KR102118652B1 - Light Source Apparatus and Device for Measuring Optical characteristics of Optical Fiber using the Laser Oscillation Optical Difference by Active Mode Locked Frequency - Google Patents

Abstract

The present invention provides a light source device using a laser oscillation output light difference for each active mode lock frequency to measure a refractive index distribution for each polarization and a refractive index distribution for each wavelength through a mode lock frequency that changes according to an optical path. An electric signal generator for controlling the intensity of an optical signal of a light source device; an optical gain unit controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths; a mode lock frequency Includes a filter unit for controlling the state of the output light oscillated by the optical gain unit in order to use the difference in the output of the laser oscillation; a test unit in which the optical fiber to be measured is located; The part has a resonator structure in which the test part is positioned linearly.

Description

Light Source Apparatus and Device for Measuring Optical characteristics of Optical Fiber using the Laser Oscillation Optical Difference by Active Mode Locked Frequency}

The present invention relates to the measurement of the optical properties of an optical fiber, and specifically, the difference in laser oscillation output light by active mode lock frequency to enable measurement of the refractive index distribution for each polarization and the refractive index distribution for each wavelength through a mode lock frequency that changes according to the optical path. It relates to a used light source device and an optical property measuring device of the optical fiber.

In general, the mode lock technology is a light source technology that creates a short optical pulse by applying a periodic electrical signal having a period divided by an integer multiple of a photon time within the resonator.

At this time, the intensity of the output light pulse oscillated has the property that is maximized when the period of the electrical signal satisfies the mode lock condition corresponding to an integer multiple of the photon time.

The mode lock condition is defined as an integer multiple of the resonance frequency, and the difference in the optical path creates a difference in the resonance frequency.

1 is a block diagram showing the principle of active mode locking.

Active mode lock means a technique of generating a light pulse of a strong intensity by controlling the gain value of the resonator through a periodic electric signal applied from the outside, as shown in FIG. 1.

When the frequency of the electric signal and the frequency at which the light rotates the resonator coincide, mode lock occurs, and the frequency at this time is called the resonant frequency, and the resonant frequency is determined by the length of the resonator.

When the mode lock occurs, the intensity of the output light is the strongest.

By changing the frequency of the external electrical signal and measuring the frequency at which the oscillating light intensity becomes the maximum, the resonance frequency can be known.

That is, when the length of the resonator is changed, the length of the resonator can be measured by measuring the change in the resonant frequency using the thing in which the resonant frequency is changed.

The measuring device using the active mode locking principle of the prior art can acquire the length information obtained as the length of the resonator is changed, but the length information for a specific wavelength or a specific polarization is not obtained, so there is a limit in measuring the optical properties of the optical fiber. have.

Accordingly, there is a need to develop a new technology that obtains length information for a specific wavelength or a specific polarization to increase the efficiency and usability of optical fiber measurement.

Republic of Korea Patent Publication No. 10-2016-0099991 Republic of Korea Patent Publication No. 10-2017-0047694 Republic of Korea Patent Publication No. 10-2007-0017394

The present invention is to solve the problem of the optical property measuring device of the optical fiber using the active mode lock of the prior art, through the mode lock frequency changed according to the optical path to measure the refractive index distribution for each polarization and the distribution of the refractive index for each wavelength An object of the present invention is to provide a light source device using a difference in laser oscillation output light by active mode lock frequency and a device for measuring optical properties of an optical fiber.

The present invention creates a light of a specific polarization state by using a polarization filter that converts the polarization state of the output light of the active mode lock oscillation, and attaches the optical fiber to be measured to change the mode lock frequency that changes depending on the optical path that differs depending on the polarization. An object of the present invention is to provide a light source device using a difference in laser oscillation output light for each active mode lock frequency and a device for measuring optical properties of an optical fiber, which enables measurement of a refractive index distribution for each polarization.

The present invention generates a light of a specific wavelength using a wavelength filter that converts the wavelength of the active mode lock oscillated output light, and attaches the optical fiber to be measured to the wavelength through a mode lock frequency that changes depending on the optical path that differs according to the wavelength. An object of the present invention is to provide a light source device using a difference in laser oscillation output light for each active mode lock frequency and a device for measuring optical properties of an optical fiber, which enables measurement of the refractive index distribution of each star.

