KR101248107B1 - optic repeater system - Google Patents

Abstract

The present invention relates to an optical repeater system for relaying an optical signal between a donor unit and a remote unit, wherein the optical repeater system is separated from each other between a first connection end of the donor unit and a second connection end of the remote unit to transmit an integrated optical signal. A first optical switch for selectively connecting one of the first and second optical paths provided, one end of the first optical path and one end of the second optical path according to the control signal with the first connection end of the donor unit, and the first optical switch according to the control signal. A second optical switch for selectively connecting any one of the other end of the first optical path and the other end of the second optical path with the second connection end of the remote unit, and a part of the light that is installed between the first connection end and the first optical switch and transmitted; A first optical splitter for branching through the first branch path, a second optical splitter for branching a portion of the light transmitted between the second connection end and the second optical switch through the second branch path, First and second photodetectors for detecting the light received through the crossroads and the second branch, respectively, and if the amount of light received from the first photodetector and the second photodetector is determined to be below the set reference level, it is determined that the optical path failure And a control unit for controlling the first optical switch and the second optical switch to switch the connection of the first optical path and the second optical path to the optical path which is not currently connected. According to the optical repeater system, when a failure occurs in any one of the plurality of optical paths provided between the donor unit and the remote unit, the connection can be automatically switched to the other optical path, thereby providing an advantage of reducing communication failure.

Description

Optical repeater system

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an optical repeater system of a mobile communication network, and more particularly, to an optical repeater system capable of switching an optical path according to a link state between a donor unit and a remote unit.

In general, various mobile communication systems including mobile phones and personal mobile communication are largely comprised of a mobile switching center, a base station transceiver subsystem, a mobile station, and each base station is mobile. It has a constant cell coverage based on radio wave strength and call quality received by the communication terminal.

Therefore, when designing a network, a predetermined area is appropriately arranged and constructed to cover a predetermined area with a plurality of base stations based on such a call radius. However, due to the propagation characteristics, a shaded area where communication is impossible due to a decrease in the strength and quality of radio waves. Many of these will occur.

Repeater (repeater) is a device for eliminating the shadow area, is a transmission medium that receives a signal from the base station and transmits to the mobile communication terminal.

In the case of an in-building repeater, the donor unit (DU), which is a master device, and the remote unit (RU), which is a remote inter-device, are connected to each other by wire. Transmission lines for connecting the donor unit and the remote unit are used in various ways such as optical / coaxial / UTP.The optical cable can transmit up to several tens of Km. On the other hand, the transmission distance of coaxial cable is much shorter than that of light, but it is mainly used for low power equipment because of low maintenance cost and low equipment cost.

At this time, if the connection (link) between the DU and the RU is completely disconnected, a communication failure occurs, and when a line failure occurs, there is a problem that the communication failure cannot be recovered during the repair process.

The present invention was devised to improve the above problems, and when the optical communication line failure between the donor unit and the remote unit occurs, to provide an optical repeater system which can automatically prevent the communication failure by switching to the bypass optical communication line. have.

In order to achieve the above object, an optical repeater system according to the present invention includes a donor unit for outputting an integrated optical signal incorporating different mutually received communication service signals through a first connection terminal, and a second connection outputted to the donor unit. An optical repeater system having a remote unit which separates the integrated optical signal received through a terminal according to a communication service type and transmits the integrated optical signal to a subscriber terminal, wherein the integrated optical signal is connected to the first connection terminal of the donor unit to transmit the integrated optical signal. A first optical path provided between said second connection end of said remote unit; A second optical path provided separately from the first optical path between the first connection end of the donor unit and the second connection end of the remote unit to transmit the integrated optical signal; A first optical switch for selectively connecting either one end of the first optical path or one end of the second optical path to the first connection end of the donor unit according to a control signal; A second optical switch for selectively connecting one of the other end of the first optical path and the other end of the second optical path with the second connection end of the remote unit in accordance with a control signal; A first optical splitter provided between the first connection terminal and the first optical switch to branch a part of the light transmitted through the first branch path; A second optical splitter configured to branch a portion of the light transmitted between the second connection terminal and the second optical switch through a second branch path; A first photodetector for detecting light received through the first branch path; A second photodetector for detecting light received through the second branch path; If it is determined that the amount of light received from the first photodetector and the second photodetector is less than or equal to a set reference level, it is determined that the optical path has failed, and connection between the first optical path and the second optical path is currently unconnected. And a control unit controlling the first optical switch and the second optical switch to be switched.

Preferably, an automatic mode for automatically adjusting the first optical path and the second optical path by the controller and a mode selection key for selecting a manual mode selectable by a user's operation, and the first mode in the manual mode. And an operation unit provided with an operation key for selecting one of the optical path and the second optical path by a user's operation, wherein the control unit selects the manual mode from the operation unit and the optical key by the operation key. When the low selection signal is received, the first and second optical switches are controlled such that the line selected by the operation unit is connected between the donor unit and the remote unit irrespective of the information received from the first and second photodetectors. do.

