KR100405279B1 - The module of dispersion compensating fiber - Google Patents

Abstract

The present invention relates to a dispersion compensation optical fiber module, and more particularly, to a dispersion compensation optical fiber module configured to be able to wind more dispersion compensation optical fiber in a module of the same size and to manufacture an optical amplifier integrally.

SUMMARY OF THE INVENTION An object of the present invention is to provide a distributed compensation optical fiber module configured to not only mount a longer dispersion compensation optical fiber but also to install an optical amplifier integrally while occupying the same volume.

In order to realize the above object, the present invention includes a dispersion compensation optical fiber 52 in the box 50 and is connected to the splice 53 and the IN and OUT terminals 54 and 55 installed outside the box 50. A distributed compensation fiber optic module,

In addition, the dispersion compensation optical fiber 52 is formed to be wound and formed in a rectangle so that the length of one side is longer than the other side, characterized in that it comprises a reel (1) configured to mount more dispersion compensation optical fiber 52 It is done.

Description

The module of dispersion compensating fiber

The present invention relates to a dispersion compensation optical fiber module, and more particularly, to a dispersion compensation optical fiber module configured to be able to wind more dispersion compensation optical fiber in a module of the same size and to manufacture an optical amplifier integrally.

In general, a dispersion compensation fiber is required to compensate for the amount of dispersion (+17 ps / nm / km) generated when transmitting a signal of 1550 nm band to a single mode fiber (1310 nm zero dispersion fiber).

The dispersion compensation fiber (Dispersion Compensating Fiber) is usually used to wind a predetermined length on the reel and to connect an optical amplifier (Erbium Doped Fiber Amplifier) to the outside.

That is, as shown in Figs. 4 and 5, the circular reel 51 accommodated in the rectangular box 50, the dispersion compensation optical fiber 52 wound around the reel 51 with a predetermined length, and In addition, the dispersion compensation optical fiber 52 and the splice 53 are connected to each other, and the box 50 is composed of a single mode optical fiber 56 in which the IN and OUT connectors 54 and 55 are installed.

The dispersion compensation ratio of the dispersion compensation optical fiber 52 is determined not only according to the characteristics of the dispersion compensation optical fiber 52 but also according to the length (volume) wound on the reel 51.

For example, if the width of the portion where the dispersion compensation optical fiber 52 can be wound in the reel 51 is W, the outer diameter is D1, the inner diameter is D2, and the optical fiber outer diameter d,

(Mm ³ / km)

The maximum length (km) that an optical fiber can be wound up will be V _REEL / V _FIBER .

However, as described above, when the dispersion compensation optical fiber is wound on a circular reel, since the reel is circular, a large amount of empty space A remains inside the box, and this causes a problem that the space utilization of the dispersion compensation optical fiber module is lowered. have.

That is, since the space utilization of the distributed compensation optical fiber module itself is lowered, space is generated when installing the distributed compensation optical fiber module occupying a predetermined volume, and the space requirement is increased because an optical amplifier must be separately installed. have.

Accordingly, an object of the present invention is to provide a distributed compensation optical fiber module configured to not only mount a longer dispersion compensation optical fiber but also to install an optical amplifier integrally while occupying the same volume.

In order to achieve the above object, the present invention provides a distributed compensation optical fiber module in which a distributed compensation optical fiber is embedded in a box and connected splices to IN and OUT terminals installed outside the box.

In addition, the dispersion compensation optical fiber is formed to be wound, and is formed in a rectangle so that the length of one side is longer than the other side, characterized in that it comprises a reel configured to mount more dispersion compensation optical fiber.

1 is a schematic perspective view showing a dispersion compensation optical fiber module according to the present invention;

Figure 2 is a plan view of the reel in Figure 1,

3 is a schematic diagram illustrating the operation of the dispersion compensation optical fiber module according to the present invention;

4 is a schematic perspective view showing a general dispersion compensation optical fiber module;

FIG. 5 is a plan view of the reel of FIG. 4; FIG.

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

1: reel 2: optical amplifier

3: splice 50: box

52: distributed compensation optical fiber 54: IN terminal

55: OUT terminal

1 and 2 are a schematic perspective view and a front view showing a dispersion compensation optical fiber module according to the present invention, one side outer diameter of the reel (1) is formed in a rectangular shape long one side is D1 and its orthogonal shaft outer diameter is D1 ' And inner diameters D2 and D2 '.

Here, the outer diameter is D1 <D1 ', the inner diameter is made of D2 <D2', so as to minimize unnecessary space not used between the reel (1) and the box 50 inherent in the box 50 do.

That is, since the reel 1 is formed in a rectangular shape so as to fit the entire space in the box 50 used previously, the space utilization rate of the box 50 is further increased, which causes the dispersion compensation optical fiber 52 to It can be wound as long as L * 2.

The length L indicates an increased side length compared to when the conventional reel 51 is circular.

In addition, the central portion of the reel (1) is a rectangular space is formed, it is possible to insert and fix the optical amplifier (2) in the rectangular shape, it is possible to manufacture the dispersion compensation optical fiber module more compact.

When explaining the operation and effect of the present invention as described above, when the reel (1) manufactured in a rectangular shape is embedded in the box 50, the dispersion compensation optical fiber 52 in the reel (1) It is wound by the volume accordingly.

That is, compared with the volume in the conventional Equation 1, the length or volume by L × (D 1 -D 2) is increased so that the dispersion compensation optical fiber 52 can be wound more.

When the dispersion compensation optical fiber 52 is wound on the reel 1, the optical amplifier (DCFM) 2 is inserted into the center of the reel 1, and the splice 3 is connected to the dispersion compensation optical fiber 52. do.

Inserting the reel 1 wound around the dispersion compensation optical fiber 52 into the box 50 and connecting the dispersion compensation optical fiber 52 to the IN and OUT terminals 54 and 55 through the splice 53 The module production is complete.

As described above, when the dispersion compensation optical fiber module having the optical amplifier 2 is built, as shown in FIG. 3, when the optical signal of 1550 nm is transmitted to a single optical fiber optimized for 1310 nm, dispersion and optical signal attenuation occur simultaneously. do.

The dispersion is modulated into a signal that is compensated by the dispersion compensation optical fiber 52 and has the same band as the first transmitted optical signal and is attenuated.

When the dispersion-compensated optical signal enters the optical amplifier 2 again, the attenuation of the optical signal is reduced back to the initial state by the optical amplifier 2, thereby eliminating the loss of the optical signal when passing through the optical fiber. .

As described above, when the size of the dispersion compensation optical fiber module is reduced, the utilization of a system rack (not shown) for accommodating the same may be increased.

As described above, the present invention does not increase the size of the dispersion compensation optical fiber module, and by incorporating the optical amplifier into the dispersion compensation optical fiber module, thereby reducing the overall size of the dispersion compensation optical fiber module and the rectangular reel in which the dispersion compensation optical fiber is wound It is an advantage that the more efficient space utilization can be made by manufacturing.

Claims (2)

In the distributed compensation optical fiber module spliced with the IN and OUT terminals installed outside the box and spliced compensation fiber inside the box, The dispersion compensation optical fiber module comprising a reel formed so that the dispersion compensation optical fiber is wound and formed in a rectangle such that the length of one side is longer than the other side, so that the dispersion compensation optical fiber can be mounted more. The method of claim 1, Dispersion compensation optical fiber module, characterized in that the intrinsic optical amplifier in the space formed in the center portion of the reel, and connected to the dispersion compensation optical fiber through a splice to compensate for the attenuation of the optical signal.