The present invention uses an active mode lock, and a polarization filter and a wavelength filter are used to continuously change the polarization state and wavelength state of incident light over time, and find the respective resonant frequency and optical path corresponding to the optical fiber through simple calculation It is an object of the present invention to provide a light source device using a difference in laser oscillation output light by active mode lock frequency and a device for measuring optical properties of an optical fiber to measure a refractive index distribution for each polarization or a refractive index distribution for each wavelength.

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

A light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving the above object is an electrical signal generator for controlling the intensity of the optical signal of the light source device; photons corresponding to different optical paths A light gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time; In order to use the output light difference that maximizes laser oscillation only at a mode lock frequency matching the cycle time, the light gain unit A filter unit that controls the output light state oscillated so that the light is a different optical path; a test in which optical fibers having optical characteristics measured depending on output states of the different optical paths controlled by the filter unit are located. Includes; and, characterized in that the light source device has a resonator structure in which a reflective optical gain unit, a filter unit, and a test unit are linearly located, and responds according to differences in optical paths according to optical fiber states.

A light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving a different object is an electrical signal generator for controlling the intensity of the optical signal of the light source device; a circle of photons corresponding to different optical paths A light gain unit controlled by a periodic electric signal having a cycle time divided by an integer multiple; a reflector reflecting the output light oscillated from the light gain unit; an output that maximizes laser oscillation only at a mode lock frequency matching the cycle time In order to use the light difference, a filter unit that controls the output light state oscillated so that the light from the light gain unit is a different light path; each according to the output light state of different light paths controlled by the filter unit Includes a test unit in which an optical fiber having optical properties measured in dependence is located; a partial reflecting unit that passes a part of the light passing through the test unit and reflects the rest; , It has a resonator structure in which the test unit is linearly located, and is characterized in that it responds according to the optical path difference for each optical fiber state.

A light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving another object comprises: an electrical signal generator for controlling the intensity of the optical signal of the light source device; photons corresponding to different optical paths A light gain unit controlled by a periodic electric signal having a cycle time divided by an integer multiple of one week time; In order to use an output light difference in which laser oscillation is maximized only at a mode lock frequency matching the cycle time, light from the light gain unit A filter unit for controlling the state of the output light oscillated to be different optical paths; an optical circulation unit for changing the path of the light output from the filter unit; each according to the output light state of the different optical paths controlled by the filter unit A test unit in which an optical fiber having optical properties measured in dependence is located; a light distribution unit for distributing light intensity at a predetermined ratio; and a light source device includes a transmissive light gain unit, a light circulation unit, a filter unit, a test unit, and a light distribution unit. It has a resonator structure located in the ring structure, and is characterized in that it responds according to the difference in optical paths for each optical fiber state.

A light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving another object comprises: an electrical signal generator for controlling the intensity of the optical signal of the light source device; photons corresponding to different optical paths A light gain unit controlled by a periodic electric signal having a cycle time divided by an integer multiple of one week time; a light circulation unit that changes the path of light output from the light gain unit; a mode lock that matches the output light state of the light circulation unit to the cycle time In order to use the difference in output light that maximizes laser oscillation only at the frequency, a filter unit that controls the state of the output light oscillated such that light emitted from the light gain unit is a different optical path; different sights controlled by the filter unit Includes; a test unit in which optical fibers having optical characteristics measured depending on the output light condition of the furnace are located; a light distribution unit for distributing the intensity of light output from the light circulation unit at a predetermined ratio; The back part is composed of a ring structure, and has a resonator structure in which a filter part and a test part are linearly located in the light circulation part, and is characterized in that it responds according to differences in optical paths according to optical fiber states.

A light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving another object comprises: an electrical signal generator for controlling the intensity of the optical signal of the light source device; photons corresponding to different optical paths A light gain unit controlled by a periodic electric signal having a cycle time divided by an integer multiple of one week time; in order to use an output light difference in which laser oscillation is maximized only at a mode lock frequency matching the cycle time, the light from the light gain unit A filter unit that controls the output light state oscillated to be different optical paths; a test unit in which optical fibers having optical characteristics measured depending on output states of the different optical paths controlled by the filter unit are located. Including;; light distribution unit for distributing the intensity of light output from the test unit at a constant rate; includes, the light source device has a resonator structure in which a transmissive light gain unit, a filter unit, a test unit, and a light distribution unit are located in a ring structure, and an optical fiber state It is characterized in that it responds according to the difference of the star light path.

