KR101567430B1 - Multi chanel coarse wavelength division multiplexing module - Google Patents

Abstract

The present invention relates to a multi-channel low-density wavelength division multiplexing module. The multi-channel low-density wavelength division multiplexing module includes a first capillary that receives light from the outside and passes the incident light, a first lens that is connected to the capillary and directs the incident light straight, A CWDM filter which is connected to the first lens and filters the light passing through the first lens to output the filtered light and reflects the remaining unfiltered light, And a second capillary that is connected to the second lens and directs the light that has passed through the second lens to output the light through a channel, a coarse wavelength division multiplexing (CWDM) package Wherein at least one of the at least two CWDM packages comprises at least two CWDM packages, Rather it receives the remaining light is reflected by the CWDM filter of another package that is not the CWDM filter. Therefore, by arranging the CWDM packages in a parallel structure, the size of the CWDM module can be miniaturized and manufactured.

Description

[0001] MULTI CHANEL COARSE WAVELENGTH DIVISION MULTIPLEXING MODULE [0002]

The present invention relates to a multi-channel low-density wavelength division multiplexing module.

The dense wavelength division multiplexing (DWDM) is an optical transmission method that simultaneously transmits multiple light wavelengths on a single optical cable, and a coarse wavelength division multiplexing (CDWM) It is a way to integrate / branch gigabit interfaces by divided wavelengths.

The CWDM uses the bandwidth in the range provided by the optical cable, and thus can lower the price of the laser diode (LD) used in the optical transmission unit and the filter used in the wavelength division multiplexing. Therefore, The economic efficiency of the system can be improved.

A multi-channel CWDM module having a plurality of CWDM packages arranges CWDM packages so that the output light of one CWDM package is incident on another adjacent CWDM package, wherein the multi-channel CWDM module uses an optical fiber to transmit the light of each CWDM package Lt; / RTI >

However, in the case of the multi-channel CWDM module thus formed, due to the radius of curvature of the optical fibers connecting the respective CWDM packages, it is impossible to arrange the arranging intervals of the respective CWDM packages narrower than a predetermined interval, There is a problem that the size of the CWDM module can not be formed to a certain size or less.

SUMMARY OF THE INVENTION The present invention is directed to miniaturize the size of a multi-channel CWDM module.

A multi-channel low-density wavelength division multiplexing module according to an embodiment of the present invention includes a first capillary for receiving light from the outside and passing the incident light, a second capillary connected to the capillary, A CWDM filter which is connected to the first lens and filters the light passing through the first lens to output filtered light and reflects the remaining unfiltered light, And a second capillary that is connected to the second lens and directs the light passing through the second lens to output the light through the channel, coarse wavelength division multiplexing (CWDM) package, wherein at least one of the at least two CWDM packages includes at least two Receives a one of the other light than the CWDM package that is not the filtered reflected by the CWDM filter of another CWDM package.

The CWDM filter of the at least two CWDM packages may filter light passing through the first lens at different central wavelengths.

The one CWDM package and the other CWDM package may be disposed to face each other at 180 degrees.

According to this feature, the multiplexed CWDM module has a first group and a second group having a plurality of CWDM packages in one direction, the CWDM packages included in the first group include CWDM packages included in the second group and 180 Are arranged to face in different directions. Accordingly, the incident light incident on the first package of the first group is reflected by the first package and is incident on the second package of the second group, and the incident light incident on the second package is reflected by the second package, The first package is incident on the third package, and the first through eighth packages of the first and second groups output light through the first through eighth channels, respectively. As such, since the first to eighth packages are arranged in the first and second groups, the size of the multiplexed CWDM module of the present invention can be miniaturized and manufactured.

1 is a schematic block diagram of a multi-channel low-density wavelength division multiplexing module according to an embodiment of the present invention.
FIG. 2 is a diagram illustrating a schematic configuration of a multi-channel low-density wavelength division multiplexing module according to another embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily carry out the present invention. The present invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. In order to clearly illustrate the present invention, parts not related to the description are omitted, and similar parts are denoted by like reference characters throughout the specification.

Hereinafter, a multi-channel low-density wavelength division multiplexing module according to an embodiment of the present invention will be described with reference to the accompanying drawings.

First, referring to FIG. 1, a multi-channel LDD wavelength division multiplexing module according to an embodiment of the present invention will be described in detail.

Referring to FIG. 1, a multi-channel low-density wavelength division multiplexing module 10 according to an embodiment of the present invention includes a plurality of CWDM packages, a plurality of optical fibers, and a module case 11 .

