KR101577204B1 - The function of the intergrated optical transceiver OSA - Google Patents

Abstract

The present invention relates to an optical transceiver-embedded optical sub-assemble (OSA) wherein an optical time domain reflectometer (OTDR) which monitors a condition of an optical communication line is integrated into an OSA which is an optical communication module to monitor a condition of an optical line in real time. An objective of the present invention is to provide an optical transceiver-embedded OSA capable of stabilizing the aligning of passive elements and optimizing operational characteristics. The optical transceiver-embedded OSA according to the present invention comprises: a first optical line to transmit a first light for monitoring to an optical fiber and to include a splitter unit for dividing and receiving a reflected light scattered backwards from the optical fiber to receive the reflected light scattered backwards from the optical fiber; a second optical line connected to one side of the first optical line and provided with a first filter which is arranged perpendicularly to the splitter unit in a direction of the first light, passes the first light therethrough to transfer the first light to the optical fiber, and reflects a second light containing a data signal transmitted to the optical fiber and a third light containing a data signal received from the optical fiber; and a third optical line connected to a lower portion of the second optical line and provided with a second filter which is arranged perpendicularly to the first filter, passes the second light therethrough to transfer the second light to the optical fiber, and reflects the third light containing the data signal received from the optical fiber to receive the third light received from the optical fiber.

Description

The optical transceiver embedded OSA (OSA)

More particularly, the present invention relates to an optical time domain reflectometer (OTDR) for monitoring the state of an optical communication line, and an optical subassembly (OSA) To optical transceiver embedded OS.

Optical fiber breakage, optical connector failure, fusion splicing point, fiber breakage, etc. on the optical path cause the transmission strength of the optical signal to be weakened, which makes smooth communication difficult. Therefore, it is very important to locate and repair the location of the anomalies on the details of the beam path.

An OTDR is an optical telecommunication instrument that can measure up to 250 km of optical communication links and is used to locate losses.

While light is transmitted through the optical fiber, a small amount of loss occurs due to Rayleigh scattering, and some photons scatter toward the light source, which is called backscatter. The intensity of the backscattering is determined by the input intensity, and the intensity of the reflected light becomes weaker after a long distance. The OTDR measures the intensity of backscattering that continues to be reflected. Within a few seconds, the total length and the loss of each part can be measured, and the length of the entire section and the section length of each contact can be measured.

Korean Patent Laid-Open Publication No. 10-2013-0030369 discloses a 10G PON optical transmission / reception sub-assembly including an OTDR function.

A 10G PON optical transceiver subassembly including an OTDR function is provided in a PON OLT diplexer (BIDI) optical transceiver including an OTDR function. The optical transceiver includes a first transmitter, an OTDR transmitter, an isolator, a first filter, a second filter, A capillary, a glass prism, and a light receiving unit.

Although the disclosed optical transceiver subassembly adds an OTDR to an optical module and manufactures it in one piece to monitor the optical path in real time, in the process of manufacturing an OSA package for alignment in an optical module, a precise holder is manufactured, Should be used later. As a result, since the passive elements are aligned, the reproducibility of the module is lowered and the alignment sensitivity is high.

Therefore, it is an object of the present invention to provide an optical transceiver built-in OS that can optimize the stability of alignment of each passive element and the operation characteristics thereof.

The optical transceiver built-in type OS according to the present invention includes a splitter for transmitting first light for monitoring by an optical fiber and dividing the reflected light back-scattered from the optical fiber and receiving the reflected light backscattered from the optical fiber, A first light path, connected to one side of the first light path, disposed perpendicularly to the first light in the direction of the first light, transmitting the first light, and transmitting the first light to the optical fiber, And a first filter that reflects a second light including a data signal transmitted to the optical fiber and a third light including a data signal received from the optical fiber, And is disposed perpendicular to the first filter and transmits the second light through the optical fiber And a second filter for reflecting the third light containing the data signal received from the optical fiber group comprises third gwangseonroeul for receiving the third light received from the optical fiber.