Here, the filter unit is a polarization filter that converts the output light oscillated from the light gain unit into light having a specific polarization state so as to have different light paths according to different polarizations, and different specific optical paths are measured according to different specific polarization states. It is characterized in that a test portion in which an optical fiber having optical characteristics is located passes through light of a specific polarization state controlled by the filter unit and responds according to a difference in optical paths for each optical polarization state.

In addition, the filter unit is a wavelength filter that converts the output light oscillated from the light gain unit into light having a specific wavelength so as to have different optical paths according to different wavelengths. The optical fiber to be measured by light of a specific wavelength transmitted from the filter unit is located. It passes through the test unit, it characterized in that it responds according to the optical path difference according to the optical fiber wavelength state.

An optical signal measuring unit for controlling the optical signal intensity of a light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving another object; A light gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of the corresponding photon; in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the cycle time, the light gain Filter unit for controlling the output light oscillated to a specific polarization state so that the light from the unit is a different optical path; Optical characteristics measured in dependence on the output light state of the different optical paths controlled by the filter unit The test unit in which the optical fiber is located; the light source device including the configuration, the light of a specific polarization transmitted from the filter unit passes through the test unit in which the optical fiber to be measured is located, and the light of the specific polarization is at a specific mode lock frequency. And a photodetector for measuring a refractive index distribution characteristic for each polarization by measuring a portion where the output light is maximized by laser oscillation.

An optical signal measuring unit for controlling the optical signal intensity of a light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention for achieving another object; A light gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of the corresponding photon; in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the cycle time, the light gain Filter unit for controlling the output light oscillated to a specific wavelength state so that the light emitted from the unit is a different optical path; Optical characteristics measured depending on the output light state of each of the different optical paths controlled by the filter unit The test unit in which the optical fiber is located; includes a light source device, and the light of a specific wavelength transmitted from the filter unit passes the test unit in which the optical fiber to be measured is located, and the light of a specific polarization is at a specific mode lock frequency. And a photodetector configured to measure a portion where the output light is maximized by laser oscillation to measure a refractive index distribution characteristic for each polarization.

Here, the light source device is characterized in that it has a resonator structure in which a reflective optical gain unit, a filter unit, and a test unit are linearly located, and responds according to differences in optical paths according to optical fiber wavelength states.

In addition, the light source device is characterized in that it has a resonator structure in which a transmissive light gain unit, a partial reflection unit, a filter unit, and a test unit are linearly located, and responds according to differences in optical paths according to optical fiber wavelength states.

In addition, the light source device is characterized in that it has a resonator structure in which a transmissive light gain unit, a light circulation unit, a filter unit, a test unit, and a light distribution unit are located in a ring structure, and responds according to differences in optical paths according to optical fiber wavelength states.

In addition, the light source device, the transmissive light gain unit, the light circulation unit, the light distribution unit is composed of a ring structure, the light circulation unit has a resonator structure in which the filter unit and the test unit are linearly located, and the optical path is different depending on the optical path difference It is characterized by corresponding.

In addition, the light source device is characterized in that it has a resonator structure in which a transmissive light gain unit, a filter unit, a test unit, and a light distribution unit are positioned in a ring structure, and responds according to differences in optical paths according to optical fiber wavelength states.

The light source device using the laser oscillation output light difference for each active mode lock frequency according to the present invention as described above, and the optical property measuring device of the optical fiber have the following effects.

First, it is possible to measure the refractive index distribution for each polarization and the refractive index distribution for each wavelength through a mode lock frequency that changes according to the optical path, thereby increasing the efficiency of manufacturing characteristics of the optical fiber and the utilization of the measuring device.

Second, a polarization filter that converts the polarization state of the output light that is active mode locked oscillation is used to create light in a specific polarization state, and by attaching the optical fiber to be measured, the mode lock frequency changes according to the optical path that differs depending on the polarization. The refractive index distribution for each polarization can be measured.

Third, by using a wavelength filter that converts the wavelength of the active mode locked oscillation output light, by attaching the optical fiber to be measured, each wavelength is changed through the mode locking frequency that changes according to the optical path that differs according to the wavelength. The refractive index distribution can be measured.

Fourth, it is possible to measure the refractive index distribution characteristic of each optical fiber or the refractive index distribution characteristic of each wavelength through a simple calculation, thereby increasing the efficiency of measuring the manufacturing characteristics of the optical fiber and the utilization of the measuring device.