The plurality of CWDM packages include a first package 100, a third package 300, a fifth package 500 and a seventh package 700 belonging to the first group G1 and a second package G2 belonging to the second group G2. A second package 200, a fourth package 400, a sixth package 600, and an eighth package 800.

Each of the first to eighth packages 100 to 800 is a multi-channel low-density wavelength division multiplexing (CWDM) package. When the first package 100 is taken as an example, A first capillary 110 for receiving incident light input from the outside through the first optical fiber 1 and a second capillary 110 connected to the first capillary 110, A first lens 120 which is connected to the first lens 120 and filters the linearly transmitted light having passed through the first lens 120 in the CWDM band and outputs the filtered light A second CWDM filter 130 disposed apart from the first CWDM filter 130 for collecting and filtering the filtered light filtered by the first CWDM filter 130 to output linear light, 140), and a second lens (140), and passes the linear light output from the second lens (140) And a second capillary 150 for outputting the first output light 2 to the first channel CH1.

The incident light input to the first capillary 110 may be light incident from a com port.

At this time, the first CWDM filter 130 divides the straight-line light having passed through the first lens 120 by dividing the wavelength from the center wavelength to an error range of 2 nm, filters the partial light of the filtered linear light toward the second lens 140 .

At this time, the first CWDM filter 130 reflects the remaining unfiltered straight-line light and outputs it to the second optical fiber 21 through the first lens 120 and the first capillary 110.

The first and second lenses 120 and 140 may be G-lenses.

The first package 100 is configured to enclose the first capillary 110, the first lens 120, the first CWDM filter 130, the second lens 140 and the second capillary 150 The first package 100, which has an integral structure including a case made of a glass material and is surrounded by a glass case, may further include a casing made of stainless steel.

The first package 100 is formed to have the structure as described above, and the multi-channel low-density wavelength division multiplexing module 10 of the present invention includes a plurality of CWDM modules having the same structure as the first package 100 .

In one example, the plurality of first packages 100 may include a second package 200, a third package 300, a fourth package 400, a fifth package 500, a sixth package 600, 7 package 700, and an eighth package 800 to provide eight packages.

At this time, the second package 200 includes a first capillary 210, a first lens 220, a second CWDM filter 230, a second lens 240, and a second capillary 250 do.

The first capillary 210 of the second package 200 receives and transmits light transmitted from the first package 100 through the second optical fiber 21.

The light incident on the second package 200 is incident on the first package 100 as part of the light emitted from the first capillary 110 of the first package 100, The light is reflected by the first CWDM filter 130 without being filtered and output to the first capillary 110.

That is, some light reflected from the first package 100 is incident on the second package 200 through the second optical fiber 21.

The first capillary 210, the first lens 220, the second CWDM filter 230, the second lens 240 and the second capillary 250 of the second package 200 are arranged in the first package 200, The first capillary 110, the first lens 120, the first CWDM filter 130, the second lens 140, and the second capillary 150 of the camera 100 are identical in structure to each other, The configuration performs the same operation.

Since the first package 100 and the second package 200 are disposed opposite to each other, the light output from the first package 100 is transmitted through the second optical fiber 21 to the second package 200 ).

The second capillary 250 of the second package 200 outputs the second output light 3 in the second channel CH2 and the second output light 3 in the second CWDM filter 230, 3 optical fiber 31 as shown in Fig.

At this time, the filtering range center wavelength of the second CWDM filter 230 of the second package 200 has a different wavelength value from the center wavelength of the first CWDM filter 130 of the first package 100.

The third package 300 is positioned in the same direction as the first package 100 and includes a first capillary 310, a second lens 320, a third CWDM filter 330, a second lens 340, And a third capillary 350. The second capillary 350 receives the light output from the second package 200 through the third optical fiber 31 and outputs the third output light 4 through the third channel CH3 And outputs a part of the light reflected by the third CWDM filter 330 to the fourth optical fiber 41.

The fourth package 400 is positioned in the same direction as the second package 200 and includes a first capillary 410, a first lens 420, a fourth CWDM filter 430, a second lens 440, And a second capillary 450. The second capillary 450 receives the light output from the third package 300 through the fourth optical fiber 41 and outputs the fourth output light 5 through the fourth channel CH4. And outputs some light reflected by the fourth CWDM filter 430 to the fifth optical fiber 51.

