KR101756364B1 - Optical Spectrometer of using Fiber Bragg Grating - Google Patents

Abstract

The present invention relates to a spectroscope using an optical fiber Bragg grating that sequentially arranges an optical fiber Bragg grating for reflecting or transmitting light of a specific wavelength between an optical coupler and a photodetector and successively detects and analyzes light of a specific wavelength, It is possible to construct a spectroscope that minimizes the size and can effectively remove the noise caused by the light source or the interference, so that the resolution and the accuracy can be improved. Can be improved.

Description

TECHNICAL FIELD [0001] The present invention relates to a spectroscope using a fiber Bragg grating,

The present invention relates to a spectroscope, and more particularly, to a spectroscope that performs non-contact non-destructive analysis of various physical quantities by measuring incident light incident from a light source by wavelength and measuring wavelength characteristics of the spectroscopic light.

As is known, the spectroscope can be used in various industrial fields such as semiconductor, semiconductor, and the like by analyzing the change in the intensity of the absorbed or transmitted light by irradiating light to the object of analysis and analyzing the quantitative change of the temperature, stress, Bio, or structural safety diagnosis.

The above-mentioned spectroscope mainly uses a spectrometer using a grating using a diffraction phenomenon and a polychromator using an optical filter.

1 is a structural view of a spectroscope using a grating according to the prior art. 1, the incident light irradiated from the light source is reflected by the first reflecting mirror 2 after passing through the slit 1, and the reflected light by the first reflecting mirror 2 is reflected by the grating 3) and are spectroscopically analyzed for each wavelength. The light that has been spectrally split by the grating 3 is reflected by the second reflecting mirror 4 and is incident on each pixel of the CCD (Charge Coupled Device) Then, the incident light to the CCD sensor 5 is converted into an electric signal and quantitatively analyzed.

However, in order to obtain a sufficient resolution in the spectrometer using the grating of FIG. 1, the guiding distance from the grating 3 to the CCD sensor 5, that is, the photodetector should be sufficiently long and the path of the light of the diffracted light should not overlap, There is a problem that noises due to a light source or noise due to mutual interference of the spectroscopic light are generated.

In addition, a multi-coloring apparatus using an optical filter also has a problem that it is difficult to secure a sufficient channel due to its size limitation, and it is difficult to remove noise caused by a light source.

The technical problem to be solved by the present invention is to provide a spectroscope using an optical fiber Bragg grating which has sufficient resolution and is independent of the overlapping of optical path paths, minimizes the guiding distance, and eliminates scattered light or noise due to interference I want to.

In order to achieve the above object, the present invention provides a spectroscope using an optical fiber Bragg grating, comprising: an optical fiber for guiding and guiding light emitted from a light source; first to Nth optical couplers for splitting or coupling incident light guided to an optical fiber; To N-th optical couplers, first to N-th reflective Bragg gratings for respectively reflecting light of first to N-th wavelength among lights incident from the first to Nth optical couplers, A first through N-th transmission Bragg gratings respectively connected to the couplers and respectively transmitting the first through N-th wavelengths of light reflected by the first through N-th reflective Bragg gratings and respectively branched by the first through Nth optical couplers, First to Nth optical detectors respectively detecting light of first to Nth wavelengths respectively transmitted from the first to Nth transmission Bragg gratings, first to Nth optical detectors respectively detected from the first to Nth optical detectors, The paper includes a signal processor to analyze the wavelength characteristics of the wavelength N in order, the first to the N-th reflection Bragg grating is characterized in that each connected in series in an optical fiber.

Preferably, the first to Nth reflective Bragg gratings and the first to Nth transmission Bragg gratings may be formed of an optical fiber Bragg grating.

The optical fiber may further include an optical isolator that transmits light incident to the optical fiber in a forward direction and blocks the light in a reverse direction.

Preferably, the apparatus may further comprise a constant temperature device for maintaining a constant temperature of each transmission Bragg grating and each reflective Bragg grating.

According to the present invention, since light of a specific wavelength is reflected by a reflective Bragg grating, and light of a specific wavelength is transmitted by a transmission Bragg grating after branched by an optical coupler, stray light or interference- Can be removed.

In addition, it is possible to construct a spectroscope that minimizes the size, while minimizing the size, while ensuring a sufficient resolution through each photodetector while minimizing the size, can be constructed irrespective of the overlapping of the optical path paths.