1 is a block diagram showing the principle of active mode locking
Figure 2 is a block diagram showing the measurement principle of the refractive index distribution characteristics of each optical fiber through the difference in output light for each active mode lock frequency according to polarization according to the present invention
Figure 3 is a block diagram showing the measurement principle of the refractive index distribution characteristics of each optical fiber through the difference in output light for each active mode lock frequency according to the wavelength according to the present invention
4 to 8 are detailed configuration diagrams of a light source device and an optical property measuring device of an optical fiber using a difference in laser oscillation output light for each active mode lock frequency according to the present invention.

Hereinafter, a preferred embodiment of the light source device using the laser oscillation output light difference for each active mode lock frequency according to the present invention and the optical property measuring device of the optical fiber will be described in detail.

The characteristics and advantages of the light source device using the laser oscillation output light difference according to the active mode lock frequency according to the present invention and the optical property measuring device of the optical fiber will become apparent through detailed description of each embodiment below.

2 is a block diagram showing the principle of measuring the refractive index distribution (birefringence) characteristic of each optical fiber through a difference in output light for each active mode lock frequency according to polarization according to the present invention, and FIG. 3 is an active mode according to the wavelength according to the present invention It is a block diagram showing the principle of measuring the refractive index distribution (color dispersion) characteristics of each optical fiber through the difference in output light for each lock frequency.

The light source device using the laser oscillation output light difference according to the active mode lock frequency according to the present invention and the optical property measuring device of the optical fiber have a refractive index distribution (birefringence) for each polarization and a refractive index for each wavelength (color dispersion) through a mode lock frequency that changes according to an optical path. ) The distribution was measured.

The present invention allows a specific wavelength to be selected by a wavelength filter or a specific polarization by a polarization filter to obtain length information corresponding thereto, and length information for a specific wavelength or specific polarization is calculated by each refractive index. It can be expressed by a refractive index (color dispersion) for a specific wavelength and a refractive index (birefringence) for a specific polarization.

By using this, in the present invention, the birefringence and color dispersion of the optical fiber can be measured through the difference in laser emission output light for each active mode lock frequency.

To this end, the present invention creates a light of a specific polarization state by using a polarization filter that converts the polarization state of the active mode lock oscillated output light, and attaches the optical fiber to be measured, thereby changing the mode lock according to the optical path different according to polarization. It may include a configuration for measuring the refractive index distribution for each polarization through the frequency.

The present invention generates a light of a specific wavelength using a wavelength filter that converts the wavelength of the active mode lock oscillated output light, and attaches the optical fiber to be measured to the wavelength through a mode lock frequency that changes depending on the optical path that differs according to the wavelength. It may include a configuration for measuring the star refractive index distribution.

The difference of the optical paths occurs according to the polarization or the refractive index distribution for each polarization of the optical fiber to be measured according to the wavelength or the distribution characteristics of the refractive index for each wavelength.

Here, the refractive index distribution for each polarization is represented by birefringence, and the refractive index distribution for each wavelength is represented by color dispersion.

In addition, in the present invention, the polarization state or the wavelength state of the incident light entering the optical fiber is changed using a polarization filter or a wavelength filter that continuously changes with time.

When the polarization state or the wavelength state of the incident light is changed by a polarization filter or a wavelength filter that changes continuously with time, different optical paths exist with time, which is represented by a change in resonance frequency, which is a mode lock condition. do.

The principle of the light source device and the optical property measuring device of the optical fiber using the difference in laser oscillation output light for each active mode lock frequency is as follows.

As shown in FIG. 2, the polarization state of the incident light continuously changes with time by a polarization filter that continuously changes the polarization of the incident light with time.

)은 다음과 같이 정의된다.Here, the refractive index for each polarization (

) Is defined as

는 편광별 광섬유의 굴절률이고,

는 편광별 공진주파수이다. L은 공진기 길이, c는 광속이다.here,

Is the refractive index of the optical fiber for each polarization,

Is a resonance frequency for each polarization. L is the length of the resonator and c is the speed of light.

As shown in FIG. 3, the wavelength state of the incident light is continuously changed with time by a wavelength filter that continuously changes the wavelength of the incident light with time.

은 다음과 같이 정의된다.Color dispersion by wavelength

Is defined as

은 파장별 색분산,

은 기준 파장에서의 광섬유 굴절률이며,

은 파장별 공진주파수,

는 기준파장에서의 공진주파수이다.

