KR20190071901A - 5G optical repeater system and method for compensating propagation delay time - Google Patents

Abstract

Disclosed are an optical relay system compensating for propagation delay time and a method thereof. The optical relay system includes: a plurality of remote units (RUs), which are configured to perform communication with a user terminal and are formed in a cascade structure or a parallel structure; a master unit (MU) performing communication between the plurality of remote units and a base station, and amplifying a signal; and an optical delay control device performing communication between the plurality of remote units and the master unit, calculating the propagation delay time caused by a multipath, and compensating for the calculated propagation delay time by a change in the length of an optical cable.

Description

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a 5 G optical repeater system and a method for compensating propagation delay time,

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical relaying technique, and more particularly, to a 5G optical relaying system and method for compensating a propagation delay for the entire wavelength of an optical signal by compensating a propagation delay time by a change in length of an optical cable.

Generally, in a mobile communication system, an optical repeater is used to solve the propagation shading in a radio-shaded area where radio waves generally are difficult to reach such as underground, inside of buildings, tunnels and the like. It is transmitted to a radio wave shadow area through an optical transmission system using an optical repeater, thereby solving the problem of radio wave shading.

On the other hand, the base station output signal is transmitted to each terminal through a master unit (MU) and N remote units (RU), which are optical repeaters, radiating in a white signal period from the base station. The remote unit can be connected to the master unit with optical cables of different lengths depending on the installation distance of each remote unit. Thus, the N remote units connected to the master unit have different transmission delay times according to the optical cable length, and quality deterioration may occur between the user terminals transmitting and receiving with the base station through different remote units.

Korean Patent Registration No. 10-1048960 (Jul. 2011)

SUMMARY OF THE INVENTION It is an object of the present invention to provide a 5 G optical relay system and a method for compensating a propagation delay time for compensating a propagation delay time caused by a multipath to achieve smooth communication.

In order to achieve the above object, a 5G optical repeater system for compensating for propagation delay time according to the present invention comprises a plurality of remote units, each having a cascade structure or a parallel structure, A master unit (MU) for performing communication between the plurality of remote units and the base station, for amplifying signals, and for performing communication between the plurality of remote units and the master unit, And compensates the calculated propagation delay time by the change in length of the optical cable.

The optical delay control device may further include a cable member having a plurality of optical cables having different lengths, and a plurality of optical cables provided between the plurality of optical cables and connected to at least one of the plurality of optical cables through on / off And a first controller for calculating a plurality of optical switches and the propagation delay time and controlling an optical switch connected to an optical cable having a delay time equal to the calculated compensation time for the propagation delay time.

The first control unit may control the plurality of optical switches connected to the optical cable to close when the compensation time is equal to a delay time generated by connecting a plurality of the plurality of optical cables.

The optical delay control apparatus may further include a cable member having a plurality of optical cables having different lengths, a plurality of optical connectors provided between the plurality of optical cables, coupled to at least one of the plurality of optical cables, And detects an optical connector corresponding to an optical cable having a delay time equal to the calculated compensation time for the radio wave transmission delay time, and the detected optical connector and the optical cable having the same delay time as the compensation time are combined And a second control unit for controlling the second control unit.

And the cable member includes at least one bundle of optical cables of 50m, 100m, 200m, 400m, 800m and 1600m.

An optical relaying method according to the present invention is a method for relaying an optical signal, comprising: a plurality of remote units communicating with a user terminal and formed in a cascade structure or a parallel structure; a master unit performing communication between the plurality of remote units and the base station; And an optical delay control device for performing communication between the remote unit and the master unit, the optical delay control method comprising the steps of: calculating the propagation delay time of the optical delay control device by multipath; And the optical delay control device compensating the calculated propagation delay time by a change in length of the optical cable.

The 5G optical repeater system and method for compensating the propagation delay time according to the present invention can compensate for the propagation delay time by using a plurality of optical cables having different lengths to enable smooth communication.

1 is a view for explaining a 5G optical repeater system according to an embodiment of the present invention.
2 is a view for explaining an optical delay control apparatus according to a first embodiment of the present invention.
3 is a view for explaining an optical delay control apparatus according to a second embodiment of the present invention.
4 is a diagram for explaining a 5G optical repeating method according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings. In the drawings, the same reference numerals as used in the appended drawings denote like elements, unless indicated otherwise. In the following description of the present invention, a detailed description of known functions and configurations incorporated herein will be omitted when it may make the subject matter of the present invention rather obvious or understandable to those skilled in the art.

