KR101761304B1 - Oscillation wavelength variable light source apparatus and measuring device using the same - Google Patents

Abstract

The present invention relates to an oscillating wavelength variable light source device in which an oscillation wavelength changes according to a change of a periodic electric signal corresponding to a different optical path for each wavelength in a resonator, and a measuring device using the oscillating wavelength variable light source device. An optical amplifier for outputting a periodic electrical signal having a cycle time obtained by dividing the optical signal by an integral multiple, an optical signal generator for performing optical generation and amplification of light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generator, And an optical path wavelength dependent optical element portion having a corresponding optical path depending on an oscillation wavelength determined by the optical path wavelength dependent optical element portion.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an oscillation wavelength variable light source device and a measurement device using the oscillation wavelength variable light source device.

More particularly, the present invention relates to an oscillation wavelength variable light source device in which an oscillation wavelength changes according to a change of a periodic electric signal corresponding to a different optical path for each wavelength in a resonator, and a measurement device using the oscillation wavelength variable light source device.

Generally, a fiber Bragg grating (FBG) sensor constituting a sensor measuring device irradiates ultraviolet rays to an optical fiber core forming a pattern (lattice) on a specific surface to induce a refractive index change at regular intervals. (Bragg wavelength), and the wavelength of the light reflected by the lattice spacing is changed.

By using these characteristics, it is possible to measure the change of the lattice spacing, that is, the strain rate, by observing the wavelength change of the reflected light when the lattice spacing is changed by the external stress.

In addition, since the optical fiber is silica-based and is not influenced by electromagnetic waves, it is an electrical insulator. Since it is small in size and light in weight, it can be mounted and inserted without affecting the function of the structure to be measured. So that remote measurement is easy.

As a method of implementing the FBG sensor demodulation system, there are a method of measuring a fiber grating wavelength by using a broadband source and a wavelength tunable filter, and a method of using a tunable laser as a light source have.

In this FBG sensor demodulating system, there is a problem that the peak of the reflected signal is low and the line width is large. In the FBG sensor demodulating system of the wavelength tunable laser, the maximum variable speed of the optical variable filter in the tunable laser There is a problem that the optical gain acquisition reaction time constantly stays at a speed of several kHz or less due to a limit that the wavelength tunable time can not keep up with.

An image measuring apparatus using spatial division of light includes optical coherence tomography (OCT), which is an apparatus for acquiring a depth direction image of a sample using coherence phenomenon of light.

The optical coherence tomographic imaging apparatus is a high-resolution imaging system capable of imaging an internal tissue section of a sample. The optical coherent tomographic imaging apparatus is a device using an interference principle of a light source in a near-infrared wavelength range.

Particularly, the optical coherent tomographic imaging technique is an image technique for non-contact imaging of the interior of a sample. Recently, related research has been actively conducted.

On the other hand, in the optical coherent tomographic imaging apparatus, the information acquisition rate in the depth direction depends on the repetition rate of the central wavelength tunable laser. On the other hand, in the optical coherent tomographic imaging apparatus, it is necessary to perform scanning on the horizontal axis and the vertical axis by using light when acquiring two-dimensional or three-dimensional images.

Accordingly, a conventional optical coherent tomographic imaging apparatus requires an optical variable filter for periodically scanning the wavelength of the laser light in the resonator to vary the wavelength.

The optical variable filter mainly uses a Fabry-Perot filter.

On the other hand, the optical variable filter has mechanical limitations in the frequency range of several hundred kHz or more and its characteristics are deteriorated.

Also, since the optical tunable filter is relatively expensive, a manufacturing cost of the optical coherent tomographic imaging apparatus is increased.

Korean Patent Publication No. 10-2011-0078766 Korean Patent Publication No. 10-2013-0023187 Korean Patent Publication No. 10-2011-0070305

The present invention solves the problems of the conventional sensor measurement apparatus and image measurement apparatus and the light source apparatus used therein, and it is an object of the present invention to provide a wavelength division multiplexing And an object of the present invention is to provide an oscillation wavelength variable light source apparatus which varies in accordance with a variation of the oscillation wavelength.