은 필터에 의해 선택된 특정 파장,

는 기준파장, L은 공진기 길이, c는 광속이다.here,

Color dispersion by wavelength,

Is the optical fiber refractive index at the reference wavelength,

Resonant frequency by wavelength,

Is the resonant frequency at the reference wavelength.

A specific wavelength selected by the silver filter,

Is the reference wavelength, L is the resonator length, and c is the luminous flux.

By measuring the frequency at which the intensity of the output light oscillated becomes maximum while changing the frequency of the external electric signal over time according to the polarization state or wavelength state that changes with time, the resonance frequency for each polarization state and wavelength state is known. It is possible to know the length of the resonator suitable for each polarization state and wavelength state.

Through this, the refractive index distribution for each polarization (birefringence) and the refractive index distribution for each wavelength (color dispersion) can be found.

The light source device using the laser oscillation output light difference according to the active mode lock frequency according to the present invention and the optical property measuring device of the optical fiber use an active mode lock, and a polarization filter and a wavelength filter are used to continuously input incident light over time. By changing the polarization state and the wavelength state, and finding the respective resonant frequencies and optical paths corresponding to this, it is possible to measure the refractive index distribution for each polarization or the refractive index distribution characteristic for each wavelength through simple calculation.

The detailed configuration of the optical characteristic measuring device of the optical fiber using the difference in laser oscillation output light for each active mode lock frequency according to the present invention will be described in detail as follows.

4 to 8 are detailed configuration diagrams of a light source device using a laser oscillation output light difference for each active mode lock frequency according to the present invention and an optical property measuring device of an optical fiber.

In the following description, the output light state control means for controlling the output light state to use the laser oscillation output light difference for each mode lock frequency is preferably a polarization filter that converts the output light oscillated from the light gain unit into light in a specific polarization state. Do.

In addition, it is preferable that the output light state control means for controlling the output light state to use the laser oscillation output light difference for each mode lock frequency is a wavelength filter that converts the output light oscillated from the light gain unit into light of a specific wavelength state.

(First embodiment)

The light source device using the laser oscillation output light difference for each active mode lock frequency according to an embodiment of the present invention, as shown in Figure 4, the electric signal generation unit 41 for controlling the intensity of the optical signal of the light source device, each different An optical gain section 42 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of a photon corresponding to an optical path, and the optical gain section 42 to utilize a difference in laser oscillation output light for each mode lock frequency It includes a filter unit 43 for controlling the output light state oscillated in ), and a test unit 44 in which the optical fiber to be measured is located.

Here, the light source device has a resonator structure in which a reflective light gain unit, a filter unit, and a test unit are linearly located.

The optical characteristic measuring device of the optical fiber having the light source device using the laser oscillation output light difference for each active mode lock frequency of such a structure, as shown in FIG. 4, an electric signal generator 41 for controlling the intensity of the optical signal of the light source device And, the optical gain unit 42 is controlled by a periodic electric signal having a cycle time divided by an integer multiple of the week time of the photons corresponding to the different optical paths, and the light to use the difference in the laser oscillation output light for each mode lock frequency The filter unit 43 controls the state of the output light oscillated by the gain unit 42, the test unit 44 where the optical fiber to be measured is located, and the test unit 44 where the output optical state is controlled and where the optical fiber is located. When passing through, it includes a photodetector 45 that measures the difference in laser oscillation output light for each mode lock frequency.

(Second example)

The light source device using the laser oscillation output light difference for each active mode lock frequency according to another embodiment of the present invention, as shown in Figure 5, the electric signal generator 51 for controlling the intensity of the optical signal of the light source device, each different An optical gain section 52 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of a photon corresponding to an optical path, and a reflection section 57 reflecting output light generated by the optical gain section 52 And, a filter unit 53 for controlling the state of the output light oscillated by the optical gain unit 52 to use the difference in the laser oscillation output light for each mode lock frequency, and a test unit 54 in which the optical fiber to be measured is located. And a partial reflection part 55 that passes a part of the light that has passed through the test part 44 and reflects the rest.

Here, the light source device has a resonator structure in which a transmissive light gain portion, a partial reflection portion, a filter portion, and a test portion are linearly located.

