecting means 72 to detect the light. Proceed to the means 30.

The light beam splitter 70 may be implemented as a conventional beam splitter.

A beam splitter is an optical device that divides incident light bundles into two or more using intensity or spectral lines. Half mirrors are used for dividing by intensity, and color screening mirrors are used for spectroscopically.

Next, the lens 71 refracts the light separated by the ray separator 70 so that the surface acoustic wave can be reflected on the surface of the medium through which the surface acoustic wave propagates. The reflected light is refracted by the light separator 70 and proceeds to the light detecting means 30.

Next, the reflecting means 72 reflects the light separated by the light separator 70 back to the light detecting means 30 through the light separator 70.

Hereinafter, a method of measuring surface vibration using an optical fiber interferometer according to an embodiment of the present invention will be described with reference to FIG. 9.

9 is a flowchart illustrating a method of measuring surface vibration using an optical fiber interferometer according to an embodiment of the present invention.

First, as shown in FIG. 9, by generating light and distributing the generated light, the distributed light may cause interference (S10).

A part of the light distributed in the step S10 is reflected back at the end of the optical fiber, and the other part is reflected at the surface of the medium through which the seismic wave propagates, and these two lights cause interference.

Next, the generated interference signal is detected (S20).

Next, the distance between the end of the optical fiber and the surface of the medium is adjusted (S30).

In the step S30, the distance between the optical fiber ends and the medium is measured, and the light output is expressed as a linear function of the vibration displacement of the medium by using the same. It is meant to be read directly.

Finally, surface acoustic wave information is output (S40).

The information output in step S40 may be a distance between the end of the optical fiber and the medium, the vibration displacement of the surface acoustic wave or the absolute value of the surface acoustic wave displacement over time.

Steps S20 to S40 as described above may be repeatedly performed, and the procedure is performed after step S40 to step S20.

As described above and described with reference to a preferred embodiment for illustrating the technical idea of the present invention, the present invention is not limited to the configuration and operation as shown and described as described above, it is a deviation from the scope of the technical idea It will be understood by those skilled in the art that many modifications and variations can be made to the invention without departing from the scope of the invention. Accordingly, all such suitable changes and modifications and equivalents should be considered to be within the scope of the present invention.

1 is a schematic diagram of the basic structure of a surface acoustic wave element;

2 is a schematic diagram of an optical diffraction method using surface waves according to the prior art.

Figure 3 is a schematic diagram showing the principle of measurement of surface vibration using an interferometer according to an embodiment of the present invention.

4 is an exemplary view of a displacement and output signal measurement result with respect to time according to an embodiment of the present invention.

5 is an overall configuration diagram of a surface vibration measurement system using an optical fiber interferometer according to an embodiment of the present invention.

6 is an enlarged view of a fiber optic probe portion in accordance with an embodiment of the present invention.

7A is a schematic configuration diagram of an experiment for measuring vibration of a cone by PZT.

7B is a graph showing the results of vibration measurement experiments.

8 is an overall configuration diagram of a surface vibration measurement system using a Michelson interferometer according to another embodiment of the present invention.

9 is an overall flow chart of the surface vibration measurement method using an interferometer according to an embodiment of the present invention.

Claims (18)

In the surface vibration measurement system using an interferometer, Light generating means (10) for generating light; An optical fiber for propagating the generated light; Light detecting means (30) for detecting an interference signal between the light reflected back from the end of the optical fiber and the light reflected from the medium through which the surface acoustic wave travels; Surface vibration measurement system using an interferometer. The method of claim 1, The light generating means (10) is a surface vibration measurement system using an interferometer, characterized in that the laser diode (Laser Diode). The method of claim 1, The optical fiber is surface vibration measurement system using an interferometer, characterized in that the end of the reflective coating. The method of claim 1, Surface vibration measurement system using an interferometer, characterized in that the collimator is mounted at the end of the optical fiber. The method of claim 1, The optical detection means (30) is a surface vibration measurement system using an interferometer, characterized in that it comprises a function for measuring the distance between the end of the optical fiber and the medium using the detected interference signal. The method of claim 1, Surface vibration measurement system using an interferometer further comprises any one of an optical coupler (Coupler) and an optical circulator. The method of claim 1, Feedback means (40) for analyzing the interference signal and transmitting a distance adjustment signal between the optical fiber end and the surface of the medium such that the light output is expressed as a linear function of the vibration displacement of the medium; And An actuator (50) for receiving the distance control signal to adjust a distance between the optical fiber end and the surface of the medium; Surface vibration measurement system using an interferometer, further comprising. The method of claim 7, wherein The feedback means (40) is a surface vibration measurement system using an interferometer, characterized in that for feeding back the maximum size of the alternating current component of the interference signal. The method of claim 7, wherein The first-order function is a surface vibration measurement system using an interferometer, characterized in that the first-order function represented by the following equation.

In the above equation, I (t) represents the intensity of light, R ₁ and R ₂ represent the reflectance at the end of the optical fiber and the actual reflectance when the light is reflected from the medium and re-entered into the optical fiber, and A (t ) Represents the displacement of the acoustic wave.) The method of claim 7, wherein The actuator (50) is a surface vibration measurement system using an interferometer, characterized in that the piezoelectric element that can adjust the length of the optical fiber according to the applied voltage. The method of claim 7, wherein The actuator 50 includes a function of scanning the distance between the optical fiber end and the surface of the medium by a quarter wavelength or more to obtain an absolute value of the vibration displacement by normalizing the light output. Surface vibration measurement system. In the surface vibration measurement system using an interferometer, Light generating means (10) for generating light; Ray separating means for separating the generated light 70; A lens (71) for refracting a part of light separated by the light beam separating means (70) so that the surface acoustic wave is reflected in the traveling medium; Reflecting means (72) for reflecting back the other part of the light separated by the light separating means (70); And Light detecting means (30) for detecting an interference signal between the light reflected back from the reflecting means (72) and the light reflected from the medium through which the surface acoustic wave travels; Surface vibration measurement system using an interferometer. The method of claim 12, Feedback means (40) for analyzing the interference signal and transmitting a position adjustment signal of the reflecting means (72) such that the light output is expressed as a linear function of the vibration displacement of the medium; And An actuator (50) for receiving the position control signal to adjust the position of the reflecting means (72); Surface vibration measurement system using an interferometer, further comprising. The method of claim 13, The feedback means (40) is a surface vibration measurement system using an interferometer, characterized in that for feeding back the maximum size of the alternating current component of the interference signal. The method of claim 13, The actuator 50 includes a function of scanning the position of the reflecting means 72 or more by a quarter wavelength or more to obtain an absolute value of the vibration displacement by normalizing the light output. system. In the surface vibration measurement method using an interferometer, (a) generating light and traveling inside the optical fiber, such that the light reflected from the optical fiber ends and the light reflected from the medium through which the surface acoustic wave travels cause interference; (b) detecting the interfering signal; (c) using the detected interference signal to adjust the distance between the optical fiber tip and the surface of the medium such that the light output is expressed as a first-order function of vibration displacement of the medium; And (d) outputting surface acoustic wave information; Surface vibration measurement method using an interferometer comprising a. The method of claim 16, In step (c), (c-1) feeding back the maximum amount of alternating current components of the interference signal; Surface vibration measurement method using an interferometer, characterized in that it comprises a. The method of claim 16, In step (c), (c-2) scanning the distance between the optical fiber end and the surface of the medium by a quarter wavelength or more to obtain an absolute value of the vibration displacement by normalizing the light output; Surface vibration measurement method using an interferometer, characterized in that it comprises a.

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