The present invention provides a light source whose oscillation wavelength changes according to characteristics of an electrical signal applied to a resonator depending on different paths for each wavelength, and is characterized in that an oscillation wavelength variable having a light source in which one or more wavelengths are periodically and repeatedly scanned over time And it is an object of the present invention to provide a light source device and a measuring device using the same.

The present invention relates to an oscillating wavelength variable light source device in which an oscillation wavelength varies according to characteristics of an electrical signal applied to a resonator depending on different paths for each wavelength without using an expensive optical variable filter for varying the wavelength of the laser light, The purpose is to provide.

The objects of the present invention are not limited to the above-mentioned objects, and other objects not mentioned can be clearly understood by those skilled in the art from the following description.

According to an aspect of the present invention, there is provided an oscillation wavelength variable light source device comprising: an electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength- An optical amplifier unit for amplifying the intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generating unit, and an optical path wavelength dependent optical element unit having a corresponding optical path depending on an oscillation wavelength determined by the optical amplifying unit .

According to another aspect of the present invention, there is provided an oscillation wavelength variable light source apparatus including an oscillation wavelength variable light source device for generating a control signal by varying a periodic period of a periodic electric signal having a periodic period divided by an integral multiple of a period of a photon corresponding to a wavelength- An optical amplifying unit that amplifies light and amplifies the light intensity and determines an oscillation wavelength by a control signal of the electric signal generating unit, an optical path unit having a corresponding optical path differently according to an oscillation wavelength determined by the optical amplifying unit, And a wavelength-dependent optical element portion.

Here, the optical amplification part is linearly positioned between the partial reflection parts that pass a part of the optical intensity and reflect the others.

And the optical amplifying part is located in a ring structure including a light distributing part for distributing the intensity of the light at a predetermined ratio.

And a circulator section for changing the traveling path of the optical amplification section light.

And an MxN light distributing unit for distributing light to oscillate a plurality of wavelengths, wherein the optical amplifying unit is linearly positioned between the partial reflectors.

The optical path-wavelength-dependent optical unit includes at least one of a prism, a chirped waveguide Bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating, (Arrayed Waveguide Grating).

According to another aspect of the present invention, there is provided an oscillation wavelength variable light source device comprising: an electric signal generator for generating a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength- An optical amplifier unit for determining the oscillation wavelength by the electrical signal of the electrical signal generator, an optical path wavelength-dependent optical amplifier unit having a corresponding optical path depending on the oscillation wavelength determined by the front- ; And

According to another aspect of the present invention, there is provided an oscillating wavelength variable light source apparatus comprising: a light source for outputting a control signal by varying a cycle time of a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength- A signal generation unit, an optical amplifier unit for amplifying the light and amplifying the light intensity, a full-wave element unit for determining the oscillation wavelength by the control signal of the electrical signal generation unit, And an optical path wavelength dependent optical element having a path.

Here, the optical amplifying part and the full-wave element part are linearly positioned between the partial reflecting parts that pass a part of the light intensity and reflect the others.

And the optical amplifying unit and the all-optical-element-added unit are located in a ring structure including a light distribution unit for distributing the intensity of light at a predetermined ratio.

And a circulator part for changing the traveling path of the optical amplifying part and the light-receiving element part.

And an MxN light distribution portion for performing optical distribution to oscillate a plurality of wavelengths, wherein the optical amplification portion and the full-wave element portion are linearly positioned between the partial reflection portions.

The optical path-wavelength-dependent optical unit includes at least one of a prism, a chirped waveguide Bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating, (Arrayed Waveguide Grating).

According to another aspect of the present invention, there is provided a measurement apparatus using an oscillating wavelength variable light source apparatus, including: an electric signal generator for outputting a periodic electric signal having a cycle time divided by an integral multiple of a period of a photon corresponding to a wavelength- An optical amplifying unit for amplifying light and amplifying the light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generating unit; and an optical path unit having an optical path wavelength having a corresponding optical path depending on an oscillation wavelength determined by the optical amplifying unit And a light source unit.