The fifth package 500 is positioned in the same direction as the first package 100 and the third package 300 and includes a first capillary 510, a first lens 520, a fifth CWDM filter 530, A second lens 540 and a second capillary 550. The light emitted from the fourth package 400 is transmitted through the fifth optical fiber 51 and is incident on the fifth channel CH5, And outputs the output light 6 and some light reflected by the fifth CWDM filter 530 to the sixth optical fiber 61.

The sixth package 600 is positioned in the same direction as the second package 200 and the fourth package 400 and includes a first capillary 610, a first lens 620, a sixth CWDM filter 630, And a second lens 640 and a second capillary 650. The light output from the fifth package 500 is transmitted from the sixth optical fiber 61 to the sixth channel CH6, And outputs a part of the light reflected by the sixth CWDM filter 630 to the seventh optical fiber 71. [

The seventh package 700 is positioned in the same direction as the first package 100, the third package 300 and the fifth package 500 and includes a first capillary 710, a first lens 720, 7 CWDM filter 730, a second lens 740 and a second capillary 750 and receives light output from the sixth package 600 from the seventh optical fiber 71, And outputs the seventh output light 8 to the seventh CWDM filter 770 and the seventh CWDM filter 730 to the eighth optical fiber 81. [

The eighth package 800 is located in the same direction as the second package 200, the fourth package 400 and the sixth package 600 and includes a first capillary 810, a first lens 820, The eighth CWDM filter 830, the second lens 840 and the second capillary 850. The seventh optical fiber 81 receives the light output from the eighth optical fiber 81, And the eighth output light 9 is outputted through the eight channels CH8.

A part of the light reflected by the eighth CWDM filter 830 passes through the ninth optical fiber 91, and the end of the ninth optical fiber 91 is formed to be inclined by an angle A.

In one example, the inclination A of the end of the ninth optical fiber 91 is preferably 82 degrees. A is formed to have an angle of 82 degrees, thereby blocking part of the reflected light of the eighth CWDM filter 830 incident on the ninth optical fiber 91 from being reflected at the end of the ninth optical fiber 91. [ Therefore, the light reflected by the eighth CWDM filter 830 and introduced into the ninth optical fiber 91 does not enter the eighth CWDM filter 830 again. That is, a part of the light reflected by the eighth CWDM filter 830 is introduced into the ninth optical fiber 91 and reflected by the eighth CWDM filter 830 by the inclination formed at the end of the ninth optical fiber 91 It does not.

2, a part of the light reflected by the seventh CWDM filter 730 of the seventh package 700 is outputted as the eighth output light 9 through the eighth optical fiber 81 .

In the example shown in FIG. 2, only the second package 200, the fourth package 400 and the sixth package 600 except for the eighth package 800 belong to the second group G2 .

The third CWDM filter 330, the fourth CWDM filter 430, and the third CWDM filter 330, as described above, that the filtering range center wavelengths of the first CWDM filter 130 and the second CWDM filter 230 have different wavelength values, The fifth CWDM filter 530, the sixth CWDM filter 630, the seventh CWDM filter 730 and the eighth CWDM filter 830 all have different filtering range center wavelengths.

Since the first to eighth CDWM filters 130, 230, 330, 430, 530, 630, 730 and 830 have central wavelength values of different filtering ranges, the first through eighth channels CH1, The first to eighth output lights 2, 3, 4, 5, 6, 7, 8, and 9 output to the first to eighth output lights CH1, CH4, CH5, CH6, CH7, and CH8 have different wavelength values.

The first, third, fifth, and seventh packages 100, 300, 500, 700 belonging to the first group G1 are arranged in one direction, and the second, third, 4, 6th and 8th packages 200, 400, 600, 800 are disposed 180 degrees opposite to the packages of the first group G1.

As described above, since the first and second groups G1 and G2, each having a package in the row direction, are positioned in opposite directions to each other, the output (output) from any one of the packages of the first group G1 The light is incident on any one of the packages of the second group G2 as incident light and the output light output from any one of the packages of the second group G2 is incident on any one of the packages of the first group G1 As an incident light.

Accordingly, a plurality of CWDM packages are arranged in parallel in the first and second groups G1 and G2, thereby miniaturizing the multi-channel CWDM module 10.

The module case 11 surrounding the first to eighth packages and the first to eighth optical fibers may be made of a plastic material.

