KR100328778B1 - The gain flattening filter for Er-doped fiber amplifier - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gain flatten filter for an optical fiber amplifier, wherein the gain flattener filter for an optical fiber amplifier is formed by adding erbium to an optical fiber and then stretching the tape to form a taper shape. The wide band can be flattened and can be manufactured according to the characteristics of many kinds of various optical fiber amplifiers by freely adjusting the length of the optical fiber to which erbium is added. In addition, since only one reinforcing agent is obtained by stretching the erbium-doped optical fiber into a tapered shape, the size of the device is reduced and the optical properties are hardly changed with temperature.

Description

The gain flattening filter for Er-doped fiber amplifier

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a gain flatten filter for an optical fiber amplifier, and more particularly, to a filter for flattening a gain curve of an Erbium Doped Fiber Amplifer (EDFA) used in an optical communication system.

Erbium-doped fiber amplifier (EDFA) is an ideal optical amplifier that can solve the loss of optical fiber in the optical fiber at 1.55㎛ wavelength.

The EDFA can extend the transmission distance from tens of Km to hundreds of Km, amplify the signal regardless of the transmission speed, and evenly amplify the signal over a wide bandwidth, so that wavelength division multiplexing (WDM) ) Also enables transmission.

1 is a schematic diagram showing the configuration of a conventional general optical fiber amplifier (EDFA).

As shown in FIG. 1, components constituting the EDFA are classified into the following. That is, optical amplification optical fiber (EDF) 1, WDM optical coupler 2, optical isolator 3, excitation light source 4, optical filter 5 and the like. In the optical amplification optical fiber (EDF) 1, erbium is added as an amplification medium, and the WDM optical coupler 2 is a device that combines a signal light source and an excitation light. The optical isolator 3 prevents light from returning, and the excitation light source 4 serves as an energy source for amplifying the optical amplified optical fiber. The gain flat type optical filter 5 functions to flatten the non-uniform optical amplifier.

2 is a diagram illustrating a system wavelength of a conventional general optical fiber amplifier.

When the conventional optical fiber amplifier 6 having the above structure is used, the characteristic of the amplified wavelength generated in the optical fiber amplifier 6 is represented by the shape (a) of the wavelength shown in FIG.

Therefore, the filter 5 having the wavelength characteristic as shown in (b) of FIG. 2a is used to planarize to have the wavelength characteristic as shown in (c) of FIG. 2a. The present invention relates to the above filter.

Like the wavelength having the characteristic as shown in (a) of FIG. 2a, due to the inherent characteristics of the optical fiber amplifier, the amplified portion is not flattened, and a filter is generally used to flatten the uneven portion.

3 (a) and 3 (b) are diagrams showing a long-period optical fiber lattice filter and a system wavelength, respectively, which are gain gain filters for a conventional optical fiber amplifier,

4 (a) and 4 (b) are diagrams illustrating a multi-stage fabricated ferret-type filter and a system wavelength, respectively, which are gain gain filters for a conventional optical fiber amplifier.

A filter generally used at present is a method of using a plurality of long-period optical fiber lattice type filters 8 formed by forming a lattice having a constant refractive index in the optical fiber 7, as shown in Fig. 3 (a). There is a method using a plurality of filters 9 in the form of multistage ferret-ferot, as shown in 3 (b).

The method using the optical fiber grating filter 8 includes a plurality of wavelengths as shown in each wavelength, e.g., in Figure 3 (b), to suit the wavelength amplified through the optical fiber amplifier (a in Figure 2a). A filter is manufactured so that three to seven optical fiber gratings having inherent characteristics are connected to each other so as to exhibit the characteristics as shown in FIG. 5 (a).

That is, using a filter having a plurality of wavelengths, such as the wavelength (ㅁ) shown in Figure 3 (b) is produced to be a curve such as the wavelength (d) and the gain curve (a) suitably arranged.

Another method is to use a filter 9 in the form of a multi-stage ferret-perot as shown in FIG. 4.

This method is also manufactured by connecting a plurality of wavelength filters in order to make each filter having a characteristic such as wavelength (′ ′) shown in FIG. 4 (b) to have a characteristic curve such as (′ ′).

In the case of using the two conventional methods described above, the filter must be manufactured in multiple stages, thereby increasing the size of the device and complicating the manufacturing process, and the combination of the respective components may change characteristics depending on temperature. . As a result, the process of manufacturing the conventional filter is difficult, and there is a problem in that the cost or increase is required.

Accordingly, the present invention has been made to solve the above problems, and the present invention provides a gain flat filter for an optical fiber amplifier in which the size of the device is small and there is almost no change in optical characteristics according to temperature, and the manufacturing cost is low. There is this.

1 is a schematic diagram showing the configuration of a conventional general optical fiber amplifier

2 is a diagram illustrating a system wavelength of a conventional general optical fiber amplifier.

3 (a) and 3 (b) show a long-period optical fiber grating filter and a system wavelength, respectively, which are gain gain filters for a conventional optical fiber amplifier.

4 (a) and 4 (b) are diagrams illustrating a multi-stage fabricated ferret-type filter and a system wavelength, respectively, which are gain flatness filters for a conventional optical fiber amplifier.

FIG. 5 is a diagram showing characteristics of an optical fiber device which is tapered and connected to an optical fiber to which erbium is added according to the technique of the present invention. FIG.