In addition, noise due to scattered light or interference can be effectively removed, and resolution and precision can be improved.

Further, it is possible to minimize the measurement and analysis errors of the spectroscope due to the change in the refractive index by keeping the temperature of the material constituting the Bragg grating at a constant temperature in order to minimize the change in the refractive index due to the temperature.

1 is a structural view of a spectroscope using a grating according to the prior art.
2 is a configuration diagram of a spectroscope using an optical fiber Bragg grating according to the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

2 is a configuration diagram of a spectroscope using an optical fiber Bragg grating according to the present invention.

2, an optical fiber 110, an optical coupler 120, a Bragg Grating Reflector (BGR), a Bragg Grating Transmitter (BGT), a photodetector A photodetector (PD), and a signal processor 130. Meanwhile, the reflective Bragg grating (BGR) or the transmission Bragg grating (BGT) is formed of an optical fiber (Bragg Grating Fiber) that reflects or transmits light of a specific wavelength by forming a different refractive index in a waveguide path in the optical fiber.

The optical fiber 110 provides a path through which light emitted from a light source (not shown) is incident and guided.

The optical coupler 120 includes first to Nth optical couplers. The optical coupler 120 splits incident light, which is guided by the optical fiber 110, into two or more paths, or combines light from two or more paths to output do. Here, the optical coupler 120 may be a WDM (Wavelength Division Multiplexing) coupler.

The reflective Bragg grating BGR is made of an optical fiber Bragg grating and is sequentially composed of first through Nth reflective Bragg gratings BGR1 through BGRN. The first to Nth reflection Bragg gratings BGR1 to BGRN are sequentially connected to the first to Nth optical couplers 120. The first to Nth reflective Bragg gratings BGR1 to BGRN are sequentially connected to the first to Nth optical couplers 120, 1 to the light (λ ₁ to λ _N) of the N wavelengths, each reflection in sequence, the wavelength of the light 1 to the exception of the light (λ ₁ to λ _N) of the N wavelength is then sequentially transmits.

For example, the first reflective Bragg grating BGR1 reflects the light of the first wavelength λ ₁ , ie, the light of the wavelength λ ₁ , to the first optical coupler, and the second reflective Bragg grating BGR2 reflects the light of the second wavelength and reflecting the light (λ _2), that is, the wavelength of the light λ ₂ to the second optical coupler, the third reflective Bragg grating (BGR3) is light (λ ₃₎ of the third wavelength, i.e. the wavelength of light λ ₃ reflected by the third optical coupler and a fourth reflective Bragg grating (BGR4) reflects the light of the fourth wavelength (λ _4), i.e., λ ₄ wavelength light sequentially to a fourth optical coupler. Thereafter, the same configuration for reflecting the light of a specific wavelength? _N is successively repeated, so it is omitted.

The transmission Bragg grating BGT is made of an optical fiber Bragg grating and is sequentially composed of first through Nth transmission Bragg gratings BGT1 through BGTN. The first to Nth transmission Bragg gratings BGT1 to BGTN are sequentially connected to the first to Nth optical couplers 120 and are respectively reflected by the first to Nth reflective Bragg gratings BGR1 to BGRN, And sequentially transmits the _first to _N- th wavelengths λ ₁ to λ _N branched by the first to Nth optical couplers 120, respectively.

For example, the first transmission Bragg grating BGT1 transmits the first resonator light λ ₁ that is reflected by the first reflective Bragg grating BGR1 and is branched and guided by the first optical coupler, The grating BGT2 transmits the _second wavelength λ ₂ of light reflected by the second reflective Bragg grating BGR2 and branched and guided by the second optical coupler and the third transmission Bragg grating BGT3 transmits the light 3 transmitted by the third optical coupler and guided by the third optical coupler while the fourth transmission Bragg grating BGT4 transmits the _third grating light L3 reflected by the third reflective Bragg grating BGR3, ) And is transmitted by the fourth optical element ( ₄ ) that is branched and guided by the fourth optical coupler. Thereafter, the same configuration for transmitting the light of a specific wavelength λ _N subsequently is repeated, so that it is omitted.

The photodetector PD includes first through Nth photodetectors PD1 through PDN and receives first through Nth wavelength light beams λ ₁ through NBTN transmitted from the first through Nth transmission Bragg gratings BGT 1 through BGTN, To? _N , respectively. Further, the photodetector PD detects light of a specific wavelength and converts it into an electrical signal corresponding thereto.

