KR102246969B1 - Distributed antenna system and service method thereof - Google Patents

Abstract

A distributed antenna system and a service method of a distributed antenna system according to another aspect of the present invention include a path for transmitting a base station signal from a main unit to a first remote unit connected to the main unit through at least one or more units. 1 determining whether a basic path is abnormal; Controlling the first basic path to be changed to a first spare path to which the main unit and the first remote unit are directly connected, based on whether the determined first basic path is abnormal; Controlling, by the main unit, to transmit the base station signal to the first remote unit through the first spare path; And controlling the first remote unit to receive the base station signal from the main unit. It may include.

Description

Distributed antenna system and service method of distributed antenna system {DISTRIBUTED ANTENNA SYSTEM AND SERVICE METHOD THEREOF}

The technical idea of the present invention relates to a distributed antenna system and a service method of the distributed antenna system. In particular, the present invention relates to a system and method for service by changing a path for transmitting a base station signal in a distributed antenna system.

A distributed antenna system is an antenna system used to spatially distribute a plurality of antennas to solve a problem of high traffic capacity in an indoor environment or a predetermined area.

Distributed antenna systems are installed inside buildings, tunnels, subways, etc. to provide communication services even in areas in which the base transceiver station signal is difficult to reach. It is used to provide services.

As described above, the distributed antenna system is a system for supplementing the limited output and coverage of a base station, and is widely used to eliminate a service shadow area.

The distributed antenna system transmits signals using a path through a line connecting several units and units. However, when a problem occurs in a path through which a signal is transmitted, a problem occurs in that the signal cannot be emitted at the end of the path in which the problem occurs.

Prior literature related to this includes Korean Patent Application Publication No. KR10-2015-0054430 (published on April 28, 2015).

A distributed antenna system and a service method of a distributed antenna system according to the technical idea of the present invention are to check whether a path for transmitting a base station signal is abnormal, and when an abnormality occurs, the purpose of the service is to change a path for transmitting a base station signal. .

A distributed antenna system and a service method of a distributed antenna system according to various embodiments of the present invention have an object of detecting an abnormal position in the distributed antenna system and changing a path for transmitting a base station signal according to the detected abnormal position. have.

A distributed antenna system and a service method of a distributed antenna system according to another aspect of the present invention include a path for transmitting a base station signal from a main unit to a first remote unit connected to the main unit through at least one or more units. 1 determining whether a basic path is abnormal; Controlling the first basic path to be changed to a first spare path to which the main unit and the first remote unit are directly connected, based on whether the determined first basic path is abnormal; Controlling, by the main unit, to transmit the base station signal to the first remote unit through the first spare path; And controlling the first remote unit to receive the base station signal from the main unit. It may include.

According to an exemplary embodiment, the step of controlling the first remote unit to process to transmit the base station signal to another remote unit; And controlling the first remote unit to transmit the processed base station signal to the other remote unit. It may further include.

According to an exemplary embodiment, the controlling of the first remote unit to transmit the processed base station signal to another remote unit includes: receiving, by the first remote unit, path control of the main unit, and the first It may include the step of controlling the remote unit to transmit the processed base station signal to the other remote unit in correspondence with the path control of the main unit.

According to an exemplary embodiment, the determining whether the first basic path is abnormal may include transmitting the base station signal from the main unit to the first remote unit connected to the main unit through at least one hub unit. Determining whether the first basic path, which is a path, is abnormal; And transmitting, by the first remote unit, the base station signal to the at least one hub unit; It may further include.

According to an exemplary embodiment, the transmitting of the base station signal from the first remote unit to the at least one hub unit comprises: receiving, by the first remote unit, path control of the main unit, and the first remote unit It may include controlling the unit to transmit the processed base station signal to the at least one hub unit in response to the path control of the main unit.

According to an exemplary embodiment, the determining whether the first basic path is abnormal may include: detecting an abnormal position, which is a position where an abnormality occurs on the path, on all paths of the distributed antenna system; Including, and the step of controlling to change to the first spare path, based on the detected abnormal position in the distributed antenna system, at least one of a plurality of remote units directly connected to the main unit through each spare path Controlling to select a remote unit of; Including, wherein the controlling of the main unit to transmit the base station signal to the first remote unit through the first spare path, the main unit, at least one selected from among the plurality of remote units Controlling to transmit the base station signal to the selected at least one remote unit through the spare path corresponding to the remote unit; And controlling the first remote unit to receive the base station signal from the main unit, the step of controlling the selected at least one remote unit to receive the base station signal from the main unit; It may include.