The optical characteristic measuring device of the optical fiber having the light source device using the laser oscillation output light difference for each active mode lock frequency of such a structure, as shown in FIG. 5, an electric signal generator 51 for controlling the intensity of the optical signal of the light source device Wow, the light gain section 52 is controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths, and the reflection reflecting the output light generated by the light gain section 52 The unit 57, a filter unit 53 for controlling the state of the output light oscillated by the light gain unit 52 to use the difference in laser oscillation output light for each mode lock frequency, and a test in which the optical fiber to be measured is located A test part 44 and a part including a part 54 and a part reflecting part 55 for passing a part of the light passing through the test part 44 and reflecting the rest, and controlling the output light state to locate the optical fiber When passing through the reflector 55, it includes a photodetector 56 that measures the difference in laser oscillation output light for each mode lock frequency.

(Example 3)

According to another embodiment of the present invention, a light source device using a laser oscillation output light difference for each active mode lock frequency, as shown in FIG. 6, an electric signal generator 61 for controlling the intensity of the optical signal of the light source device, respectively The optical gain unit 62 is controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of a photon corresponding to a different optical path, and the optical gain unit for using the difference in laser oscillation output light for each mode lock frequency ( 62) a filter unit 63 for controlling the state of the output light oscillated, a light circulation unit 66 for changing the path of the light output from the filter unit 63, and a test unit 67 in which the optical fiber to be measured is located. ), and a light distribution unit 65 for distributing light intensity at a predetermined ratio.

Here, the light source device has a resonator structure in which a transmissive light gain unit, a light circulation unit, a filter unit, a test unit, and a light distribution unit are located in a ring structure.

The optical characteristic measuring device of the optical fiber having the light source device using the difference in the laser oscillation output light for each active mode lock frequency of such a structure, as shown in FIG. 6, an electric signal generator 61 for controlling the intensity of the optical signal of the light source device And, the optical gain unit 62 is controlled by a periodic electric signal having a cycle time divided by an integer multiple of the week time of the photons corresponding to different optical paths, and the light to use the difference in the laser oscillation output light for each mode lock frequency The filter unit 63 for controlling the output light state oscillated by the gain unit 62, the optical circulation unit 66 for changing the path of the light output from the filter unit 63, and the test in which the optical fiber to be measured is located It includes a unit 67, a light distribution unit 65 for distributing light intensity at a predetermined ratio, and a light detection unit 64 for measuring the difference in laser oscillation output light for each mode lock frequency.

(Example 4)

According to another embodiment of the present invention, a light source device using a laser oscillation output light difference for each active mode lock frequency, as shown in FIG. 7, an electric signal generator 71 for controlling the intensity of the optical signal of the light source device, respectively An optical gain section 72 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of a photon corresponding to another optical path, and an optical circulation section for changing the path of light output from the optical gain section 72 ( 73), a filter unit 74 for controlling the output light state of the light circulation unit 73, a test unit 75 in which the optical fiber to be measured is located, and a certain ratio of light intensity output from the light circulation unit 73 It includes a light distribution unit 76 for distribution to.

Here, the light source device has a transmissive light gain unit, a light circulation unit, and a light distribution unit having a ring structure, and has a resonator structure in which a filter unit and a test unit are linearly located in the light circulation unit.

The optical characteristic measuring device of the optical fiber having the light source device using the difference in the laser oscillation output light for each active mode lock frequency of such a structure, as shown in FIG. 7, an electric signal generator 71 for controlling the intensity of the optical signal of the light source device Wow, the optical gain section 72 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths, and changing the path of light output from the optical gain section 72 The light circulation section 73, the filter section 74 for controlling the output light state of the light circulation section 73, the test section 75 where the optical fiber to be measured is located, and the intensity of light output from the light circulation section 73 It includes a light distribution unit 76 for distributing a constant ratio, and a light detection unit 77 for measuring the difference in laser oscillation output light for each mode lock frequency.

(Example 5)

According to another embodiment of the present invention, a light source device using a laser oscillation output light difference for each active mode lock frequency, as shown in FIG. 8, an electric signal generator 81 for controlling the intensity of the optical signal of the light source device, respectively An optical gain unit 82 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of a photon corresponding to another optical path, and a filter unit controlling an output light state generated by the optical gain unit 82 It includes a 83, a test unit 84 on which the optical fiber to be measured is located, and a light distribution unit 85 for distributing the intensity of light output from the test unit 84 at a predetermined ratio.

Here, the light source device has a resonator structure in which a transmissive light gain unit, a filter unit, a test unit, and a light distribution unit are positioned in a ring structure.