The multi-channel low density wavelength division multiplexing module according to an embodiment of the present invention having such a structure includes a first optical fiber 1, a first capillary 110, a first lens 120, The first lens 220, the third optical fiber 31, the first capillary 310, the first lens 320, and the fourth optical fiber (not shown). The first capillary 210, the first lens 220, The first capillary 410, the first lens 420, the fifth optical fiber 51, the first capillary 510, the first lens 520, the sixth optical fiber 61, The first capillary 610, the first lens 620, the seventh optical fiber 71, the first capillary 710, the first lens 720, the eighth optical fiber 81, The first capillary 810, the first lens 820 and the ninth optical fiber 91 are first fabricated, the above components are arranged, and the remaining components are arranged to form a multi-channel low density wavelength division multiplexing module 10).

By arranging the components in this order to fabricate the module 10 of the multi-channel low-density wavelength division multiplexing system, the defect rate can be minimized.

Next, the operation of the multi-channel low-density wavelength division multiplexing module 10 according to an embodiment of the present invention will be described with reference to FIG.

First, the incident light incident through the comfort is incident on the first package 100 through the first optical fiber 1, passes through the first capillary 110, the first lens 120, And is filtered by the CWDM filter 130.

At this time, a part of the filtered light passes through the second lens 140 and the second capillary 150 and is output as the first output light 2 to the first channel CH1, 1 CWDM filter 130 and is output to the second optical fiber 21 through the first lens 120 and the first capillary 110.

The light output to the second optical fiber 21 is incident on the first capillary 210 of the second package 200 and passes through the first capillary 210 and the first lens 220, 2 CWDM filter 230 and then output through the second lens 240 and the second capillary 250 as the second output light 3 to the second channel CH2.

At this time, the remaining unfiltered light in the second CWDM filter 230 is reflected by the second CWDM filter 230 and passes through the third optical fiber 31 through the first lens 220 and the second capillary 210, .

Subsequently, the light incident on the third package 300 through the third optical fiber 31 is partially filtered to be output as the third output light 4 to the third channel CH3, and the remaining unfiltered light Is reflected by the third CWDM filter 330 and output to the fourth optical fiber 41.

A part of the light incident on the fourth package 400 through the fourth optical fiber 41 is filtered and output as the fourth output light 5 to the fourth channel CH4, And reflected by the fourth CWDM filter 430 to be output to the fifth optical fiber 51.

Similarly, the light incident on the fifth package 500 through the fifth optical fiber 51 is partially output to the fifth channel CH5 and partially output to the sixth optical fiber 61, The light incident on the sixth package 600 through the fiber 61 is partially output to the sixth channel CH6 and partially output to the seventh optical fiber 71. [

Finally, the light incident on the seventh package 700 through the seventh optical fiber 71 is partially output to the seventh channel CH7 and partially output to the eighth optical fiber 81, The light incident on the eighth package 800 through the optical fiber 81 is output to the eighth channel CH 8.

As a result, the incident light incident on the comfort is output to the first to eighth channels CH1 to CH8 through the first to eighth packages 100 to 800, respectively.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed exemplary embodiments, It belongs to the scope of right.

1, 21, 31, 41, 51, 61, 71, 81: Optical fiber
10: Multi-channel low-density wavelength division type module 11: Module case
100: first case 110: first capillary
120: first lens 130: first CWDM filter
140: second lens 150: second capillary

Claims (3)

A first lens which is connected to the first capillary and directs the incident light to pass through, a first lens which is connected to the first lens, A CWDM filter for filtering the light having passed through the first lens to output a part of the filtered light and reflecting the remaining unfiltered light to enter the first optical fiber, And a second capillary that is connected to the second lens and directs light passing through the second lens to output to a first channel, wherein the first capillary comprises a first CWDM (coarse wavelength division multiplexing) package,
The first CWDM package has a structure identical to that of the first CWDM package, and is incident on the first optical fiber after being reflected by the CWDM filter of the first CWDM package. A second CWDM package that reflects and enters the second optical fiber and is oriented 180 degrees away from the first CWDM package,
And a module case enclosing the outside of the first CWDM package and the second CWDM package
Lt; / RTI >
And a plurality of first CWDM packages and a plurality of second CWDM packages alternately arranged in the module case, the light reflected from the first CWDM package or the second CWDM package Channel low-density wavelength division multiplexing module in which the end of the optical fiber is inclined at an angle of 82 degrees. The method of claim 1,
Wherein the CWDM filter of the first CWDM package or the CWDM filter of the second CWDM package filters light having passed through the first lens at different central wavelength bands. delete

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