According to another aspect of the present invention, there is provided a measurement apparatus using an oscillation wavelength variable light source apparatus, the apparatus comprising: a control signal generator for generating a control signal by varying a cycle time of a periodic electric signal having a cycle time, An optical amplifier unit for amplifying light and for amplifying the light intensity and determining an oscillation wavelength by a control signal of the electric signal generator; and an amplifying unit for differently responding to the oscillation wavelength determined by the optical amplifying unit And the optical path wavelength-dependent optical element portion having the optical path for the light path portion to constitute the light source portion.

According to another aspect of the present invention, there is provided a measurement apparatus using an oscillating wavelength variable light source apparatus, including: an electric signal generator for outputting a periodic electric signal having a cycle time divided by an integral multiple of a period of a photon corresponding to a wavelength- An optical amplifier section for determining the oscillation wavelength by an electrical signal of the electrical signal generating section, and a light source for outputting a corresponding optical path differently depending on the oscillation wavelength determined by the front- And an optical path wavelength-dependent optical element unit having a light source unit and a light source unit.

According to another aspect of the present invention, there is provided a measurement apparatus using an oscillation wavelength variable light source apparatus, the apparatus comprising: a control signal generator for generating a control signal by varying a cycle time of a periodic electric signal having a cycle time, An optical amplifier section for determining the oscillation wavelength by a control signal of the electric signal generating section, and a light source for outputting an oscillation determined by the front light element section, And an optical path wavelength dependent optical element having a corresponding optical path according to a wavelength, and is characterized by a light source unit.

Here, the measuring instrument having the light source part is an image measuring instrument or a sensor measuring instrument.

The oscillating wavelength variable light source device and the measuring device using the oscillating wavelength variable light source device according to the present invention have the following effects.

First, the oscillation wavelength can be changed by the change of the periodical electric signal corresponding to the different optical path by the wavelength in the resonator.

Second, it is possible to remove the optical variable filter having the mechanical limit by changing the oscillation wavelength by the change of the periodic electric signal corresponding to the different optical path by the wavelength in the resonator.

Third, the manufacturing cost of the measuring apparatus can be reduced by replacing the expensive optical variable filter with the electric signal generating unit.

Fourth, since the electric signal generator is independent of the length of the resonator, which is the light source, it is possible to change the wavelength variable speed.

Fifth, the oscillation wavelength is changed according to the characteristic of the electrical signal applied to the resonator depending on different paths according to wavelength, thereby broadening the broadband and greatly improving the output efficiency.

FIG. 1A is a configuration diagram of an image measuring apparatus using an oscillation wavelength variable light source apparatus according to an embodiment of the present invention. FIG.
1B is a configuration diagram of a sensor measuring instrument using an oscillating wavelength variable light source device according to an embodiment of the present invention
FIGS. 2 to 6 are schematic diagrams of an oscillation wavelength variable light source device according to an embodiment of the present invention
7 to 11 are schematic diagrams of optical path wavelength-dependent optical elements of an oscillation wavelength variable light source device according to an embodiment of the present invention
12 to 16 are schematic diagrams of an oscillating wavelength variable light source device according to another embodiment of the present invention

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of an oscillating wavelength variable light source device and a measuring device using the oscillating wavelength variable light source device according to the present invention will be described in detail as follows.

The features and advantages of the oscillating wavelength variable light source device and the measuring device using the oscillating wavelength variable light source device according to the present invention will be apparent from the following detailed description of each embodiment.

FIG. 1A is a configuration diagram of an image measuring apparatus using an oscillating wavelength variable light source apparatus according to an embodiment of the present invention, FIG. 1B is a configuration diagram of a sensor measuring apparatus using an oscillating wavelength variable light source apparatus according to an embodiment of the present invention to be.

The present invention provides a light source whose oscillation wavelength varies according to characteristics of an electrical signal applied to a resonator depending on different paths by wavelength, and is intended to provide a light source in which one or more wavelengths are periodically and repeatedly scanned over time .

The present invention provides an image measuring apparatus and a sensor measuring apparatus having such a light source apparatus.