1 is a view for explaining a 5G optical repeater system according to an embodiment of the present invention.

Referring to FIG. 1, the 5G optical repeater 100 compensates for the propagation delay time caused by the multipath to allow smooth communication. Here, the 5G optical repeater can perform 5G communication. 5G optical repeater system 100 includes a remote unit (RU) 10, a master unit (MU) 20 and an optical delay control device 30, and includes a base station 40 and a user terminal (Not shown).

The remote unit 10 performs communication with the user terminal. The remote unit 10 is formed in a cascade structure or a parallel structure. Therefore, the remote unit 10 is composed of a plurality of units. For example, the remote unit 10 includes the first remote unit 11, the second remote unit 12, the third remote unit 13 to the nth remote unit (n is a natural number of 2 or more) 14 do.

When receiving the optical signal from the master unit 20, the remote unit 10 converts it into an RF signal through photoelectric conversion, and transmits the RF signal to the user terminal via the antenna. The remote unit 10 converts an RF (radio frequency) signal received from a user terminal into an optical signal through an all-optical conversion, and transmits the optical signal to the master unit 20 through an optical cable.

The master unit 20 performs communication between the remote unit 10 and the base station 40. At this time, the master unit 20 serves to amplify the signal. The master unit 20 is connected to the base station 40 via an RF cable.

When receiving the RF signal from the base station 40, the master unit 20 converts the RF signal into an optical signal through the electro-optical conversion, and transmits the optical signal to the remote unit 10 through the optical cable. The master unit 20 converts the optical signal transmitted from the remote unit 10 to a RF signal through photoelectric conversion, and transmits the RF signal to the base station 40 via the RF cable.

On the other hand, radio propagation delay time is generated by multipath while communicating between the remote unit 10, the master unit 20, the base station 40 and the user terminal.

The optical delay control device 30 compensates for the above-mentioned radio wave transmission delay time to control the communication to be smooth. Here, the optical delay control device 30 can compensate the propagation delay time for the entire optical wavelength, not the limited wavelength. The optical delay control device 30 is disposed between the remote unit 10 and the master unit 20.

The optical delay control device 30 calculates the propagation delay time of the RF signal or the optical signal, and compensates the calculated propagation delay time by the length of the optical cable. That is, the optical delay control device 30 uses the fact that the delay time differs depending on the length of the optical cable. The optical delay control device 30 can compensate for time from several hundred nanoseconds to several hundreds of microseconds.

Here, the optical delay control device 30 can compensate the radio wave transmission delay time by changing the length of the optical cable by the external control by the remote unit 10 and the master unit 20. [

Hereinafter, a process of transmitting signals in the forward and reverse channels using the components of the optical repeater system 100 will be described.

In the forward channel, the RF signal transmitted through the RF cable at the base station 40 is transmitted to the master unit 20. The transmitted RF signal is removed by the master unit 20, amplified, and then converted into an optical signal from the RF signal. The converted optical signal is transmitted to the optical delay control device 30 through the optical cable. The propagation delay time is compensated by the optical delay controller 30 for the transmitted optical signal. The optical signal with the propagation delay time compensated is transmitted to the remote unit 10 through the optical cable. The transmitted optical signal is spectrally converted by the remote unit 10, converted into an RF signal from the optical signal, amplified to an effective output for wirelessly transmitting the converted RF signal, and then transmitted to the user terminal.

In the case of the reverse channel, when the RF signal is received from the user terminal through the antenna of the remote unit 10, the transmitted RF signal is removed from the noise, the signal component is amplified, The converted optical signal is transmitted to the optical delay control device 30 through the optical cable. The optical transmission delay time is compensated by the optical delay control device 30 for the transmitted optical signal. The optical signal with the propagation delay time compensated is transmitted to the master unit 20 through the optical cable. The transmitted optical signal is photoelectrically converted by the master unit 20, converted into an RF signal from the optical signal, amplified to an effective output for transmitting the converted RF signal to the base station 40, and then transmitted to the base station 40 do.

2 is a view for explaining an optical delay control apparatus according to a first embodiment of the present invention.

