KR100417466B1 - Method of manufacturing a microbending long-period fiber grating - Google Patents

Abstract

The present invention relates to a method for manufacturing a micro banding long-period optical fiber grating and grating pairs, the method comprising periodically arranging and attaching carbon rods having a constant diameter on a plate, and raising the optical fiber on a plate on which the carbon rods are periodically arranged. Forming a micro banding on the optical fiber core with the stress applied above, and combining the core mode and the cladding mode at a specific wavelength satisfying the phase matching condition by the micro banding periodically formed on the optical fiber, Microbanding long periods that can tune the center wavelength of the absorption band by creating an absorption band and changing the lattice period according to the angle between the periodically arranged carbon rods and the optical fiber placed thereon. Long period optical fiber The grating can be easily manufactured, and the spectral characteristics are also excellent.

Description

Method of manufacturing micro banding long period fiber gratings

The present invention relates to a method for manufacturing a micro banding long-period fiber grating and grating pair, and more particularly, it is easy and simple to fabricate by forming a micro banding in the optical fiber core with the pressure of pressing the optical fiber on the periodically arranged carbon rods and pressing it on the above. The present invention relates to a micro banding long cycle optical fiber grating and a method for manufacturing a pair of gratings capable of manufacturing the excellent long period optical fiber grating. Is active. The optical fiber grating creates an interference pattern of a strong ultraviolet (UV) beam within a germanium (Ge) -doped optical fiber core for a certain time or slightly increases the refractive index when irradiating light in the ultraviolet region using a phase mask. The optical fiber device is fabricated by periodically modulating the refractive index of the optical fiber core using the phenomenon, and is a key device in the field of optical communication and optical fiber sensors. The optical fiber grating is divided into a short period grating having a refractive index change period of about 0.5 μm and a long period grating having a refractive index change period of about 500 μm. The optical fiber grating device has advantages in that the optical fiber grating device is made entirely of optical fiber, has low insertion loss, and high return loss, compared to the device having the same function as the bulk type. These fiber gratings have been applied to various fields such as sensors for measuring temperature and displacement, filters for WDM, gain flattening elements of optical amplifiers, and elements for compensating optical fiber dispersion. However, the conventional optical fiber grating has a disadvantage in that the manufacturing cost is high and difficult to manufacture and complicated and requires high cost equipment.

An object of the present invention created to solve the above problems is to form a micro banding in the optical fiber core with the pressure to press the optical fiber on the carbon rods arranged on a periodically arranged on the top of the long period optical fiber grating is easy and simple and excellent in spectral characteristics SUMMARY OF THE INVENTION An object of the present invention is to periodically arrange and attach a carbon rod having a constant diameter on a plate, and to periodically arrange the carbon rod. Raising the optical fiber onto the plate and forming a micro banding on the optical fiber core with the stress applied on it, and the core mode and cladding mode at a specific wavelength satisfying the phase matching condition by the micro banding periodically formed on the optical fiber. Is coupled to the transmission spectrum Microbanding long periods to tune the center wavelength of the absorption band by generating a few bands, and the lattice periods vary depending on the angle between the periodically arranged carbon rods and the optical fiber placed thereon. It can be achieved by a method for producing a micro banding long period optical fiber grating characterized in that it comprises a step of completing the optical fiber grating. In addition, an object of the present invention, two identical plates in which the carbon rods are arranged periodically Arranging in series at appropriate intervals, and forming two symmetric microbands in the optical fiber core with pressure to press and press the optical fiber on the two plates arranged periodically with the carbon rods; After two identical bands are created to satisfy the phase matching condition. Microbanding long-period fiber grating pairs comprising the steps of completing a microbanding long-period fiber grating pair in which interference fringes occur in the transmission spectrum by coupling and interference of the core mode and the cladding mode at a particular wavelength It can be achieved by the production method of.

1 is a cross-sectional view showing a method for manufacturing a micro banding long period optical fiber grating according to an embodiment of the present invention.

FIG. 2 is a graph illustrating transmission spectrum characteristics of the micro banding long period optical fiber grating of FIG. 1.

3 is a cross-sectional view showing a method for manufacturing a micro banding long period optical fiber grating pair according to another embodiment of the present invention.

4 is a graph showing transmission spectral characteristics of the microbanding long period optical fiber grating pair of FIG. 3.

