KR20210115447A - optical fiber spectrometer - Google Patents

Abstract

The present invention relates to an optical fiber spectrometer including: an optical circulator outputting inspection light input through an input stage through a detection stage and outputting light inversely proceeding in the detection stage through an output stage; a spectral optical fiber connected to the detection stage, inclined on an optical fiber to radiate longitudinally incident light in a direction intersecting the longitudinal direction, and provided with tilt chirping gratings with different separation intervals such that reflection wavelengths differ depending on a formation position; a reflector movable along the extension direction of the optical fiber such that light emitted at the tilt chirping gratings of the spectral optical fiber is reflected back to the tilt chirping gratings and inversely proceeds at the optical fiber; a photodetector detecting the light output through the output stage of the optical circulator; and a measuring unit processing a signal output by the photodetector. With the optical fiber spectrometer, wavelength-specific spectrum information can be acquired with a signal photodetector, and thus the structural simplification can be achieved.

Description

optical fiber spectrometer

The present invention relates to an optical fiber spectrometer, and more particularly, to an optical fiber spectrometer capable of acquiring spectrum information for each wavelength of a measurement target light by using a tilt chirping grating in which the spacing is gradually changed while being inclined to the optical fiber.

In general, a spectrometer refers to a device for measuring a response for each wavelength of a target sample by spatially dispersing it for each wavelength component of light. Such spectrometers are being used in various fields such as medical optics, biology, and telemedicine diagnostic services.

In addition, a transmission type or reflection type diffraction grating and a lens are used as a method for splitting light in a spectrometer.

However, since the size of the diffraction grating or the lens is relatively large, the size of the entire device is increased and the weight is large. In addition, it is necessary to solve the problem of the dispersion effect and aberration caused by the used optical element.

In order to improve this disadvantage, a spectrometer capable of performing spectroscopy using an optical fiber grating is disclosed in Korean Patent Registration No. 10-1756364.

However, the spectrometer has a complicated structure because each photodetector must be applied to each Bragg grating, and when the measurement target wavelength range is to be extended, the photodetector must be increased correspondingly, so the extension of the measurement target wavelength range is also limited. There are disadvantages.

An object of the present invention is to provide an optical fiber spectrometer that has a simple structure and can selectively measure only a desired specific wavelength.

In order to achieve the above object, an optical fiber spectrometer according to the present invention includes: an optical circulator for outputting inspection light input through an input end through a detecting end, and outputting light traveling backward from the detecting end through an output end; A spectroscopic optical fiber connected to the detection end and provided with a tilt chirping grating having a different distance from each other and formed inclined on the optical fiber so as to radiate incident light along the longitudinal direction in a direction crossing the longitudinal direction and having different reflection wavelengths for each formation position; ; a reflector installed movably in the extension direction of the optical fiber to reflect the light emitted from the tilt chirping grating of the spectral optical fiber back to the tilt chirping grating and to travel in the reverse direction in the optical fiber; a photodetector configured to detect light output through an output terminal of the optical circulator; and a measuring unit that processes the signal output from the photodetector.

Preferably, the reflector is controlled by the measuring unit to further include a movement driving unit for moving along the longitudinal direction of the spectroscopic optical fiber.

According to an aspect of the present invention, the movement driving unit includes a screw mounted to a support frame rotatably free of charge along the extension direction of the spectral optical fiber; a constraint rail extending parallel to the screw and mounted on the support frame; a sliding guide member coupled to the restraint rail to advance and retreat along the restraint rail; and a motor for rotating the screw in a forward and reverse direction controlled by the measuring unit, wherein the reflector is screwed with the screw from the outside of the screw and moves forward and backward along the extension direction of the spectral optical fiber according to the forward and reverse rotation of the screw. The side is coupled to the sliding guide member.

According to the optical fiber spectrometer according to the present invention, spectrum information for each wavelength can be acquired even with a single photodetector, thereby providing an advantage in that the structure is simplified.

1 is a view showing an optical fiber spectrometer according to the present invention,
Figure 2 is a schematic cross-sectional view for explaining the structure of the spectroscopic optical fiber of Figure 1,
FIG. 3 is a view showing an example of the movement driving unit of FIG. 1 .

Hereinafter, an optical fiber spectrometer according to a preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings.