6 is a view showing a method of manufacturing a gain flatten filter for an optical fiber amplifier of the present invention and its structure;

<Description of the symbols for the main parts of the drawings>

1 optical amplification optical fiber 2 optical coupler

3: optical isolator 4: light source for excitation

5: gain flatness filter 6: fiber amplifier

7: optical fiber 8: optical fiber lattice

9: Ferret-Perot filter 10: Taper tension part

13: reinforcing agent

In order to achieve the above object, a gain flatten filter for an optical fiber amplifier of the present invention,

An optical amplification optical fiber (EDFA) to which erbium is added is placed at the front end of the filter to absorb light in a predetermined wavelength region to flatten the wavelength region of the optical amplifier;

The middle portion of the filter is made by twisting a plurality of optically amplified optical fibers with each other, and then heat-welded to form a tapered portion by applying heat to the wire;

The rear end of the filter is characterized in that the fusion-strengthened portion and the general optical fiber is configured to be connected.

Hereinafter, a gain flatten filter for an optical fiber amplifier according to the present invention will be described in detail with reference to the accompanying drawings.

5 is a view showing the characteristics of the optical fiber element tensioned by the erbium-added optical fiber and the tapered model according to the technique of the present invention,

6 is a diagram showing a method of manufacturing a gain flatten filter for an optical fiber amplifier of the present invention and its structure.

As shown in FIG. 6, the gain flattening filter for the optical fiber amplifier of the present invention combines the absorption characteristics of the optically amplified optical fiber 1 to which erbium is added and the characteristics of the tapered tensioned optical fiber element. At this time, the tapered tension portion is indicated by the reference numeral (10). An optical amplification fiber (1) was placed at the front end to flatten the 1530 nm area of the optical amplifier by using the absorption characteristics of the 1530 nm area, and in order to planarize the 1540 nm area, the general optical fiber (7) and the optical amplification fiber (EDF) or the optical amplification fiber (EDF). ) And the optical amplification optical fiber (EDF) (1) is directly connected to the optical amplification optical fiber of the front end is placed in the rear end.

In the manufacturing method of the present invention, the general optical fiber (or optical amplified fiber) at the input terminal and the optical amplified optical fiber (EDF) 1 at another input terminal are rotated by 180 turns to twist each other, and then heat is applied from the outside as shown in FIG. After application, they are fused and welded. At this time, the light source coming into the general fiber and the light source coming into the optical amplification fiber (EDF) 1 are combined with each other and come out to the output terminal. In this situation, when the light source coming from the both ends of the light source exhibits 0% or 100% of the coupling ratio in the 1540nm region at the output end, the tensioning operation is completed, and as shown in FIG. On the other hand, Figure 6 (c) is a view showing a state used as the final product.

The absorption characteristic curve of the erbium-doped optical fiber becomes as shown in the curve shown in Fig. 5A. However, the characteristic curve of the tapered optical fiber has the same characteristics as the curve (ㅅ) when passing through the tapered tension portion 10 of the optical fiber.

Therefore, the curve (o) shown in FIG. 5 (a) is a combination of the two curves (i) and (s), which can be obtained by combining the respective curve characteristics. Therefore, when the filter 12 is manufactured by stretching the erbium-doped optical fiber of the present invention into a tapered shape, the characteristic curve of the filter 12 becomes the curve (o) of FIG.

Therefore, when the filter 12 element of the present invention having the characteristic curve (o) is used as a filter which is a component of the optical fiber amplifier EDFA shown in FIG. 1, the curve (c) of FIG. Effect.

As described above, the gain flattening filter for the optical fiber amplifier of the present invention as described above can flatten a wider band and can be manufactured according to the characteristics of many kinds of various optical fiber amplifiers by freely adjusting the length of the optical fiber to which erbium is added. have.

In addition, unlike the conventional method, since only one reinforcing agent is obtained by tensioning an erbium-doped optical fiber into a tapered shape, the size of the device is reduced and there is little change in optical characteristics with temperature.

Claims (5)

A gain flatten filter for an optical fiber amplifier used in an optical communication system, An optical amplification optical fiber (EDFA) to which erbium is added is placed at the front end of the filter to absorb light in a predetermined wavelength region to planarize the wavelength region of the optical amplifier; The middle portion of the filter is made by twisting a plurality of optically amplified optical fibers with each other, and then heat-welded to form a tapered portion by applying heat to the wire; A gain flattening filter for an optical fiber amplifier, characterized in that the rear end portion of the filter is configured such that the fusion-stretched portion and the general optical fiber are connected. The method of claim 1, The plurality of optical fibers forming the twist is a gain flatten filter for an optical amplifier, characterized in that the optical amplification optical fiber and optical amplification optical fiber or optical amplification optical fiber and a combination of a general optical fiber The method according to claim 1 or 2, The plurality of optical fibers to form the twist is the gain flattening filter for the optical fiber amplifier, characterized in that the twisted rotation by 180 optical fibers. The method of claim 1, A gain flattening filter for a fiber amplifier, characterized in that the front end portion of the gain flattening filter in which the optical amplified optical fiber is located absorbs a wavelength region of 1530 nm. The method of claim 1, The intermediate portion of the filter formed tapered portion gain flatness filter for the optical fiber amplifier, characterized in that absorbs a wavelength range of 1540nm.