The optical characteristic measuring device of the optical fiber having the light source device using the laser oscillation output light difference for each active mode lock frequency of such a structure, as shown in FIG. 8, an electrical signal generator 81 for controlling the intensity of the optical signal of the light source device And, a light gain unit 82 controlled by a periodic electric signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths, and the output light state oscillated by the light gain unit 82 are controlled. The filter unit 83, the test unit 84 where the optical fiber to be measured is located, the light distribution unit 85 for distributing the intensity of light output from the test unit 84 at a constant rate, and the laser for each mode lock frequency And a photodetector 86 for measuring the difference in oscillation output light.

The optical property measuring device of the optical fiber using the laser oscillation output light difference for each active mode lock frequency according to the present invention described above uses an active mode lock, and a polarization state of incident light continuously with time using a polarization filter and a wavelength filter And by changing the wavelength state and finding the respective resonant frequency and optical path corresponding to this, it is possible to measure the refractive index distribution for each polarization or the refractive index distribution characteristic for each wavelength through simple calculation.

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

Therefore, the specified embodiments should be considered in terms of explanation rather than limitation, and the scope of the present invention is shown in the claims rather than the foregoing description, and all differences within the equivalent range are included in the present invention. Should be interpreted.

41. Electric signal generator 42. Optical gain
43. Filter section 44. Test section
45. Photodetector

Claims (14)

