KR102036248B1 - Optical communication system using main and sub optical line - Google Patents

Abstract

The present invention relates to an optical communication system including a main line and a secondary line, comprising: a first transmitting and receiving unit located in a first region; A second transmitter / receiver located in a second region; A first automatic switching unit connected to the first transmission / reception unit located in the first region; A second automatic switching unit connected to the second transmission / reception unit located in the second region; A main line and a sub-line which are located between the first automatic switching part and the second automatic switching part, and comprising an optical cable including an optical fiber; The first automatic switching unit and the second automatic switching unit, an input unit connected to the first transmitter and receiver and the second transmitter and receiver; The input portion is coupled to one coupling portion of the switch, the switch includes at least two other coupling portions, one of the two other coupling portions is connected to the main line connection, the other is connected to the sub-line connection The first transmitter / receiver and the second transmitter / receiver communicate with the main line, the switch is controlled by a controller, and when the controller cannot communicate with the main line, the controller controls the switch and the first transmitter / receiver. Characterized in that the communication of the second transmitting and receiving unit is changed from the main line to the sub-line.

Description

Optical communication system using main line and secondary line {OPTICAL COMMUNICATION SYSTEM USING MAIN AND SUB OPTICAL LINE}

The present invention relates to an optical communication system, and more particularly, to a system for optical communication using a main line and a secondary line.

With the recent rapid increase in traffic and the convergence of broadcasting and telecommunication services, the speed of subscriber networks has been increasing rapidly. Among the various technologies for this, the optical subscriber network is to build the subscriber network by the optical cable.

Optical subscriber networks are being built using optical communication systems, and most subscriber networks currently use optical communication systems.

On the other hand, cloud systems, streaming systems, banks, and the like, in which real-time data exchange is important, when a conventional optical communication system is used, if a problem occurs in an intermediate optical cable, data is lost and service cannot be performed. In such a case, a big problem occurs, and a system using a plurality of optical cables is used. In other words, if there is a problem in the main line by placing the main line and the sub-line, a system for switching the transmission line to the sub-line so that there is no problem in communication.

In an optical communication system using a plurality of transmission lines, it is an object of the present invention to accurately recognize a problem of a main line and to provide a function of changing a transmission line from a main line to a secondary line.

One purpose is to minimize the structure of the switching portion for switching.

One embodiment of an optical communication system including a main line and a secondary line as a means for solving the problems of the present invention includes a first transmitting and receiving unit located in the first region; A second transmitter / receiver located in a second region; A first automatic switching unit connected to the first transmission / reception unit located in the first region; A second automatic switching unit connected to the second transmission / reception unit located in the second region; A main line and a sub-line which are located between the first automatic switching part and the second automatic switching part, and comprising an optical cable including an optical fiber; The first automatic switching unit and the second automatic switching unit, an input unit connected to the first transmitter and receiver and the second transmitter and receiver; The input portion is coupled to one coupling portion of the switch, the switch includes at least two other coupling portions, one of the two other coupling portions is connected to the main line connection, the other is connected to the sub-line connection The first transmitter / receiver and the second transmitter / receiver communicate with the main line, the switch is controlled by a controller, and when the controller cannot communicate with the main line, the controller controls the switch and the first transmitter / receiver. Characterized in that the communication of the second transmitting and receiving unit is changed from the main line to the sub-line.

According to an embodiment, the first automatic switching unit and the second automatic switching unit may include a coupler, and determine whether the main line is incapable of communication by a monitoring photodiode connected to the coupler.

In one embodiment, the coupler portion is coupled to the sub-wire connection portion, characterized in that it further comprises a filter portion between the coupler portion and the monitoring photodiode.

The effect of the present invention has the advantage that can accurately determine the problem in the main line.

In addition, there is an advantage in that it is possible to accurately determine and change the communication line from the main line to the sub-line.

1 is a configuration diagram of an optical communication system of the present invention
2, 3 configuration diagram of the automatic switching part of the present invention

As the inventive concept allows for various changes and numerous embodiments, particular embodiments will be illustrated in the drawings and described in detail in the written description. However, this is not intended to limit the present invention to specific embodiments, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements.

Terms such as first, second, A, and B may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component. The term and / or includes a combination of a plurality of related items or any item of a plurality of related items.