1 and 2, the optical delay control apparatus 30 includes a cable member 31, an optical switch 32, and a first control unit 33, and further includes a communication unit 34. [

The cable member 31 has a plurality of optical cables having different lengths. That is, the cable members 31 include bundles of optical cables having different lengths from each other. For example, the cable member 31 includes at least one bundle of optical cables 50m, 100m, 200m, 400m, 800m and 1600m. Here, the longer the optical cable is, the longer the delay time becomes. The delay time of the optical cable may be several hundred nanoseconds (~) to hundreds of microseconds (mu s). The cable member 31 may also include ordinary light rays.

The optical switch 32 is provided between a plurality of optical cables. The optical switch 32 is connected to at least one of the plurality of optical cables through on / off. That is, the optical switch 32 is inserted between a plurality of optical cables to switch the optical path.

The first control unit 33 calculates the propagation delay time of the transmitted signal. The first controller 33 compares the predetermined radio wave transmission time with the radio wave transmission time of the actually transmitted signal to calculate the radio wave transmission delay time. Here, the predetermined radio wave transmission time means a radio wave transmission time when the radio wave transmission delay time does not occur. The first control unit 33 controls the optical switch 32 connected to the optical cable having the same delay time as the calculated compensation time for the radio wave transmission delay time. The first control unit 33 controls the plurality of optical switches connected to the optical cable to close when the compensation time is equal to the delay time generated by connecting a plurality of optical cables. For example, when the compensation time is 100 μs, the first controller 33 controls the optical switch corresponding to the 200 m optical cable having the delay time of 20 μs and the 800 m optical cable having the delay time of 80 μs to be closed, Mu s.

On the other hand, the first control unit 33 can control the on / off state of the optical switch 32 according to the user input received from the communication unit 34. [ Thus, the manager can control the on / off of the optical switch 32 remotely from the outside.

The communication unit 34 performs communication with an external administrator terminal (not shown). The communication unit 34 receives a user input from the administrator terminal. The communication unit 34 also receives user inputs from the remote unit 10 and the master unit 20. Here, the user input may be a control signal for on / off of the optical switch 32. [

Therefore, the optical delay control apparatus 30 according to the first embodiment not only compensates the radio wave transmission delay time automatically but also transmits the radio wave propagation delay time through at least one of the manager terminal, the remote unit 10 and the master unit 20 Lt; / RTI > can be controlled.

3 is a view for explaining an optical delay control apparatus according to a second embodiment of the present invention.

1 and 3, the optical delay control apparatus 30 includes a cable member 31, an optical connector 35, a second control unit 36, and an output unit 37. Here, the cable member 31 has the same structure as that of the first embodiment, and a description thereof will be omitted.

The optical connector 35 is provided between a plurality of optical cables. The optical connector 35 is coupled to at least one of the plurality of optical cables. That is, the optical connector 35 is inserted between a plurality of optical cables to switch the optical path. At this time, the optical connector 35 is directly coupled to the optical cable by the user.

The second control unit 36 calculates the propagation delay time of the transmitted signal. The second controller 36 compares the predetermined radio wave transmission time with the radio wave transmission time of the actually transmitted signal to calculate the radio wave transmission delay time. Here, the predetermined radio wave transmission time means a radio wave transmission time when the radio wave transmission delay time does not occur. The second controller 36 detects the optical connector corresponding to the optical cable having the same delay time as the calculated time for the calculated propagation delay time. The second controller 36 controls the optical connector to be coupled with the optical connector having the delay time equal to the compensation time with the detected optical connector. That is, the second control unit 36 controls the output unit 37 to display the optical cable and the detected optical connector having the same delay time as the compensation time, so that the manager can directly couple the optical cable and the optical connector. The second controller 36 controls the plurality of optical connectors corresponding to the optical cable to be coupled when the compensation time is equal to the delay time generated by connecting a plurality of optical cables.

The output unit 37 indicates the optical cable and the optical connector to be combined to compensate for the propagation delay time. At this time, the output unit 37 is not limited to the screen display but can output the optical cable and the optical connector through sound.

Therefore, unlike the first embodiment, the optical delay control apparatus 30 according to the second embodiment requires the direct manager to combine the optical fiber and the optical connector but does not use the optical switch, thereby reducing the cost and the loss ) Can be prevented in advance.

4 is a diagram for explaining a 5G optical repeating method according to an embodiment of the present invention.

Referring to FIGS. 1 and 4, the 5G optical repeating method compensates for the propagation delay time by using a plurality of optical cables having different lengths, so that smooth 5G communication can be achieved.