A subsystem included in a distributed antenna system according to another aspect according to the technical idea of the present invention includes: a main unit; And a first remote unit connected to the main unit through at least one or more units. Including, the main unit, the path abnormality detection module for determining whether or not a first basic path, which is a path for transmitting a base station signal to the first remote unit; A path control module configured to change the first basic path to a first spare path to which the main unit and the first remote unit are directly connected, based on whether the determined first basic path is abnormal; And a main signal transmission module configured to transmit the base station signal to the first remote unit through the first spare path. Including, the first remote unit, the upper signal receiving module for controlling to receive the base station signal from the main unit; It may include.

According to an exemplary embodiment, the first remote unit includes: a signal processing module controlling the first remote unit to process the base station signal to transmit the base station signal to another remote unit; And a remote signal transmission module for controlling the first remote unit to transmit the processed base station signal to the other remote unit. It may further include.

According to an exemplary embodiment, the path control module generates a signal for controlling a signal transmission path of the first remote unit, and the first remote unit generates a signal based on a signal for controlling the signal transmission path. A path change module for controlling to change a transmission path; It further includes, wherein the remote signal transmission module, the base station signal processed by the first remote unit, based on a path through which the changed signal is transmitted, may be controlled to transmit to the other remote unit.

According to an exemplary embodiment, the path abnormality detection module is configured to determine whether a first basic path, which is a path for transmitting signals from the main unit to the first remote unit connected through at least one hub unit, is abnormal. And the first remote unit comprises: a remote signal transmission module for transmitting the base station signal to the at least one hub unit to which the first remote unit is directly connected; It may further include.

According to an exemplary embodiment, the path control module generates a signal for controlling a signal transmission path of the first remote unit, and the first remote unit, based on a signal for controlling the signal transmission path, A path change module for controlling to change a path for transmitting the data; Further comprising, the remote signal transmission module, the base station signal processed by the first remote unit, based on a path through which the changed signal is transmitted, may be controlled to transmit to the at least one or more hub units. .

According to an exemplary embodiment, the path anomaly detection module detects an anomaly location, which is a location of an anomaly on a path, on all paths of the distributed antenna system, and the path control module, based on the detected abnormal location , Controls to select at least one remote unit from among a plurality of remote units directly connected to the main unit through respective spare paths, and the main signal transmission module corresponds to at least one remote unit selected from among the plurality of remote units. Controls to transmit the base station signal to the selected at least one remote unit through the reserved path, and the upper signal receiving module includes the selected at least one remote unit to receive the base station signal from the main unit. Can be controlled to do.

In the distributed antenna system and the service method of the distributed antenna system according to the technical idea of the present invention, it is possible to check whether an abnormality exists in a path for transmitting a base station signal and, if an abnormality occurs, change a path for transmitting a base station signal to provide service.

The distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present invention may detect an abnormal position in the distributed antenna system, and service by changing a path for transmitting a base station signal according to the detected abnormal position. .

A brief description of each drawing is provided in order to more fully understand the drawings cited in the detailed description of the present invention.
1 is a conceptual diagram of a distributed antenna system according to an embodiment of the present invention.
2 is a block diagram of a configuration of a main unit according to various embodiments of the present disclosure.
3 is a block diagram of a configuration of a remote unit according to various embodiments of the present disclosure.
FIG. 4 is an exemplary diagram illustrating a method of changing a transmission path according to a state of a path through which a signal is transmitted in a distributed antenna system in which a hub unit is implemented in a ring structure according to various embodiments of the present disclosure to provide a service.
FIG. 5 is a diagram illustrating a method of changing a transmission path according to a state of a signal transmission path in a distributed antenna system implemented in a structure in which a plurality of hub units are connected to a main unit according to various embodiments of the present invention to provide a service. It is an exemplary diagram.
6 is a flowchart illustrating a method of determining and servicing an abnormal state of a basic path in a distributed antenna system according to various embodiments of the present disclosure.
7 is a flowchart illustrating a method of determining and servicing an abnormal location in a distributed antenna system according to another embodiment of the present invention.

The technical idea of the present invention is that various changes may be made and various embodiments may be provided, and specific embodiments will be illustrated in the drawings and described in detail. However, this is not intended to limit the technical idea of the present invention to a specific embodiment, it should be understood to include all changes, equivalents, and substitutes included in the scope of the technical idea of the present invention.

In describing the technical idea of the present invention, if it is determined that a detailed description of a related known technology may unnecessarily obscure the subject matter of the present invention, a detailed description thereof will be omitted. In addition, numbers (eg, first, second, etc.) used in the description of the present specification are merely identification symbols for distinguishing one component from other components.

In addition, in the present specification, when one component is referred to as "connected" or "connected" to another component, the one component may be directly connected or directly connected to the other component, but specially It should be understood that as long as there is no opposite substrate, it may be connected or may be connected via another component in the middle.