The configuration of the image measuring apparatus according to the present invention having such a light source apparatus is shown in FIG. 1A.

In the embodiment of the present invention, the optical coherence tomographic imaging apparatus is described as an example of an image measuring apparatus having an oscillating wavelength variable light source apparatus according to the present invention, but the present invention is not limited thereto.

The optical coherent tomographic imaging apparatus according to an embodiment of the present invention acquires image information of a sample using optical interference. The optical coherence tomographic imaging apparatus includes a light source unit 10a, a light separation unit 10b, a reference unit 10c, a diagnosis unit 10d, a light coupling unit 10e, and a signal processing unit 10f. It is to be understood that the present invention is not limited thereto and may include other types of configurations.

Specifically, a light separation unit 10b separates light emitted from the light source unit 10a into a first light and a second light having different paths, and a second light separation unit 10b separating the first light separated by the light separation unit 10b A reference portion 10c disposed on a path along which the first light is reflected to reflect the first light and a second portion that is disposed in a path of the second light separated by the optical separation portion 10b, A diagnostic unit 10d which reflects the first light and the second light which are generated by interference with each other through the reference unit 10c and the diagnosis unit 10d, And a signal processing unit 10f for detecting and imaging data of light received from the optical coupling unit 10e.

A configuration of a sensor measuring instrument having an oscillating wavelength variable light source device according to the present invention is shown in FIG. 1B.

In the embodiment of the present invention, the FBG sensor demodulating system is described as an example of a sensor measuring instrument having an oscillating wavelength variable light source device according to the present invention, but the present invention is not limited thereto.

An FBG sensor demodulation system according to an embodiment of the present invention includes a light source unit 11a that emits an optical signal and a light source unit 11b that receives an optical signal from the light source unit 11a and reflects a center wavelength thereof according to a physical change amount externally applied And a signal processing unit 11c for receiving the optical signal reflected from the sensing unit 11b and detecting and imaging the data.

The light source unit constituting the image measuring apparatus having the oscillating wavelength variable light source apparatus according to the present invention and the sensor measuring apparatus having the oscillating wavelength variable light source apparatus according to the present invention has the following configuration.

The light source unit is composed of a resonator type in which an oscillation wavelength is determined by an optical amplifier unit controlled by a periodic electric signal having a light element unit whose path is changed by a wavelength and a cycle time obtained by dividing a period of time of a photon corresponding to a path of the wavelength by an integral multiple .

The light source unit includes an optical amplifying unit and a resonator in which an oscillation wavelength is determined by a full-wave element unit controlled by a periodic electrical signal having an optical element unit whose path is varied by wavelength, . ≪ / RTI >

The light source unit includes a resonator in which the oscillation wavelength is changed by an optical amplification unit controlled by a change in the periodic time of the periodic electrical signal having a period of time in which an optical element unit whose path is varied by wavelength and a periodic time period . ≪ / RTI >

The light source unit includes an optical amplifier unit, an optical element unit whose path is varied by wavelength, and a light source unit which is controlled by a change in the periodic period of the periodic electric signal having a periodic time divided by integer times, But it is not limited to such a form.

로 정의할 때, 파장 별로 광의 일주 시간은 수학식 1에서와 같다.Here, the optical path along the wavelength in the resonator

, The one-week time of light for each wavelength is expressed by Equation (1).

Where n is the refractive index and c is the speed of light.

The period of the electric signal generated by the electric signal generating unit is expressed by Equation (2).

Where N is all integers.

Specifically, the first embodiment of the oscillating wavelength variable light source apparatus according to the present invention includes an electric signal generator for outputting a periodical electric signal having a cycle time obtained by dividing a period of a photon corresponding to a path for each wavelength by an integral multiple, An optical amplifying section for determining an oscillation wavelength by an electrical signal of the generating section and an optical path wavelength dependent optical element section having a corresponding optical path depending on an oscillation wavelength determined by the optical amplifying section.

The oscillation wavelength variable light source device according to the second embodiment of the present invention includes an electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a path for each wavelength by an integral multiple, And a light path wavelength dependent optical element portion having a corresponding optical path depending on an oscillation wavelength determined by the front light element portion.