In step S110, the optical delay control apparatus 100 calculates the propagation delay time caused by the multipath. The optical delay control apparatus 100 calculates the radio wave transmission delay time generated while communicating between the remote unit 10, the master unit 20, the base station 40 and the user terminal. The optical delay control apparatus 100 compares the predetermined radio wave transmission time with the radio wave transmission time of the actually transmitted signal to calculate the radio wave transmission delay time. Here, the predetermined radio wave transmission time means a radio wave transmission time when the radio wave transmission delay time does not occur.

In step S120, the optical delay control apparatus 100 compensates the calculated propagation delay time by the change in length of the optical cable. The optical delay control apparatus 100 can adjust the length of the optical cable through an optical switch or an optical connector.

When the optical delay control apparatus 100 uses an optical switch, the optical delay control apparatus 100 controls the optical switch connected to the optical cable having the same delay time as the calculated time for the calculated propagation delay time, Time is compensated. In this case, when the compensation time is equal to the delay time generated by connecting a plurality of optical cables, the optical delay control apparatus 100 controls the plurality of optical switches connected to the optical cable to be closed.

When the optical delay control apparatus 100 uses an optical connector, the optical delay control apparatus 100 detects an optical connector corresponding to an optical cable having a delay time equal to the compensation time for the calculated radio wave transmission delay time. The optical delay control apparatus 100 notifies the manager of the detected optical connector and the detected optical connector so that the detected optical connector and the optical cable having the same delay time as the compensation time are coupled. This allows the administrator to combine the optical fiber and the optical connector directly. When the compensation time is equal to the delay time generated by connecting a plurality of optical cables, the optical delay control apparatus 100 notifies the manager that a plurality of optical connectors corresponding to the optical cable are coupled.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is clearly understood that the same is by way of illustration and example only and is not to be taken by way of limitation in the embodiment in which said invention is directed. It will be understood by those skilled in the art that various changes in form and detail may be made therein without departing from the scope of the appended claims.

10: Remote unit
11: First remote unit
12: Second remote unit
13: Third remote unit
14: n remote unit
20: Master unit
30: optical delay control device
31: Cable member
32: Optical switch
33:
34:
35: Optical connector
36:
37: Output section
40: base station
100: 5G Optical Relay System

Claims (6)

A plurality of remote units (RUs) communicating with the user terminals and formed in a cascade structure or a parallel structure;
A master unit (MU) for performing communication between the plurality of remote units and the base stations and amplifying the signals; And
An optical delay control device for performing communication between the plurality of remote units and the master unit, calculating an electric wave transmission delay time generated by the multipath, and compensating the calculated electric wave transmission delay time by a change in length of the optical cable, ;
To compensate for the propagation delay time. The method according to claim 1,
The optical delay control apparatus includes:
A cable member having a plurality of optical cables having different lengths;
A plurality of optical switches provided between the plurality of optical cables and connected to at least one of the plurality of optical cables through on / off; And
A first control unit for calculating the radio wave transmission delay time and controlling an optical switch connected to an optical cable having a delay time equal to the calculated radio wave transmission delay time;
And a second optical repeater for compensating for the propagation delay time. 3. The method of claim 2,
Wherein the first control unit includes:
And controls the plurality of optical switches connected to the optical cable to be closed when the compensation time is equal to a delay time generated by connecting a plurality of the plurality of optical cables. The method according to claim 1,
The optical delay control apparatus includes:
A cable member having a plurality of optical cables having different lengths;
A plurality of optical connectors provided between the plurality of optical cables and coupled with at least one of the plurality of optical cables; And
Wherein the controller detects the optical connector corresponding to the optical cable having the same delay time as the compensation time for the calculated radio wave transmission delay time and calculates the delay time equal to the compensation time A second control unit for controlling the optical fibers to be coupled;
And a second optical repeater for compensating for the propagation delay time. The method according to claim 2 or 4,
The cable member includes:
50m, 100m, 200m, 400m, 800m and 1600m. The 5G optical repeater system compensates for the propagation delay time. A plurality of remote units communicating with a user terminal and formed in a cascade structure or a parallel structure, a master unit performing communication between the plurality of remote units and the base stations, and a plurality of remote units communicating with each other between the plurality of remote units and the master unit In an optical repeating method using an optical repeater system including an optical delay control apparatus for performing communication with a base station,
Calculating the propagation delay time of the optical delay control device by multipath; And
Compensating the calculated propagation delay time by a change in length of the optical cable;
Gt; 5G < / RTI >

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