1 is a view showing an optical fiber spectrometer according to the present invention, and FIG. 2 is a schematic cross-sectional view for explaining the structure of the spectroscopic optical fiber of FIG. 1 .

1 and 2 , the optical fiber spectrometer 100 according to the present invention includes an optical circulator 110 , a spectroscopic optical fiber 130 , a reflector 150 , a movement driving unit 160 , a light detection unit 170 , and a manipulation unit. 181 , a display unit 183 , and a measurement unit 185 are provided.

The optical circulator 110 outputs the inspection light input through the input terminal 110a through the detection terminal 110b, and outputs the light propagating in reverse from the detection terminal 110b through the output terminal 110c. An input optical fiber 112 is coupled to the optical circulator 110 to receive the inspection light to the input terminal 110a.

The spectroscopic optical fiber 130 is connected to the detection end 110b of the optical circulator 110 and is formed to be inclined with respect to the extension direction of the optical fiber 132 so as to emit light incident along the longitudinal direction in a direction crossing the longitudinal direction. It has a structure in which the tilt chirping gratings 134 with different distances from each other are provided with different reflection wavelengths for each forming position. Here, the tilt chirping gratings 134 are formed to be inclined with respect to the extending direction of the optical fiber 134 , and refer to a grating formed along the extending direction of the optical fiber 134 so that the spacing is gradually increased or decreased.

In the illustrated example, the spectral optical fiber 130 includes a core 132a and a clad 132b surrounding the core 132a. A tilt chirping grating 134 formed with a different refractive index from the core 132a is spaced apart from each other. The interval is formed to increase gradually. Here, the angle α inclined with respect to the extension direction of the core 132a of the tilt chirping grating 134 is applied to 45 so that the light emitted to the reflector 150, which will be described later, is reflected and incident back to the position. it is preferable

In addition, the separation distance between the tilt chirping gratings 134 formed in the spectral optical fiber 130 is a factor that determines the spectral wavelength, and may be appropriately applied to correspond to the spectral precision to be measured. In addition, the number of applications of the tilt chirping grating 134 may be applied to correspond to the spectral precision and the entire spectral wavelength range to be measured.

The tilt chirping grating 134 of the spectral optical fiber 130 has a different wavelength of light emitted by a difference in a separation distance for each position along the longitudinal direction.

The reflector 150 reflects the light emitted from the tilt chirping grating 134 of the spectral optical fiber 130 back to the tilt chirping grating 134 and proceeds backward in the optical fiber 132 along the extension direction of the optical fiber 132 . It is installed to be movable.

The reflector 150 may be formed of a material having a high reflectance or a reflective surface coated with a material having a high reflectance may be applied. The size of the reflector 150 may be formed to have an appropriate size to selectively reflect only the wavelength band to be measured. As an example, the reflector 150 may be formed to have a reflective area of about the minimum spacing of the tilt chirping grating 134 .

The reflector 150 can be moved by the movement driving unit 160 .

The movement driving unit 160 is controlled by the measuring unit 185 to move the reflector 150 in the longitudinal direction of the spectral optical fiber 130 , and will be described with reference to FIG. 3 .

The moving driving unit 160 includes a support frame 161 , a screw 163 , a restraining rail 167 , a sliding guide member 168 , and a motor (M) 169 .

The support frame 161 is applied to support the horizontal movement of the reflector 150 and has a length longer than the entire length of the tilt chirping gratings 134 .

The screw 163 is freely rotatably mounted on the support frame 161 in parallel with the spectral optical fiber 130 along the extension direction of the spectral optical fiber 130 . Reference numeral 165 denotes a bearing coupled to the support frame 161 while supporting the screw 163 in the vicinity of both ends to be able to rotate freely.

The restraint rail 167 is mounted on the support frame 161 to extend in parallel with the screw 163 . Constraint rail 167 is applied to be applied to guide the movement of the reflector 150 in the horizontal plane, the sliding guide member 168, which will be described later, is applied to be formed in a rod shape so that it can be inserted and moved from the outside. Of course, a structure in which a constraining groove or a constraining protrusion is formed along the extension direction of the screw 163 may be applied, unlike the illustrated example.

The sliding guide member 168 is formed in a ring shape and is coupled to be inserted into the outside of the constraint rail 167 to advance and retreat along the constraint rail 167 , and one side is coupled to the reflector 150 .