In the OS with built-in optical transceiver according to the present invention, the first filter is characterized by selectively transmitting or reflecting the wavelengths of the first light, the second light, the third light, and the reflected light .

In the OS with built-in optical transceiver according to the present invention, the second filter selectively transmits or reflects light directions of the second light and the third light.

A first transmitter for generating the first light and transmitting the first light to the optical fiber via the first optical line and the second optical line; a second transmitter located at an outer surface of the first optical line, A first lens that focuses the reflected light backscattered from the optical fiber by the first light transmitted from the first transmission unit to the optical fiber, and a first light receiving unit that receives the reflected light through the first lens .

The optical transceiver embedded OS of the present invention is characterized in that the first light and the second light incident on the outer surface of the second optical path are focused and transmitted to the optical fiber, And a second lens for focusing the incident third reflected light and the reflected light and transmitting the focused third reflected light to the second optical path.

A second transmitter for generating the second light and transmitting the second light to the optical fiber through the third optical line and the second optical line; A third lens for focusing the third light received from the optical fiber through the third optical line, and a second light receiving unit receiving the third light through the third lens.

In the OS with built-in optical transceiver according to the present invention, the first optical line, the second optical line, and the third optical line are integrated into a single case to form a single optical system.

A first optical line for transmitting the first light for monitoring by the optical fiber and having a splitter for dividing the reflected light backwardly scattered from the optical fiber and receiving the reflected light, And a third filter connected to an upper portion of the first optical path and arranged to be perpendicular to the splitter portion to reflect the first light and transmit the second light to the optical fiber and to transmit the second light including the data signal to the optical fiber A second light path connected to one side of the second light path and disposed perpendicular to the third filter in the direction of the second light and transmitting the first light, the second light, and the reflected light, And a fourth filter that reflects a third light including a received data signal, and transmits the first light and the second light to the optical fiber, Passing the reflected light to the second optical line group, and a third optical line receiving the third light.

The optical transceiver built-in type OS according to the present invention can reduce the misalignment occurring when aligning the respective elements for signal transmission by constituting the first optical line, the second optical line and the third optical line as a single optical system, So that the optical loss can be minimized.

1 is a perspective view illustrating an optical transceiver embedded OS according to an embodiment of the present invention.
FIG. 2 is a view illustrating an optical path of an optical transceiver built-in type ASE according to an embodiment of the present invention.
FIG. 3 is a diagram illustrating an optical path of the optical transceiver built-in type ASE according to the embodiment of the present invention.
4 is a perspective view showing the optical transceiver embedded OS according to another embodiment of the present invention.
5 is a view illustrating an optical path of a built-in optical transceiver according to another embodiment of the present invention.
FIG. 6 is a diagram illustrating an optical path to a built-in optical transceiver according to another embodiment of the present invention.

In the following description, only parts necessary for understanding the embodiments of the present invention will be described, and the description of other parts will be omitted so as not to obscure the gist of the present invention.

The terms and words used in the present specification and claims should not be construed as limited to ordinary or dictionary meanings and the inventor is not limited to the meaning of the terms in order to describe his invention in the best way. It should be interpreted as meaning and concept consistent with the technical idea of the present invention. Therefore, the embodiments described in the present specification and the configurations shown in the drawings are merely preferred embodiments of the present invention, and are not intended to represent all of the technical ideas of the present invention, so that various equivalents And variations are possible.

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

FIG. 1 is a perspective view of a built-in optical transceiver according to an embodiment of the present invention. FIG. 2 is a view showing the optical path of the optical transceiver embedded type ASE according to an embodiment of the present invention, and FIG. Fig. 2 is a diagram for analyzing the optical path of the optical transceiver built-in type ASE according to the example.

1 to 3, the optical transceiver embedded OS-A 100 according to the embodiment of the present invention includes a first optical line 10, a second optical line 20, and a third optical line 30 do.