An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
A filter unit for controlling the state of the output light oscillated so that the light emitted from the light gain unit becomes a different optical path in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the period time;
It includes; a test unit in which optical fibers having optical characteristics measured depending on the output light conditions of the different optical paths controlled by the filter unit are respectively measured;
Using a laser oscillation output light difference for each active mode lock frequency, characterized in that the light source device has a resonator structure in which the reflection type optical gain unit, the filter unit, and the test unit are positioned linearly, and responds according to the optical path difference for each optical fiber state. Light source device. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
A reflector for reflecting the output light oscillated from the light gain unit;
A filter unit for controlling the state of the output light oscillated so that the light emitted from the light gain unit becomes a different optical path in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the period time;
A test unit in which optical fibers having optical characteristics measured in dependence on output states of different optical paths controlled by the filter unit are located;
Includes a partial reflection portion that passes a portion of the light passing through the test portion and reflects the rest,
Laser oscillation output light for each active mode lock frequency, characterized in that the light source device has a resonator structure in which the transmissive light gain portion, the partial reflection portion, the filter portion, and the test portion are linearly located, and responds according to the optical path difference for each optical fiber state. Light source device using difference. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
A filter unit for controlling the state of the output light oscillated so that the light emitted from the light gain unit becomes a different optical path in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the period time;
A light circulation unit for changing a path of light output from the filter unit;
A test unit in which optical fibers having optical characteristics measured depending on output states of different optical paths controlled by the filter unit are respectively measured;
Includes; a light distribution unit for distributing the intensity of light at a constant rate,
A laser for each active mode lock frequency, characterized in that the light source device has a resonator structure in which a transmissive light gain unit, an optical circulation unit, a filter unit, a test unit, and an optical distribution unit are located in a ring structure, and responds according to optical path differences according to optical fiber states. Light source device using oscillation output light difference. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
An optical circulation unit for changing a traveling path of light output from the optical gain unit;
In order to use the difference in output light that maximizes laser oscillation only at the mode lock frequency that matches the output light state of the light circulation unit at the cycle time, the output light state oscillated so that the light from the light gain unit becomes a different light path. A filter unit to control;
A test unit in which optical fibers having optical characteristics measured depending on output states of different optical paths controlled by the filter unit are respectively measured;
Includes; a light distribution unit for distributing the intensity of light output from the light circulation unit at a constant rate,
Active mode characterized in that the light source device is composed of a light circulation unit and a light distribution unit having a ring structure, a filter unit and a test unit are linearly located in the light circulation unit, and responds according to the optical path difference for each optical fiber state. Light source device using laser oscillation output light difference by lock frequency. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
A filter unit that controls an output light state oscillated such that light emitted from the light gain unit is a different optical path in order to use a difference in output light that maximizes laser oscillation only at a mode lock frequency matching the period time;
A test unit in which optical fibers having optical characteristics measured depending on output states of different optical paths controlled by the filter unit are respectively measured;
Includes a; light distribution unit for distributing the intensity of the light output from the test unit at a constant rate,
Laser oscillation output light for each active mode lock frequency, characterized in that the light source device has a resonator structure in which a transmissive light gain part, a filter part, a test part, and a light distribution part are positioned in a ring structure, and responds according to a difference in an optical path for each optical fiber state. Light source device using difference. The method according to claim 1 or 2 or 3 or 4 or 5,
The filter unit is a polarization filter that converts the output light oscillated from the light gain unit into light having a specific polarization state so as to have different optical paths according to different polarizations,
The test unit in which the optical fiber having the optical characteristics in which different specific optical paths are measured according to different specific polarization states passes through the light of the specific polarization state controlled by the filter unit, and corresponds to the optical path difference for each optical polarization state. Light source device using a laser oscillation output light difference for each active mode lock frequency, characterized in that. The method according to claim 1 or 2 or 3 or 4 or 5,
The filter unit is a wavelength filter that converts the output light oscillated from the light-gaining unit into light of a specific wavelength so as to have different optical paths according to different wavelengths,
A light source using a difference in laser oscillation output light by active mode lock frequency, characterized in that light of a specific wavelength transmitted from the filter part passes through a test section where an optical fiber to be measured is located, and responds according to an optical path difference according to the optical fiber wavelength state. Device. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
In order to use the difference in output light that maximizes laser oscillation only at a mode lock frequency that matches the period time, a filter unit that controls the output light oscillated to a specific polarization state so that the light from the light gain section is a different optical path. ;
A light source device is configured, including; a test unit in which optical fibers having optical characteristics measured depending on output states of different optical paths controlled by the filter unit are respectively located;
Refractive index distribution characteristics for each polarization by measuring the part where the light of a specific polarization transmitted from the filter part passes through a test section where the optical fiber to be measured is located, and the light of a specific polarization is laser oscillated at a specific mode lock frequency to maximize the output light Includes, and, Optical fiber measuring device using the difference of the laser oscillation output light by the active mode lock frequency, characterized in that corresponding to the optical path difference for each wavelength state of the optical fiber. An electric signal generator for controlling the intensity of the optical signal of the light source device;
An optical gain unit controlled by a periodic electrical signal having a cycle time divided by an integer multiple of a week time of photons corresponding to different optical paths;
In order to utilize the difference in output light that maximizes laser oscillation only at the mode lock frequency matching the period time, a filter unit that controls the output light oscillated to a specific wavelength state so that the light from the light gain section is a different optical path ;
A light source device is configured, including; a test unit in which optical fibers having optical characteristics measured depending on output states of different optical paths controlled by the filter unit are respectively located;
The characteristics of the refractive index distribution for each polarization are measured by passing through the test unit where the light of a specific wavelength transmitted from the filter unit is located, and the light of a specific polarization is laser oscillated at a specific mode lock frequency to maximize the output light. Includes, and, Optical fiber measuring device using the difference of the laser oscillation output light by the active mode lock frequency, characterized in that corresponding to the optical path difference for each wavelength state of the optical fiber. The light source device according to claim 8 or 9,
The optical fiber using the laser oscillation output light difference for each active mode lock frequency, which has a resonator structure in which the reflection type optical gain unit, the filter unit, and the test unit are positioned linearly, and responds according to the optical path difference for each optical fiber wavelength state. Optical characteristic measuring device. The light source device according to claim 8 or 9,
A laser oscillation output light difference for each active mode lock frequency, which has a resonator structure in which a transmissive light gain unit, a partial reflection unit, a filter unit, and a test unit are linearly located, and responds according to the optical path difference for each optical fiber wavelength state. Measuring device for optical properties of used optical fibers. The light source device according to claim 8 or 9,
Laser oscillation output by active mode lock frequency, characterized in that the transmissive light gain unit, light circulation unit, filter unit, test unit, and light distribution unit have a resonator structure located in the ring structure, and responds according to the optical path difference according to the optical fiber wavelength state. Optical fiber measurement device using optical difference. The light source device according to claim 8 or 9,
The transmissive light gain section, light circulation section, and light distribution section consist of a ring structure, and the filter section and the test section have a resonator structure that is linearly located in the light circulation section. Optical characteristic measurement device of optical fiber using laser oscillation output light difference by active mode lock frequency. The light source device according to claim 8 or 9,
It has a resonator structure in which a transmissive light gain unit, a filter unit, a test unit, and a light distribution unit are located in a ring structure, and responds according to the optical path difference for each wavelength state of the optical fiber. Measuring device for optical properties of used optical fibers.

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