First, the configuration of the oscillating wavelength variable light source device according to the first embodiment including the optical amplifying unit that performs the light generation and the amplification of the light intensity and determines the oscillation wavelength by the electric signal of the electric signal generating unit is as follows.

FIGS. 2 to 6 are block diagrams of an oscillating wavelength variable light source device according to an embodiment of the present invention.

The oscillating wavelength variable light source apparatus according to the first embodiment is provided with an optical amplifying unit which is controlled by a periodic electric signal having an optical element whose path is varied by wavelength and a periodic time period obtained by dividing the round- Is a resonator type light source device in which an oscillation wavelength is determined.

Here, the resonator-type light source device includes an optical element having a path that varies with wavelength, a reflection type optical amplifier having a linearly positioned shape, an optical element having a path different for each wavelength, Or a ring structure including an optical element having a path different for each wavelength or an optical element having an optical amplification part located at a ring structure including a light distribution part or an optical part having a path different for each wavelength and a circulator part including an optical amplification part, And the like.

More specifically, FIG. 2 illustrates an oscillating wavelength variable light source apparatus according to an embodiment of the present invention. The oscillation wavelength variable light source apparatus generates an electric signal for outputting a periodic electric signal having a cycle time, An optical amplifying section 20b for amplifying light and for amplifying the light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generating section 20a; And an optical path wavelength-dependent optical part 20c having a corresponding optical path differently depending on the oscillation wavelength.

The oscillation wavelength variable light source device shown in FIG. 3 includes an electric signal generator 30a for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength-specific path by an integral multiple, An optical amplifier 30b for performing amplification and determining an oscillation wavelength by an electrical signal of the electrical signal generator 30a; and an optical amplifier 30b having a corresponding optical path differently depending on the oscillation wavelength determined by the optical amplifier 30b And a structure in which the optical amplifying section 30b includes the optical path wavelength-dependent optical element section 30c and is linearly positioned between the partial reflecting sections 30d and 30e that pass a part of the light intensity and reflect the remaining light .

The oscillation wavelength variable light source device shown in FIG. 4 includes an electric signal generator 40a for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a path for each wavelength by an integral multiple, An optical amplifying section 40b for performing amplification and determining an oscillation wavelength by an electrical signal of the electrical signal generating section 40a, and an optical amplifier 40b having a corresponding optical path differently depending on an oscillation wavelength determined by the optical amplifying section 40b And the optical path length-dependent optical element portion 40c, and the optical amplifying portion 40b is located in a ring structure including a light distributing portion 40d for distributing the light intensity at a predetermined ratio.

The oscillating wavelength variable light source device shown in FIG. 5 includes an electric signal generator 50a for outputting a periodical electric signal having a cycle time obtained by dividing a round time of a photon corresponding to a path for each wavelength by an integral multiple, An optical amplifier 50b for performing amplification and determining an oscillation wavelength by an electrical signal of the electrical signal generator 50a, and an optical amplifier 50b having a corresponding optical path depending on the oscillation wavelength determined by the optical amplifier 50b And the optical path length-dependent optical element portion 50c, and the optical amplifying portion 50b is located in the ring structure including the circulator portion 50d that changes the traveling path of the light.

6, the variable oscillation wavelength light source device includes an electric signal generator 60a for outputting a periodic electric signal having a cycle time divided by an integral multiple of a period of a photon corresponding to a wavelength-specific path, An optical amplifier 60b for amplifying light and amplifying the light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generator 60a, an MxN optical distributor 60c for distributing light to oscillate a plurality of wavelengths And optical path wavelength dependent optical elements 60d and 60e having different optical paths depending on the oscillation wavelengths respectively constituted by the optical paths distributed by the MxN optical distributor 60c, 60b are linearly positioned between the partial reflection portion 60f and the partial reflection portions 60g, 60h.