The display apparatus may further include a display unit controlled by the controller to display line state information currently connected between the donor unit and the remote unit.

According to the optical repeater system according to the present invention, when a failure occurs in any one of the plurality of optical paths provided between the donor unit and the remote unit, the connection can be automatically switched to the remaining optical paths, thereby providing an advantage of reducing communication failure. do.

1 is a view schematically showing a mobile communication network to which the optical repeater system according to the present invention is applied,
FIG. 2 is a block diagram illustrating in detail the light path switching unit provided between the donor unit and the remote unit of FIG. 1.

Hereinafter, an optical repeater system according to a preferred embodiment of the present invention with reference to the accompanying drawings will be described in more detail.

FIG. 1 is a view schematically illustrating a mobile communication network to which an optical repeater system according to the present invention is applied, and FIG. 2 is a block diagram illustrating a light path switching unit installed between the donor unit and the remote unit of FIG. 1 in detail.

1 and 2, the optical repeater system 100 may include a donor unit 110, a remote unit 130, and a light beam switching unit 150. Equipped.

The donor unit 110 outputs an integrated optical signal incorporating different communication service signals received from the base station 10 through one first connection terminal 112, and the first connection terminal from the remote unit 130. The signal received through 112 is separated for each communication service type and transmitted to the base station 10.

In the illustrated example, the donor unit 110 communicates with the WCDMA1 with a center frequency of up to 1570 nm / down 1510 nm, the WCDMA2 with a center frequency of uplink 1530 nm / down 1470 nm, the LTE with a center frequency of uplink 1490 nm / downward 1350 nm, and a center. An example of a structure in which an integrated optical signal is generated and output through a first access terminal for different communication service signals of Wibros having a frequency of uplink 1550nm / downlink 1310nm is illustrated.

When the donor unit 110 wirelessly communicates with the base station 10, the received RF signal is integrated and converted into an optical signal, integrated, transmitted through the first access terminal 112, and the first access terminal. The integrated optical signal received in the reverse direction through the 112 is constructed to be separated by the communication service type and then converted to the RF signal to be transmitted to the base station 10, the structure of such a donor unit 110 is well known and detailed description thereof is omitted. do.

The remote unit 130 separates the integrated optical signal received from the donor unit 110 into different communication service signals, converts the integrated optical signal into RF signals, and transmits the signal to the subscriber terminal 200, for example, a mobile phone.

In addition, the remote unit 130 integrates mutually different communication service signals received from the subscriber terminal 200 and converts the integrated optical signal converted into an optical signal through the door unit 110 through one second connection end 132. To send.

The light path switching unit 150 is configured to selectively connect any one of a plurality of first and second light paths provided between the door unit 110 and the remote unit 130.

The optical path switching unit 150 includes a first optical path 151, a second optical path 152, a first optical switch 161, a second optical switch 162, a first optical splitter 165, and a second optical path 151. An optical splitter 166, a first photodetector 171, a second photodetector 172, a control unit 181, an operation unit 183, and a display unit 185 are provided.

The first optical path 151 is selectively connected between the first optical switch 161 and the second optical switch 162 and the first connection end 112 of the donor unit 110 to transmit the integrated optical signal. It is provided between the 2nd connection terminal 132 of the remote unit 130. As shown in FIG.

The second optical path 152 is selectively connected between the first optical switch 161 and the second optical switch 162 and the first connection end 112 of the donor unit 110 to transmit an integrated optical signal. The first optical path 151 is separated from the second connection terminal 132 of the remote unit 130.

The first optical switch 161 connects the first terminal 161a connected to the first optical splitter 165 to one end of the first optical path 151 according to the control signal of the control unit 181. 161b and the third terminal 161c connected to one end of the second optical path 152 can be selectively connected.

The second optical switch 162 connects the fourth terminal 162a connected to the second optical splitter 166 to the other end of the first optical path 151 according to the control signal of the controller 181. 161b and the sixth terminal 162c connected to the other end of the second optical path 152 can be selectively connected.

The first optical splitter 165 is installed between the first connection end 112 and the first optical switch 161 and is disposed between the first connection end 112 and the first terminal 161a of the first optical switch 161. A portion of the light transmitted through the main transmission path of the branched through the first branch path (165a).

Preferably, the first optical splitter 165 receives about 2 to 10% of the light transmitted between the first connection terminal 112 and the first terminal 161a of the first optical switch 161 to the first branch 165a. What can be branched through applies.