The first optical path 10 conveys the first light to the optical fiber 1 and receives the backscattered reflected light from the optical fiber 1. Here, the first light may be near-infrared light as light for obtaining data on a damaged point of the monitoring section of the optical fiber 1. [

The first light path 10 includes a first transmitting section 11, a first lens 12, a first light receiving section 13, and a splitter section 14.

The first transmitter 11 generates the first light so that a signal is incident on the optical fiber 1 and emits the first light for acquiring data on a damaged point of the monitoring section. Here, the first transmitting unit may be positioned to face the optical fiber 1 such that the first light can be linearly incident on the optical fiber 1.

The first light emitted from the first transmission section 11 is incident on the splitter section 14. At this time, the splitter section 14 may divide a part of the first light and transmit it to the optical fiber 1.

Here, the splitter 14 may be a passive element for distributing a plurality of incident light beams. In the present embodiment, the splitter unit 14 may divide the reflected light back-scattered from the optical fiber 1 and transmit the split light to the first lens 12.

The splitter 14 may be arranged in a state of being inclined at 45 degrees with respect to the reflected light incident so that the reflected light backscattered from the optical fiber 1 in the form of a plate is vertically split and irradiated onto the first lens 12. [

On the other hand, the first lens 12 is located on the outer surface of the first optical path 10. That is, the first lens 12 can be installed in the direction in which the reflected light split by the splitter unit 14 is incident. The reflected light backscattered from the optical fiber 1 can be focused by the first light transmitted from the first transmitter 11 to the optical fiber 1 and transmitted to the first light receiver 13. The first lens 12 may be made of a transparent material such as glass, plastic, or the like, and has both side surfaces formed with convex surfaces.

The reflected light incident through the first lens 12 is incident on the first light receiving portion 13.

The first light receiving section 13 can diagnose the state of the optical fiber in the monitoring section through the received reflected light signal. Here, a photodiode may be used as the first light receiving portion 13. [

While the second light path 20 is connected to one side of the first light path 10. [ That is, the second optical line 20 is positioned between the first optical line 10 and the optical fiber 1 and transmits the first light incident from the first optical line 10 to the optical fiber 1, Scattered back from the first optical path 10 to the first optical path 10.

The second optical path 20 includes a first filter 21 and a second lens 22.

The first filter 21 transmits the first light incident from the first optical path 10 to the optical fiber 1 and the second light including the data signal transmitted from the third optical path 30 is reflected And transmits the third light including the data signal received from the optical fiber 1 to the third optical path 30. [

Here, the first filter 21 can selectively transmit or reflect the wavelengths of the first light, the second light, the third light, and the reflected light.

The first filter 21 reflects the second light in the form of a plate and vertically transmits the light to the optical fiber 1 or reflects the third light and transmits the second light and the third light perpendicularly to the third light path 30. [ As shown in FIG. That is, the first filter 21 may be vertically arranged in a state where one side of the first filter 21 is connected to the splitter 14 described above.

While the second lens 22 may be located on the outer surface of the second light path 20. [ That is, the second lens 22 can be installed in a direction in which the optical fiber 1 is located. The first light incident from the first light path 10 and reflected by the first filter 21 and the second light incident from the third light path 30 and reflected by the first filter 21 are focused And then transmitted to the optical fiber 1.

The second lens 22 can focus the third light including the data signal received from the optical fiber 1 and the reflected light backscattered from the optical fiber 1 and transmit the reflected light to the first filter 21. As the second lens 22, a lens formed of a transparent material such as glass, plastic or the like and having convex surfaces on both sides can be used.

On the other hand, the third optical path 30 is connected to the lower part of the second optical path 20, and transmits a second light including a data signal to the optical fiber 1, and a third light including a data signal received from the optical fiber .

The third light ray path 30 includes a second transmitting unit 31, a second filter 32, a third lens 33, and a second light receiving unit 34.