For example, the first photodetector PD1 detects light (? ₁ ) of the first wavelength transmitted through the first transmission Bragg grating (BGT1) and converts it into an electric signal, and the second photodetector (PD2) and to detect light (λ ₂₎ of the second wavelength transmitted through the Bragg grating (BGT2) converted into an electric signal, third photodetector (PD3) is a third transmitting a third wavelength of light transmitted through the Bragg grating (BGT3) the fourth optical detector into an electrical signal, and to detect the (λ ₃₎ (PD4) with detection light (λ ₄₎ of the fourth wavelength which is transmitted through the fourth transmission Bragg grating (BGT4) is converted into an electrical signal. Thereafter, the same configuration for detecting light of a specific wavelength (λ _N ) and converting it into an electric signal is repeated thereafter, so that it is omitted.

The signal processor 130 sequentially analyzes the wavelength characteristics of the first through N-th wavelengths λ ₁ through λ _N detected from the first through Nth optical detectors PD1 through PDN, respectively. That is, the signal processor 130 analyzes the optical wavelength characteristic of the specific wavelength converted from the photodetector PD into the electrical signal.

Meanwhile, the spectroscope using the optical fiber Bragg grating according to the present invention may further include an optical isolator, a constant temperature device, and an optical filter.

The optical isolator (not shown) transmits the light incident on the optical fiber in the forward direction, that is, the direction of the following optical coupler, and blocks it in the reverse direction, that is, in the direction of the preceding optical coupler. For example, the optical isolator allows the incident light that guides the optical fiber to pass through in the direction of the optical coupler trailing and shields the reflected light returning to the light source or the preceding optical coupler, thereby eliminating measurement and analysis errors of the spectrometer due to oscillation can do.

A thermostat (not shown) maintains a constant temperature in order to minimize the change in the characteristic of the material constituting each transmission Bragg grating and each reflection Bragg grating, that is, the change in refractive index, so that the measurement and analysis error Can be minimized.

According to the configuration of the spectroscope using the optical fiber Bragg grating as described above, after the light of a specific wavelength is reflected by the reflective Bragg grating, the light of a specific wavelength is split by the optical coupler and transmitted by the transmission Bragg grating, stray light, or interference noise. In addition, a fiber Bragg grating that reflects or transmits light of a specific wavelength is sequentially disposed between an optical coupler and a photodetector so that sufficient resolution can be ensured through each photodetector while minimizing the size, and optical fiber Bragg gratings It can be configured independently of the waveguide path overlapping.

The embodiments described in the present specification and the configurations shown in the drawings are merely the most preferred embodiments of the present invention and are not intended to represent all of the technical ideas of the present invention and therefore various equivalents It should be understood that water and variations may be present.

110: optical fiber 120: optocoupler
130: Signal processor BGRN: Nth reflection Bragg grating
BGTN: Nth transmission Bragg grating PD: Photodetector
λ _N : Light of the Nth wavelength

Claims (3)

An optical fiber for guiding and guiding light emitted from a light source,
First to Nth optical couplers for splitting or coupling incident light that is guided to the optical fiber,
First to Nth reflective Bragg gratings respectively connected to the first to Nth optical couplers and respectively reflecting light of first to Nth wavelengths of light incident from the first to Nth optical couplers,
And first to Nth optical couplers respectively connected to the first to Nth optical couplers and respectively reflected by the first to Nth reflective Bragg gratings and branched by the first to Nth optical couplers, Transmitting first to N-th transmission Bragg gratings,
First to Nth optical detectors for respectively detecting light beams of first to Nth wavelengths transmitted from the first to Nth transmission Bragg gratings,
A signal processor for sequentially analyzing wavelength characteristics of light of first to Nth wavelengths respectively detected from the first to Nth optical detectors,
Lt; / RTI >
The first to Nth reflection Bragg gratings are connected in series in the optical fiber
Spectroscope using fiber Bragg gratings. The method of claim 1,
Wherein the first through Nth reflective Bragg gratings and the first through Nth transmission Bragg gratings are optical fiber Bragg gratings. The method of claim 1,
And an optical isolator for transmitting the light incident on the optical fiber in the forward direction and blocking the light in the reverse direction.

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