The second optical splitter 166 is installed between the second connection end 132 and the second optical switch 162 to between the second connection end 132 and the fourth terminal 162a of the second optical switch 162. A portion of the light transmitted through the main transmission path of the branched through the second branch path (166a).

Preferably, the second optical splitter 166 also receives about 2 to 10% of the light transmitted between the second connection terminal 132 and the fourth terminal 162a of the second optical switch 162 to the second branch path 166a. What can be branched through applies.

The first photodetector 171 detects the light received through the first branch path 165a and outputs the light to the controller 181.

The second photodetector 172 detects the light received through the second branch path 166a and outputs the light to the controller 181.

If the light quantity received from the first photodetector 171 and the second photodetector 172 is determined to be less than or equal to the set reference level, the controller 181 determines that the optical path is faulty, and thus, the first optical path 151 and the second optical beam. The first optical switch 161 and the second optical switch 162 are controlled to switch the connection to the optical path which is currently unconnected in the furnace 152.

That is, the controller 181 currently connects the first optical path 151 with the first connection terminal 112 and the second connection terminal 132 through the first optical switch 161 and the second optical switch 162. If the amount of light received from the first photodetector 171 and the second photodetector 172 is less than or equal to the set reference level in the maintained state, it is determined that the optical path is out of order, and the second optical path 152 determines that the first optical The first optical switch 161 and the second optical switch 162 are controlled to be connected to the switch 161 and the second optical switch 162.

Meanwhile, the operation unit 183 may select an automatic mode in which the first optical path 151 and the second optical path 162 are automatically adjusted by the control unit 181, and a manual mode selectable by a user's operation. A mode selection key (not shown) and an operation key for selecting one of the first optical path 151 and the second optical path 152 to be connected by a user's operation in the state set to the manual mode are provided. .

In this case, when the control unit 181 receives the optical mode selection signal from the operation unit 183 by the manual mode selection and the operation key, the control unit 183 irrespective of the information received from the first and second photodetectors 171 and 172. The first and second optical switches 161 and 162 are controlled to be connected between the donor unit 110 and the remote unit 130.

The display unit 183 is controlled by the control unit 181 to display line state information currently connected between the donor unit 110 and the remote unit 130.

On the other hand, the control unit 181 determines that there is an abnormality in the optical path maintained at the current connection in the automatic mode, and when the first and second optical switches 161 and 162 are controlled to switch to another optical path, the controller abnormality is registered. It can be constructed to transmit information in a text communication (sms) manner.

The optical repeater system 100 can reduce the communication failure by automatically switching the connection to the remaining optical path when any one of the plurality of optical paths provided between the donor unit 110 and the remote unit 130 occurs. In case of diagnosing, repairing and repairing the optical line, it selects the line in the manual mode and provides the advantage that the operation can be performed without communication failure.

110: donor unit 130: remote unit
150: light beam switching unit

Claims (3)

delete A donor unit for outputting an integrated optical signal incorporating different mutually received communication service signals through a first connection terminal, and the integrated optical signal transmitted to the donor unit and received through a second connection terminal according to a communication service type; In the optical repeater system having a remote unit for separating and transmitting to the subscriber station,
A first optical path provided between the first connection end of the donor unit and the second connection end of the remote unit to transmit the integrated optical signal;
A second optical path provided separately from the first optical path between the first connection end of the donor unit and the second connection end of the remote unit to transmit the integrated optical signal;
A first optical switch for selectively connecting either one end of the first optical path or one end of the second optical path to the first connection end of the donor unit according to a control signal;
A second optical switch for selectively connecting one of the other end of the first optical path and the other end of the second optical path with the second connection end of the remote unit in accordance with a control signal;
A first optical splitter provided between the first connection terminal and the first optical switch to branch a part of the light transmitted through the first branch path;
A second optical splitter configured to branch a portion of the light transmitted between the second connection terminal and the second optical switch through a second branch path;
A first photodetector for detecting light received through the first branch path;
A second photodetector for detecting light received through the second branch path;
If it is determined that the amount of light received from the first photodetector and the second photodetector is less than or equal to a set reference level, it is determined that the optical path has failed. A control unit controlling the first optical switch and the second optical switch to be switched;
A mode selection key for selecting an automatic mode for automatically adjusting the first optical path and the second optical path by the controller and a manual mode selectable by a user's operation, and the first optical path and the And an operation unit provided with an operation key for selecting one of the second optical paths so as to be connected by a user's operation.
The controller selects the line selected by the operation unit regardless of the information received from the first and second photodetectors when the manual mode selection and the optical path selection signal are received by the operation key from the operation unit. And controlling said first and second optical switches to be connected between a remote unit. The optical repeater system according to claim 2, further comprising a display unit controlled by the control unit to display line state information currently connected between the donor unit and the remote unit.

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