The second transmitter 31 generates a second light including a data signal and causes the second light to enter the second light path 20 so that the second light can be transmitted to the optical fiber 1.

The second light generated through the second transmission unit 31 is incident on the second filter 32.

The second filter 32 transmits the second light to the first filter 21 of the second light path 20 and the second light path 20 transmits the second light to the first filter 21 of the second light path 20. [ 3 light and transmits the light to the second light-receiving unit 34.

The second filter 32 may be disposed at an angle of 45 degrees with respect to the incident third light in order to reflect the third light transmitted from the first filter 21 and vertically transmit the light to the second light receiving unit 34 have. That is, the second filter 32 may be disposed vertically with one side connected to the first filter 21.

The second filter 32 can selectively transmit or reflect the light directions of the second light and the third light.

While the third lens 33 may be positioned on the outer surface of the third light path 30. [ That is, the third lens 33 may be positioned in the direction of the third light reflected by the second filter 32. The third lens 33 focuses the third light reflected through the second filter 32 and enters the second light receiving part 34. As the third lens 33, a lens formed of a transparent material such as glass, plastic or the like and having convex surfaces on both sides can be used.

The third light incident through the third lens 33 is incident on the second light receiving portion 34.

The second light receiving section 34 can receive the third light including the data signal received from the optical fiber 1 through the second lens 33. Here, a photodiode may be used as the second light receiving part 34. [

As described above, in the embodiment of the present invention, the respective elements provided in the first light path 10, the second light path 20 and the third light path 30 are integrated into a single case to form a single optical system.

Therefore, the optical transceiver embedded OS-A 100 according to the embodiment of the present invention can be configured so that the first optical line 10, the second optical line 20, and the third optical line 30 are constituted by a single optical system, The misalignment that occurs when aligning the respective elements for the light source can be reduced, thereby minimizing the optical loss.

Hereinafter, the optical transceiver embedded OSE 100 according to another embodiment of the present invention will be described.

FIG. 4 is a perspective view of a built-in optical transceiver according to another embodiment of the present invention, FIG. 5 is a view illustrating an optical path of a built-in optical transceiver according to another embodiment of the present invention, FIG. The optical path to the optical transceiver built-in type OS according to another embodiment of the present invention is analyzed.

Meanwhile, the optical transceiver built-in type ASE 200 according to another embodiment of the present invention has a configuration which is the same as that of the optical transceiver built-in type ASE 100 according to the embodiment of the present invention. Therefore, redundant description of the same configuration will be omitted, and the same names and the same reference numerals will be given to the same configurations.

4 to 6, the optical transceiver built-in type ASE 200 according to another embodiment of the present invention includes a first optical line 210, a second optical line 220, and a third optical line 230 .

The first optical path 210 transmits the first light to the optical fiber 1 and receives the backscattered reflected light from the optical fiber 1. [

The first light path 210 includes a first transmission unit 211, a first lens 212, a first light receiving unit 213, and a splitter unit 214.

The first transmitter 211 generates the first light so that a signal is incident on the optical fiber 1 and emits the first light for acquiring data on a damaged point of the monitoring section. Here, the first transmission unit 211 may allow the first light to be incident on the third filter 211 of the second optical path 220, which will be described later.

The first light emitted from the first transmission section 211 is incident on the splitter section 214. At this time, the splitter section 214 may divide a part of the first light and transmit it to the optical fiber 1.

Also, the splitter unit 14 may divide the reflected light backscattered from the optical fiber 1 and transmit the split light to the first lens 212.

The splitter 214 may be disposed at an angle of 45 degrees with respect to the reflected light incident on the first lens 212 so that the reflected light backscattered from the optical fiber 1 is vertically split.