When a component is referred to as being "connected" or "connected" to another component, it may be directly connected to or connected to that other component, but it may be understood that other components may be present in between. Should be. On the other hand, when a component is said to be "directly connected" or "directly connected" to another component, it should be understood that there is no other component in between.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. It is to be understood that terms such as "comprise" or "have" in the present application do not exclude in advance the existence or possibility of addition of features, numbers, steps, operations, components, parts or combinations thereof described in the specification. .

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art.

Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

Hereinafter, an optical communication system using a main line and a secondary line according to the present invention will be described in detail with reference to the accompanying drawings.

The optical communication system using the main line and the sub-line is configured as shown in FIG.

The optical communication system using the main line 10 and the sub-line 20 includes a first transmitter / receiver 100 located in a first region and a second transmitter / receiver 200 located in a second region.

The first transmitter / receiver 100 communicates with the second transmitter / receiver 200 using an optical cable including an optical fiber. The communication is performed using the main line 10, and includes a sub-line 20 that can replace the case of the main line 10 with almost any implementation stage.

In order to transmit / receive all in one optical fiber, the wavelength of the light source for the transmission of the first transmitter / receiver 100 is different from that for the reception.

When the first band, which is the wavelength band of the transmission light source of the first transmission and reception unit 100, and the wavelength band of the reception light source are the second band, the wavelength band of the transmission light source of the second transmission and reception unit 200 is the second band and the reception. The wavelength band of the light source may use the first band. That is, when the first transmitter / receiver 100 transmits data to the transmission light source of the first band, the second transmitter / receiver 200 receives the first band light source, and the second transmitter / receiver 200 receives the second band light source. When the data is transmitted by using the first transmitter / receiver 100, the first transmitter / receiver 100 receives the second band light source and receives the data.

If a problem occurs such that the main line 10 is disconnected in the optical communication system of this type, the communication line should be changed to the sub line 20. The configuration to enable such a change is the first automatic switching unit 300 and the second automatic switching unit 400.

The first transmitter / receiver is connected to the input unit 320 of the first automatic transfer part 300. The connection is characterized in that connected to one optical fiber.

The second transmitting and receiving unit is also connected to the input unit 420 of the second automatic switching unit 400, the connection is characterized in that connected to one optical fiber.

The first automatic switching unit 300 and the second automatic switching unit are connected to the main line 10 and the sub-line 20, respectively.

The first automatic transfer part 300 and the second automatic transfer part 400 are configured as follows.

The first automatic switching unit 300 and the second automatic switching unit 400 are connected to the first transmitting and receiving unit 100 and the second transmitting and receiving unit 200 through the input unit 320 and 420, respectively, the input unit 320, 420 is preferably an optical connector type such as SC, LC type.

The input units 320 and 420 are connected to the switches 310 and 410 using the first internal cables 311 and 411. The switches 310 and 410 have a form of 1 × 2, that is, one path on one side and two paths on the other side, and one path on one side selects one of two paths on the other side. . The operating wavelength range of the switches 310 and 410 is characterized in that it can accommodate both the first band and the second band.

The first light transmitting / receiving unit 100 and the second light transmitting / receiving unit 200 are coupled to one side of the switches 310 and 410 by the first internal cables 311 and 411, and the other side of the switch is coupled. One of the two paths is coupled to the main line connecting portions 340 and 440 to which the main line 10 is connected. In addition, the other one of the two paths is connected to the sub-line connecting portion 330, 430 to which the sub-line 20 is connected.

The switches 310 and 410 and the sub wire connection parts 330 and 430 are connected by the second internal cables 312 and 412, and are directly connected without a separate optical device in the middle.

The switches 310 and 410 and the main line connection parts 340 and 440 are connected by the third internal cables 313 and 413, and include a configuration capable of sensing a state of the main line 10 in the middle.

The sensing can be configured in a variety of forms, but to simplify the structure, the present invention proposes the configuration as follows.

The third internal cables 313 and 413 are connected to the coupler parts 370 and 470, and the coupler parts 370 and 470 have a form of 2 × 1 and include two paths on one side and one path on the other side. One path of the other side is connected to the main line connection parts 340 and 440, one of two paths of one side is connected to the third internal cable 313 and 413, and the other is connected to the filter unit 360 and 460. Is connected through is connected to the monitoring photodiode (350, 450). The two paths on one side are characterized in that the ratio of power distribution is higher than the other path to which the third internal cable is connected, and the power is preferably distributed at 9: 1 or 95: 5.