The electrical signal generator of the oscillating wavelength variable light source according to the present invention outputs a control signal by varying the periodic time of the periodic electrical signal having a periodic time divided by an integral multiple of the period of the photon corresponding to the path for each wavelength, The amplifying unit may be configured to determine the oscillation wavelength by the control signal of the electric signal generating unit.

The optical path difference inductance element for each wavelength of the oscillation wavelength variable light source device according to the present invention has the following configuration.

7 to 11 are schematic diagrams of optical path wavelength dependent optical elements of an oscillating wavelength variable light source according to an embodiment of the present invention.

The optical path wavelength-dependent optical unit of the oscillation wavelength variable light source device according to the present invention includes a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, Grating, or an arrayed waveguide grating, but is not limited thereto.

The oscillation wavelength variable light source apparatus according to the second embodiment includes a full-wave element unit for determining an oscillation wavelength by an electric signal of the electric signal generating unit.

12 to 16 are block diagrams of an oscillation wavelength variable light source device according to another embodiment of the present invention.

The oscillating wavelength variable light source apparatus according to the second embodiment of the present invention includes an optical amplifying unit and an optical element whose path is changed by wavelength, and a cycle time obtained by dividing the rounding time of the photon corresponding to the path of the wavelength by an integer multiple Is a resonator type light source device in which the oscillation wavelength is determined by a front light element part controlled by a periodic electrical signal.

Here, the resonator-type light source device may be configured in such a manner that the optical element, the optical element, and the reflection-type optical amplifier are linearly positioned with respect to each wavelength, and the optical element, the optical element, And the amplifying part may be configured to be positioned linearly between the reflection element parts.

In addition, the resonator type light source device may have a configuration in which the optical element unit, the optical element unit, and the optical amplification unit having different paths for respective wavelengths are located in the ring structure including the optical distribution unit, or the optical element unit, And may be in a form located in a ring structure including a circulator portion.

And the light-receiving element portion is an element whose light intensity is controlled by an electric signal externally applied.

12 illustrates an oscillating wavelength variable light source apparatus according to an embodiment of the present invention. The oscillation wavelength variable light source apparatus generates an electric signal for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength- An optical amplifier unit 120c for amplifying light and amplifying the light intensity, a full-wave element unit 120b for determining an oscillation wavelength by an electrical signal of the electrical signal generator 20a, And an optical path wavelength-dependent optical element portion 120d having a corresponding optical path differently depending on the oscillation wavelength determined by the element portion 120b.

13, the oscillation wavelength variable light source apparatus includes an electric signal generator 130a for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength-specific path by an integral multiple, An optical amplification section 130c for performing amplification, a full-wave element section 130b for determining the oscillation wavelength by an electrical signal of the electrical signal generation section 130a, and an optical amplifier section 130b for determining an oscillation wavelength determined by the front- And a circulator unit 130e including an optical path wavelength dependent optical element unit 130d having a corresponding optical path and the optical amplification unit 130c and the front element unit 130b changing the path of light, Ring structure.

14, the oscillation wavelength variable light source device includes an electric signal generator 140a for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength-specific path by an integral multiple, An optical amplification section 140c for performing amplification and a front light element section 140b for determining the oscillation wavelength by the electrical signal of the electrical signal generation section 140a; And the optical amplification part 140c and the front element part 140b include a partial reflection part (not shown) for passing a part of the light intensity and reflecting the other part 140e (140f).

15, the oscillation wavelength variable light source device includes an electric signal generator 150a for outputting a periodic electric signal having a cycle time obtained by dividing a period of a photon corresponding to a wavelength-specific path by an integral multiple, An optical amplification unit 150c for amplifying the light emitted from the light source unit 150a, a full-wave element unit 150b for determining the oscillation wavelength by the electrical signal of the electrical signal generator 150a, And the optical amplification part 150c and the all-light element part 150b include a light distribution part 40d for distributing the light intensity at a predetermined ratio In the ring structure.