Meanwhile, the first lens 212 may be positioned on the outer surface of the first light path 210. That is, the first lens 212 may be positioned in the direction of the reflected light divided by the splitter unit 214. [ The first lens 212 can focus the reflected light backscattered from the optical fiber 1 by the first light transmitted from the first transmission unit 211 to the optical fiber 1 and transmit the reflected light to the first light receiving unit 213. That is, the first lens 212 focuses the reflected light split from the splitter unit 214 and transmits the focused light to the first light receiving unit 213.

The reflected light incident through the first lens 212 is incident on the first light receiving section 213.

The first light receiving section 213 can diagnose the state of the optical fiber 1 in the monitoring section through the received reflected light signal.

While the second light path 220 is connected to the upper surface of the first light path 210. That is, the second light path 220 transmits the first light incident from the first light path 210 to the third light path 230 and the back light scattering from the optical fiber 1 through the third light path 230 And transmits the reflected light to the first light path 210.

The second light path 220 includes a second transmission unit 221 and a third filter 222.

The second transmitting unit 221 generates a second light including a data signal, and causes the second light generated toward the optical fiber 1 to enter. At this time, the second light passes through the third filter 222 and is transmitted to the optical fiber 1 through the third optical path 230.

The third filter 222 reflects the first light incident from the first light path 210 and transmits the first light to the third light path 230 and transmits the second light generated from the second transmission part 221 To the third light path (230). The third filter 222 receives the reflected light backscattered from the optical fiber 1 through the third optical path 230, reflects the reflected light, and transmits the reflected light to the first optical path 210.

Here, the third filter 222 can selectively transmit or reflect wavelengths of the first light, the second light, and the reflected light.

The third filter 222 reflects the first light in the form of a plate and vertically transmits the light to the optical fiber 1 or reflects the reflected light and transmits the first light and the second light to the first light path 210, As shown in FIG. That is, the third filter 222 may be disposed vertically with one side connected to the upper portion of the splitter 214 described above.

The third light path 230 is connected to one side of the second light path 220 and transmits the first light and the second light to the optical fiber 1 and transmits the reflected light to the second light path 220 And receives the third light including the data signal received from the optical fiber 1. [

The third light path 230 includes a fourth filter 231, a second lens 232, a second light receiving portion 233, and a third lens 234.

The fourth filter 231 transmits the first light and the second light transmitted from the second light path 220 and transmits the first light and the second light to the optical fiber 1. The fourth filter 231 transmits the reflected light received from the optical fiber 1, (220).

The fourth filter 231 reflects the third light including the data signal received from the optical fiber 1 and transmits the reflected third light to the second light receiving part 233.

The fourth filter 231 reflects the third light transmitted from the optical fiber 1 in a plate shape in a state where one side faces the third filter 222 in the direction of the second light and transmits the third light to the second light receiving part 34 And may be disposed at an angle of 45 degrees with respect to the third light incident for vertical transmission.

The fourth filter 231 may selectively transmit or reflect the wavelengths of the first light, the second light, the third light, and the reflected light.

While the second lens 232 may be located on the outer surface of the third light path 230. That is, the second lens 232 may be positioned in the direction of the third light reflected from the fourth filter 231. The second lens 232 focuses the third light reflected from the fourth filter 231 and transmits the third light to the second light receiving part 233.

The second light receiving section 233 can receive the third light including the data signal received from the optical fiber 1 through the second lens 232. Here, a photo diode may be used as the second light receiving portion 234.

While the third lens 235 may be positioned on the outer surface of the third light path 230. That is, the third lens 235 may be positioned in the optical fiber direction. The third lens 235 focuses the first light and the second light received from the fourth filter 231 and transmits the focused light to the optical fiber 1.

The third lens 235 focuses the third light and the reflected light incident from the optical fiber 1 and transmits the third light and the reflected light to the fourth filter 231.

As described above, according to another embodiment of the present invention, each element included in the first light path 210, the second light path 220 and the third light path 230 is integrated into a single case to form a single optical system .