The monitoring photodiodes 350 and 450 measure the intensity of the light source received by the first transmitter / receiver 100 and the second transmitter / receiver 200. That is, the monitoring photodiode 350 inside the first automatic switching unit 300 measures the intensity of the light source of the second band, and the monitoring photodiode 450 inside the second automatic switching unit 400 is the first band. It is characterized by measuring the intensity of the light source.

The monitoring photodiodes 350 and 450 are connected to the control units 380 and 480, and when a predetermined power is not received, the control unit determines that the main line 10 is cut and changes the communication line to the sub line 20. do. The change of the communication line may change the path of the switches 310 and 410, and the control of the change may provide a predetermined voltage to the switch.

Even if there are no filter units 360 and 460, the above functions may be theoretically performed. However, in the actual environment, the cutting of the main line 10 may take various forms, and in many cases, the light source to be transmitted is reflected from the cutting surface to enter the monitoring photodiode. Then, even though the cutting is performed, since the monitoring photodiode continuously measures a predetermined power, the control unit recognizes that the cutting is not performed even though the main line 10 is cut. Therefore, the filter units 360 and 460 have a wavelength characteristic of blocking the light source of the band to be transmitted and passing only the light source of the band to be transmitted. That is, the filter unit of the first automatic switching unit connected to the first transmitting and receiving unit blocks the first band, passes only the second band, the filter unit of the second automatic switching unit passes the first band, and blocks the second band. When configured in this way, there is an advantage that can be prevented at the source of the reflection of the transmission light source from the cutting surface of the main line (10).

In the present invention, there is an advantage that can be easily applied to a system using different wavelength bands as one optical fiber for transmission and reception. In addition, the automatic switching machine can be configured at low cost without using a separate optical isolator or optical circulator, and the process of selectively monitoring using only the filter unit, and the structure composed of only optical elements has a fast response speed. It has an advantage to have.

When the main line 10 has a problem, the time to change to the sub-line 20 is preferably 50 ms or less. The reason for this is that data loss occurs when 50 ms or more, and for such a fast time response, it is preferable to analyze the characteristics using only an optical device as in the present invention.

Although the present invention has been described by specific embodiments such as specific components and the like, but the embodiments and the drawings are provided to assist in a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations can be made from these descriptions.

Therefore, the spirit of the present invention should not be limited to the embodiments described above, and all of the equivalents or equivalents of the claims, as well as the following claims, are included in the scope of the spirit of the present invention. I will say.

10 main lines
20 barges
100 First Transmitter and Receiver
200 Second Transmitter and Receiver
300 1st automatic transfer part
400 2nd automatic transfer part
110 First Optical Cable
210 Second Optical Cable
310, 410 switch
320, 420 inputs
330, 430 barge connection
340, 440 main line connections
350, 450 Monitoring Photodiode
360, 460 filter part
370, 470 Coupler Part
380, 480 controls

Claims (3)

In the optical communication system including a main line and a secondary line,
A first transmitter / receiver, positioned in a first region, using a transmission light source having a wavelength of a first band and receiving light of a wavelength of a second band;
A second transmitter / receiver, located in a second region, using a transmission light source having a wavelength of a second band, and receiving light of a wavelength of a first band;
A first automatic switching unit connected to the first transmission / reception unit located in the first region;
A second automatic switching unit connected to the second transmission / reception unit located in the second region;
The first automatic transfer part and the second automatic transfer part is located between, and includes a main line and a sub-line consisting of an optical cable including an optical fiber,
The first automatic transfer part,
An input unit connected to the first transmitter / receiver;
A switch coupled to one side of the input unit and including two other coupling parts connected to a main line connection part and a sub-line connection part;
A coupler part disposed between the other side coupling part and the sub-line connection part and to which a monitoring photodiode is connected;
A filter unit positioned between the coupler unit and the monitoring photodiode and blocking light of a first band and passing light of a second band;
A control unit for controlling the switch;
The second automatic transfer part,
An input unit connected to the second transmitter / receiver;
A switch coupled to one side of the input unit and including two other coupling parts connected to a main line connection part and a sub-line connection part;
A coupler part disposed between the other side coupling part and the sub-line connection part and to which a monitoring photodiode is connected;
A filter unit positioned between the coupler unit and the monitoring photodiode and blocking light of a second band and passing light of a first band;
It includes a control unit for controlling the switch,
If a predetermined light is not received by the monitoring photodiode of the first automatic switching unit and the monitoring photodiode of the second automatic switching unit, the controller controls a switch to arrange communication between the first transmitting and receiving unit and the second transmitting and receiving unit. Optical communication system, characterized in that for changing to the bar. delete delete

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