In addition, terms such as "~ unit", "~ group", "~ character", and "~ module" described in the present specification mean a unit that processes at least one function or operation, which is a processor or a microcomputer. Processor (Micro Processer), Micro Controller, CPU (Central Processing Unit), GPU (Graphics Processing Unit), APU (Accelerate Processor Unit), DSP (Digital Signal Processor), ASIC (Application Specific Integrated Circuit), FPGA It can be implemented by hardware or software such as (Field Programmable Gate Array), or a combination of hardware and software.

In addition, it is intended to clarify that the division of the constituent parts in the present specification is merely divided by the main function that each constituent part is responsible for. That is, two or more constituent parts to be described below may be combined into one constituent part, or one constituent part may be divided into two or more for each more subdivided function. In addition, each of the constituent units to be described below may additionally perform some or all of the functions of other constituent units in addition to its own main function, and some of the main functions of each constituent unit are different. It goes without saying that it can also be performed exclusively by.

Hereinafter, embodiments according to the technical idea of the present invention will be described in detail in order.

1 is a conceptual diagram of a distributed antenna system according to an embodiment of the present invention.

Referring to FIG. 1, a distributed antenna system 10 may include a Point Of Interest (POI) 30, a main unit 100, a hub unit 200, and a remote unit 300. Here, the POI 30 and the main unit 100 may be referred to as a head end, and the main unit 100 may be referred to as a head end.

The POI 30 may be connected to each of the plurality of base stations 1a to 1n, and may receive a base station signal corresponding to the downlink from the connected plurality of base stations 1a to 1n. In addition, the POI 30 may transmit the processed base station signal to the main unit 100.

The POI 30 can process the base station signal transmitted from the base station (BTS, 1a~1n) so that the distributed antenna system 10 can process it, and the terminal signal received and processed by the distributed antenna system 10 The signal can be processed so that it can be transmitted to the base stations 1a to 1n.

For example, the POI 30 may attenuate a base station signal having a high power level and convert it to a level suitable for the distributed antenna system 10. In addition, the POI 30 may attenuate the terminal signal processed by the distributed antenna system 10 to be suitable for the base stations 1a to 1n.

Here, the POI 30 may also be referred to as a signal matching device.

The main unit 100 may be connected to the POI 30, the hub unit 200, and the plurality of remote units 300 through a communication medium. Here, the communication medium may include an optical fiber, a coaxial cable, or the like.

The main unit 100 may transmit the received base station signal to the hub unit 200 and the remote unit 300.

For example, the main unit 100 may convert an RF signal into a digital signal, and may distribute the converted digital signal to the hub unit 200 and the remote unit 300.

Specifically, the main unit 100 may distribute the converted digital signal so as to transmit the received RF signal to the remote unit 300 corresponding to the area to be output.

The main unit 100 may be connected to another main unit, and may transmit or receive a base station signal or a terminal signal with another main unit connected. Here, the base station signal may mean a downlink signal, and the terminal signal may mean an uplink signal.

The main unit 100 may distribute or redistribute capacity for communication services.

Also, the main unit 100 may perform signal conversion between a frequency division duplex method and a time division duplex method. For example, the main unit 100 may convert an FDD carrier into a TDD carrier, and may convert a TDD carrier into an FDD carrier. Here, the carrier may include data according to a service signal or may mean a service signal.

The main unit 100 may detect whether a path for transmitting a base station signal is abnormal. In addition, the main unit 100 may detect a location where an abnormality occurs during configuration in the distributed antenna system 10. Also, the main unit 100 may detect whether a path for receiving a terminal signal is abnormal.

The main unit 100 may change a signal transmission path according to whether a path for transmitting a base station signal is abnormal. In addition, the main unit 100 may change a signal transmission path according to a location of a component in which an abnormality occurs in the distributed antenna system. Also, the main unit 100 may change a path for receiving a signal according to whether or not a path for receiving a terminal signal is abnormal.

The main unit 100 may also be referred to as a DAU (Distribution & Aggregation Unit).

The hub unit 200 may be connected to the main unit 100 and the remote unit 300. For example, the hub unit 200 may be connected to the main unit 100 and a plurality of remote units 300 through an optical fiber.

The hub unit 200 may be connected between the main unit 100 and the remote unit 300 to expand the connection capacity of the remote unit 300 of the main unit 100. For example, the first hub unit 200a may be connected to the main unit 100, the second hub unit 200b, and the first remote unit 300a. It can also be connected to the remote unit (300b). The second hub unit 200b may be connected to the third remote unit 300c and the fourth remote unit 300d. In addition, the third hub unit 200c may be connected to the main unit 100 and the fifth remote unit 300e. Accordingly, the main unit 100 is directly connected to the sixth to nth remote units 300f to 300n, and the first to fifth remote units 300a to 300e are connected through the hub unit 200. I can.