The motor (M) 169 is controlled by the measuring unit 185 to rotate the screw 163 forward and reverse.

In this structure, the reflector 150 is applied as a nut structure screwed with the screw 163 from the outside of the screw 163 , and moves forward and backward along the extension direction of the spectroscopic optical fiber 130 according to the forward and reverse rotation of the screw 163 . One side is coupled to the sliding guide member (168).

Accordingly, the reflector 150 may be moved to a position of the tilt chirping grating 134 among the tilt chirping gratings 134 by the forward and reverse rotation of the motor 169 .

The photodetector 170 detects light output through the output terminal 110c of the optical circulator 110 and outputs an electrical signal corresponding to the detected intensity of light.

One photodetector is applied to the photodetector 170 .

The operation unit 181 is configured to set supported functions related to spectral measurement.

The display unit 183 is controlled by the measurement unit 185 to display display target information.

The measurement unit 185 processes the signal output from the photodetector 170 .

When a detection instruction for a specific wavelength is received from the manipulation unit 181 , the measurement unit 185 controls the movement driving unit 160 to move the reflector 150 to the tilt chirping grating position corresponding to the wavelength, and the photodetector 170 . ), the detection intensity information from the received signal is processed to be displayed on the display unit 185 .

Similarly, when the measurement unit 185 receives a spectral detection instruction for all wavelengths from the manipulation unit 181 with respect to the inspection light input through the input terminal 110a of the optical circulator 110, tilt chirp corresponding to each of the spectral wavelengths. After controlling the movement driver 160 to move the reflector 150 to the grating position, and recording the detection intensity of the corresponding wavelength from the signal received from the photodetector 170, the entire tilt chirping grating is sequentially performed. The aggregated spectral information is processed to be displayed through the display unit 183 .

According to this structure, even if only one photodetector is applied to one photodetector 170 , spectral spectrum information can be acquired, thereby providing an advantage in that the structure is simplified.

Meanwhile, in the illustrated example, a structure in which the movement driving unit 160 is controlled to the measurement unit 185 is applied, but the reflector 150 is moved to the measurement target wavelength position in a manual manner, and the measurement result is obtained from the measurement unit 185 Of course, it can be constructed so that it can be checked.

In this case, instead of the motor 169, a handle capable of rotating the screw by the user and a position identification scale or a position value for identifying the movement position of the reflector 150 with respect to the manipulation of the handle may be applied.

According to the optical fiber spectrometer described above, it is possible to acquire spectral information for each wavelength even with a single photodetector, thereby providing an advantage in that the structure is simplified.

110: optical circulator 130: spectral optical fiber
150: reflector 160: moving driving unit
170: light detection unit 181: operation unit
183: display unit 185: measurement unit

Claims (3)

an optical circulator for outputting the inspection light input through the input end through the detecting end, and outputting the light propagating in reverse from the detecting end through the output end;
A spectroscopic optical fiber connected to the detection end and provided with a tilt chirping grating having a different distance from each other and formed inclined on the optical fiber so as to radiate incident light along the longitudinal direction in a direction crossing the longitudinal direction and having different reflection wavelengths for each formation position; ;
a reflector installed movably in the extension direction of the optical fiber to reflect the light emitted from the tilt chirping grating of the spectral optical fiber back to the tilt chirping grating and to travel in the reverse direction in the optical fiber;
a photodetector configured to detect light output through an output terminal of the optical circulator;
and a measuring unit that processes the signal output from the photodetector. [2] The optical fiber spectrometer according to claim 1, further comprising: a movement driving unit controlling the reflector to move along the longitudinal direction of the spectroscopic optical fiber under the control of the measuring unit. According to claim 2, wherein the movement driving unit
a screw mounted to the support frame to be freely rotatable along the extension direction of the spectral optical fiber;
a constraint rail extending parallel to the screw and mounted on the support frame;
a sliding guide member coupled to the restraint rail to advance and retreat along the restraint rail;
and a motor controlling the screw to rotate forward and reverse by the measuring unit; and
The reflector is screwed with the screw from the outside of the screw and moves forward and backward along the extension direction of the optical fiber according to the forward and reverse rotation of the screw, and one side is coupled to the sliding guide member.

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