<Description of the code | symbol about the principal part of drawing>

1, 11: optical fiber 3, 13: upper plate

4, 14: graphite rods 5, 15: lower plate

P1, P2: pressure

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. FIG. 1 is a cross-sectional view illustrating a method of manufacturing a micro banding long period optical fiber grating according to an embodiment of the present invention. In the method of manufacturing a micro banding long period fiber grating, a micro banding long period fiber grating is formed by periodically arranging carbon rods 4 having a constant diameter, and forming a micro banding on the fiber core with a pressure P1 on which the optical fiber 1 is placed thereon. . This is easier, simpler and more expensive to manufacture than conventional fiber gratings made by irradiating UV light with periodic changes in the refractive index of the core. Here, reference numerals "3" and "5" are respectively "top". Flat plate " and " lower flat plate &quot;. The transmission spectrum by such a micro banding long period fiber grating can be seen in FIG. The micro banding long period optical fiber grating combines the core mode and the cladding mode at a specific wavelength that satisfies the phase matching condition, so that the light propagating to the core exits the cladding and disappears, resulting in an absorption band. A phase matching condition for combining the basic mode traveling into the core and the cladding mode in the traveling direction is represented by Equation 1.

Here, Λ is a grating period of the long period optical fiber grating, β ₀₁ is a propagation constant of the basic mode, β _cl ⁽ⁿ⁾ is a propagation constant of the n-th cladding mode. As such, the absorption bandwidth of the micro banding long period optical fiber grating is very wide, 15 µm or more, and in particular, the lattice period is changed according to the periodically arranged carbon rods and the angle of the optical fiber placed thereon, so that the center wavelength of the absorption band can be easily adjusted. Tuning is very effective in the application of the filter for gain flattening of optical fiber amplifiers.

3 is a cross-sectional view showing a method for manufacturing a micro banding long period optical fiber grating pair according to another embodiment of the present invention. In the method for manufacturing a micro banding long period optical fiber grating according to the present invention, a carbon rod 14 having a constant diameter is periodically arranged. Arrange the same two lower plates in series at appropriate intervals and form a symmetric micro banding in the optical fiber core with the pressure P2 which raises the optical fiber 11 over the carbon rods 14 and presses on the micro A banding long period optical fiber grating pair (MLPFG pair) is produced. Here, reference numeral "13" is "top plate". The transmission spectrum by the micro banding long period optical fiber grating pair can be seen in FIG. In the microbanding long period fiber grating pair, part of the light incident on the fiber core is combined with the cladding mode in the first long period fiber grating, and again in the second long period fiber grating, the core mode and cladding mode are combined again, resulting in interference between modes Creates an interference fringe according to the wavelength. As such, micro-banding long-period grating pairs can be manufactured that are easier, simpler, and more expensive than conventional long-period fiber grating pairs, and do not require expensive equipment, and are suitable for optical sensors, refractive index measurements, and all-optical switches. It can be applied in various ways.

As described above, the micro banding long period optical fiber grating (MLPFG) and the micro banding long period optical fiber grating pair (MLPFG) are easier and simpler to manufacture than the conventional fiber grating made by irradiating ultraviolet light, and have excellent transmission spectrum characteristics. However, there is an advantage that the lattice period is changed according to the angle between the periodically arranged carbon rods and the optical fiber placed thereon, thereby tuning the center wavelength of the absorption band. Furthermore, the present invention can be applied to various fields such as a WDM filter for ultra-high speed optical communication, a gain-flattening filter of an optical fiber amplifier, an optical sensor, and the like.

Claims (2)

Periodically arranging and attaching carbon rods having a constant diameter on a plate; Raising the optical fiber over a plate on which the carbon rods are periodically arranged and forming micro banding in the optical fiber core with a stress applied thereon; Coupling the core mode and the cladding mode at a specific wavelength satisfying the phase matching condition by micro banding periodically formed in the optical fiber to generate an absorption band in the transmission spectrum; And completing a micro banding long-period fiber grating capable of tuning the center wavelength of the absorption band by changing the lattice period according to the angle between the periodically arranged carbon rods and the optical fiber placed thereon. Method for producing a micro banding long period optical fiber grating characterized in that configured. Arranging two identical plates in which carbon rods are periodically arranged in series at appropriate intervals, Forming two symmetric micro bands in the optical fiber core under pressure to raise and press the optical fiber on the two plates where the carbon rods are periodically arranged; Microbanding long-period fiber grating pairs with interference patterns in the transmission spectrum due to the coupling and interference of the core mode and the cladding mode at a specific wavelength satisfying the phase matching condition by two identically made microbands after the above step. A method of manufacturing a micro banding long period optical fiber grating pair, comprising the step of completing the.