Therefore, the optical transceiver embedded OS-A 200 according to another embodiment of the present invention may be configured such that the first optical line 210, the second optical line 220, and the third optical line 230 are constituted by a single optical system, It is possible to reduce the misalignment that occurs when aligning the respective elements for the light emitting element 100, thereby minimizing the optical loss.

It should be noted that the embodiments disclosed in the present specification and drawings are only illustrative of specific examples for the purpose of understanding, and are not intended to limit the scope of the present invention. It will be apparent to those skilled in the art that other modifications based on the technical idea of the present invention are possible in addition to the embodiments disclosed herein.

1: optical fiber 10, 210: first optical line
11, 211: first transmission unit 12, 212: first lens
13, 213: first light receiving section 14, 214: splitter section
20, 220: second light path 21: first filter
22, 232: second lens 30, 230: third light path
31, 221: second transmission unit 32: second filter
33, 235: third lens 34, 233: second light receiving portion
222: third filter 231: fourth filter
100, 200: optical transceiver built-in OSA

Claims (8)

A first light ray for transmitting the first light for monitoring to the optical fiber and a splitter for dividing and transmitting the reflected light backscattered from the optical fiber to receive the reflected light backscattered from the optical fiber;
And a second optical transmission line connected to one side of the first optical transmission line and disposed perpendicularly to the first optical splitter unit in a direction of the first optical transmission line and transmitting the first light to the optical fiber, transmitting the reflected light to the splitter unit, A second light ray having a first filter that reflects a second light including a data signal transmitted through an optical fiber, and a third light that includes a data signal received from the optical fiber;
A second filter connected to a lower portion of the second optical line and arranged to be perpendicular to the first filter and transmitting the second light to the optical fiber and reflecting a third light including a data signal received from the optical fiber, A third optical line for receiving third light received from the optical fiber;
And an optical transceiver built-in type OS-A. The method according to claim 1,
Wherein the first filter selectively transmits or reflects the wavelengths of the first light, the second light, the third light, and the reflected light. The method according to claim 1,
And the second filter selectively transmits or reflects the optical directions of the second light and the third light. The method according to claim 1,
A first transmitter for generating the first light and transmitting the first light to the optical fiber through the first optical line and the second optical line;
A first lens positioned on an outer surface of the first optical path and focusing the reflected light backscattered from the optical fiber by the first light transmitted from the first transmitting unit to the optical fiber;
A first light receiving unit receiving the reflected light through the first lens;
Further comprising an optical transceiver built-in. 5. The method of claim 4,
Focuses the first light and the second light incident from the second optical line and transmits the focused light to the optical fiber and focuses the third light and the reflected light incident from the optical fiber on the outer surface of the second optical line, A second lens for transmitting the light to the second optical line;
Further comprising an optical transceiver built-in. 6. The method of claim 5,
A second transmitter for generating the second light and transmitting the second light to the optical fiber through the third optical line and the second optical line;
A third lens positioned on an outer surface of the second optical path to focus third light received from the optical fiber through the third optical path;
A second light receiving unit receiving the third light through the third lens;
And an optical transceiver built-in type OS-A. The method according to claim 6,
Wherein the first optical line, the second optical line, and the third optical line are integrated into a single case and configured as a single optical system. A first light ray for transmitting the first light for monitoring to the optical fiber and a splitter for dividing the reflected light backwardly scattered from the optical fiber and receiving the reflected light;
A third filter connected to an upper portion of the first optical line and perpendicular to the splitter portion to reflect the first light and transmit the second light to the optical fiber and transmit the second light including the data signal to the optical fiber, A second light path provided;
And a second filter that is connected to one side of the second optical line and is disposed perpendicularly to the third filter in the direction of the second light and includes a data signal transmitted through the first light, And a fourth filter for reflecting the third light to transmit the first light and the second light to the optical fiber, to transmit the reflected light to the second optical line, and to transmit the third light, in;
And an optical transceiver built-in type OS-A.

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