16, the oscillating wavelength variable light source device includes an electric signal generating unit 160a for outputting a periodical electric signal having a cycle time obtained by dividing a round time of a photon corresponding to a wavelength-specific path by an integer multiple, An optical amplifier 160c for generating light and amplifying the light intensity, a full-waveguide unit 160b for determining the oscillation wavelength by the electrical signal of the electrical signal generator 160a, And an optical path wavelength-dependent optical element unit 160f (160g) having a corresponding optical path depending on an oscillation wavelength respectively constituted by optical paths distributed by the MxN optical distributor 160e, And the optical amplification section 160c and the front element section 160b are linearly positioned between the partial reflection section 160d and the partial reflection sections 160h and 160i.

The electric signal generator of the oscillating wavelength variable light source according to the present invention outputs a control signal by varying the cycle time of the periodic electric signal having a cycle time divided by an integral multiple of the one-week time of the photon corresponding to the path for each wavelength, The element section may be configured to determine the oscillation wavelength by the control signal of the electric signal generation section.

Likewise, the optical path-dependent optical component of such an oscillating wavelength variable light source device may include a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, Grating, or an arrayed waveguide grating, but is not limited thereto.

The oscillating wavelength variable light source device according to the present invention can be used as a light source part of an image measuring device as shown in FIG. 1A or as a light source part of a sensor measuring device as shown in FIG. 1B.

As described above, the oscillating wavelength variable light source device and the measuring device using the same according to the present invention provide a light source whose oscillation wavelength varies according to characteristics of an electrical signal applied to a resonator depending on different paths by wavelength, And to provide a light source which is periodically and repeatedly scanned according to this time.

As described above, it will be understood that the present invention is implemented in a modified form without departing from the essential characteristics of the present invention.

It is therefore to be understood that the specified embodiments are to be considered in an illustrative rather than a restrictive sense and that the scope of the invention is indicated by the appended claims rather than by the foregoing description and that all such differences falling within the scope of equivalents thereof are intended to be embraced therein It should be interpreted.

20a. Electric signal generator 20b. The optical amplifying unit
20c. Optical path wavelength dependent optical element portion

Claims (19)

An electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a cycle time of a photon corresponding to a path for each wavelength by an integral multiple;
An optical amplifier for amplifying light and amplifying the light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generator;
And an optical path wavelength dependent optical element part having a corresponding optical path differently depending on an oscillation wavelength determined by the optical amplification part,
The optical path-wavelength-dependent optical element may be a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating element Arrayed waveguide gratings. ≪ RTI ID = 0.0 > 1 < / RTI > An electric signal generator for outputting a control signal by varying a periodic time of a periodic electric signal having a cycle time obtained by dividing a cycle of a photon corresponding to a path by wavelength by an integer multiple;
An optical amplifier for amplifying light and amplifying the light intensity and determining an oscillation wavelength by a control signal of the electrical signal generator;
And an optical path wavelength dependent optical element part having a corresponding optical path differently depending on an oscillation wavelength determined by the optical amplification part,
The optical path-wavelength-dependent optical element may be a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating element Arrayed waveguide gratings. ≪ RTI ID = 0.0 > 1 < / RTI > The oscillation wavelength variable light source device according to claim 1 or 2, wherein the optical amplification part is linearly positioned between partial reflection parts that pass a part of the light intensity and reflect the others. The oscillation wavelength variable light source device according to claim 1 or 2, wherein the optical amplification unit is located in a ring structure including a light distribution unit that distributes the intensity of light at a predetermined ratio. The oscillation wavelength variable light source device according to claim 1 or 2, wherein the optical amplification section is located in a ring structure including a circulator section for changing the traveling path of light. The oscillation wavelength variable light source device according to claim 1 or 2, further comprising an MxN light distribution section for performing optical distribution to oscillate a plurality of wavelengths, wherein the optical amplification section is linearly positioned between the partial reflection sections . delete An electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a cycle time of a photon corresponding to a path for each wavelength by an integral multiple;
An optical amplifier for performing light generation and amplification of light intensity;
A full-wave element unit for determining an oscillation wavelength by an electrical signal of the electrical signal generator;
And an optical path wavelength dependent optical element part having a corresponding optical path differently depending on an oscillation wavelength determined by the front element part,
The optical path-wavelength-dependent optical element may be a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating element Arrayed waveguide gratings. ≪ RTI ID = 0.0 > 1 < / RTI > An electric signal generator for outputting a control signal by varying a periodic time of a periodic electric signal having a cycle time obtained by dividing a cycle of a photon corresponding to a path by wavelength by an integer multiple;
An optical amplifier for performing light generation and amplification of light intensity;
A full-wave element part for determining an oscillation wavelength by a control signal of an electric signal generator;
And an optical path wavelength dependent optical element part having a corresponding optical path differently depending on an oscillation wavelength determined by the front element part,
The optical path-wavelength-dependent optical element may be a prism, a chirped waveguide bragg grating, a grating, a chirped fiber Bragg grating, an array optical waveguide grating element Arrayed waveguide gratings. ≪ RTI ID = 0.0 > 1 < / RTI > The oscillation wavelength variable light source device according to claim 8 or 9, wherein the optical amplification part and the full-wave element part are positioned linearly between the partial reflection parts that pass a part of the light intensity and reflect the rest. The oscillating wavelength variable light source device according to claim 8 or 9, wherein the optical amplifying part and the full-wave element part are located in a ring structure including a light distributing part for distributing the light intensity at a predetermined ratio. The oscillation wavelength variable light source device according to claim 8 or 9, wherein the optical amplification section and the all-optical-element section are located in a ring structure including a circulator section for changing the traveling path of light. 10. The optical pickup as set forth in claim 8 or 9, further comprising an MxN light distributing unit for distributing light so as to oscillate a plurality of wavelengths, wherein the optical amplifying unit and the full- A variable wavelength light source device. delete An electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a period of one week of a photon corresponding to a path for each wavelength by an integer multiple;
An optical amplifier for amplifying light and amplifying the light intensity and determining an oscillation wavelength by an electrical signal of the electrical signal generator;
The optical waveguide grating may be any one of prism, chirped waveguide bragg grating, grating, chirped fiber Bragg grating, and arrayed waveguide grating And an optical path wavelength dependent optical element having a corresponding optical path differently depending on an oscillation wavelength determined by the optical amplifying part. An electric signal generator for outputting a control signal by varying a periodic time of a periodic electric signal having a cycle time obtained by dividing a period of time of a photon corresponding to a path of each wavelength by an integer multiple;
An optical amplifier unit for amplifying light and for amplifying the light intensity and for determining an oscillation wavelength by a control signal of the electrical signal generator;
The optical waveguide grating may be any one of prism, chirped waveguide bragg grating, grating, chirped fiber Bragg grating, and arrayed waveguide grating And an optical path wavelength dependent optical element having a corresponding optical path differently depending on an oscillation wavelength determined by the optical amplifying part. An electric signal generator for outputting a periodic electric signal having a cycle time obtained by dividing a period of one week of a photon corresponding to a path for each wavelength by an integer multiple;
An optical amplifier for performing light generation and amplification of light intensity,
A full-wave element section for determining an oscillation wavelength by an electrical signal of the electrical signal generation section,
The optical waveguide grating may be any one of prism, chirped waveguide bragg grating, grating, chirped fiber Bragg grating, and arrayed waveguide grating And an optical path wavelength dependent optical element having a corresponding optical path depending on an oscillation wavelength determined by the front element unit. An electric signal generator for outputting a control signal by varying a periodic time of a periodic electric signal having a cycle time obtained by dividing a period of time of a photon corresponding to a path of each wavelength by an integer multiple;
An optical amplifier for performing light generation and amplification of light intensity,
A full-wave element unit for determining the oscillation wavelength by a control signal of the electric signal generator,
The optical waveguide grating may be any one of prism, chirped waveguide bragg grating, grating, chirped fiber Bragg grating, and arrayed waveguide grating And an optical path wavelength dependent optical element having a corresponding optical path depending on an oscillation wavelength determined by the front element unit. The method according to claim 15 or 16 or 17 or 18,
The measurement apparatus using the oscillation wavelength variable light source apparatus,
Measuring instrument or a sensor measuring instrument.

Images