In another embodiment, the distribution antenna system 10 may be configured in a topology in which the remote unit 300 is connected to the main unit 100 through the hub unit 200.

The hub unit 200 may transmit a signal between the connected main unit 100 and the remote unit 300.

For example, the hub unit 200 may convert a digital signal transmitted from the main unit 100 into an Ethernet format and transmit data converted into the Ethernet format to the remote unit 300.

The hub unit 200 may supply power to the remote unit 300. For example, the hub unit 200 may supply power to the connected remote unit 300 through Power of Ethernet (PoE).

The hub unit 200 may monitor current for each of the connected plurality of remote units 300 and may automatically cut off power according to the monitoring.

The remote unit 300 may be connected to the main unit 100 and may be connected to the main unit 100 through the hub unit 200. In addition, the remote unit 300 may be connected to the main unit 100 through another remote unit 300.

The remote unit 300 may output a base station signal transmitted from the main unit 100 through an antenna, and may transmit a terminal signal received through the antenna to the main unit 100.

The remote unit 300 may be divided into high power and low power according to the output. A remote unit having a low output power may be referred to as a low power radio node, and a remote unit having a high output power may be referred to as a high power radio node.

The remote unit 300 may include an integrated antenna, and may be connected to an external antenna through an external antenna port.

Further, the remote unit 300 may include or be connected to a plurality of directional antennas, so that a signal may be transmitted to a specific area or a specific sector, and a signal from a specific area or a specific sector may be received. For example, the remote unit 300 may include at least one sector antenna or may be connected to a sector antenna. In addition, the remote unit 300 may include or be connected to an omnidirectional antenna and a directional antenna.

The remote unit 300 may selectively operate only some of the external antennas connected to the built-in antenna.

The remote unit 300 may receive a base station signal from the main unit 100, the hub unit 200, or another remote unit 300, and the remote unit 300 is a terminal signal from the terminal or other remote unit 300. Can be received.

The remote unit 300 may receive a base station signal through a separate line directly connected to the main unit 100. In addition, the remote unit 300 may transmit a terminal signal through a separate line directly connected to the main unit 100. For example, the first remote unit 300a may be directly connected to the main unit 100 through a separate line to receive a base station signal, and the first remote unit 300a may be directly connected to the main unit 100 through a separate line to be connected to the terminal. Can transmit signals.

When the remote unit 300 directly receives a base station signal from the main unit 100, the remote unit 300 may perform processing for transmitting the signal to the other remote unit 300. Specifically, the first remote unit 300a may receive a base station signal from the main unit 100 through a separate line directly connected to the main unit 100, and the first remote unit 300a may receive the received base station signal. It is possible to perform a process for transmitting to the second remote unit (300b).

For example, the first remote unit 300a may divide the received base station signal into a frequency band that can be used by the second remote unit 300b, and transmit the divided signal to the second remote unit 300b.

For another example, the first remote unit 300a converts a base station signal, which is a digital signal transmitted from the main unit 100, into an Ethernet format, and transmits the base station signal converted into the Ethernet format to the second remote unit 300b. I can.

For another example, the first remote unit 300a may supply power to the connected second remote unit 300b through Power of Ethernet (PoE).

For another example, the first remote unit 300a may monitor the current to the connected remote unit 300b, and automatically cut off the power according to the monitoring.

A Network Management System (NMS) 50 may manage a network including the distributed antenna system 10. For example, the NMS 50 may monitor and control components included in the distributed antenna system 10, for example, the state and operation of one node.

2 is a block diagram of a configuration of a main unit 100 according to various embodiments of the present disclosure.

1 and 2, the main unit 100 may include a path abnormality detection module 110, a path control module 130, and a main signal transmission module 150. The path abnormality detection module 110 may determine whether a basic path, which is a path for transmitting a base station signal from the main unit 100 to the remote unit 300, is abnormal.

Here, the basic path may mean a path for transmitting a base station signal from the main unit 100 to the remote unit 300. Specifically, the basic path is a path through which the main unit 100 is connected to the remote unit 300 through at least one unit, and may mean a path for transmitting and receiving signals in a normal state. Therefore, the default path may be referred to as a main path. For example, a path to which the main unit 100, the first hub unit 200a, and the first remote unit 300a are connected may be referred to as a first basic path. For another example, a path to which the main unit 100, the first hub unit 200a, the first remote unit 300a, and the second remote unit 300b are connected may be referred to as a second basic path. In addition, a path to which the main unit 100, the first hub unit 200a, the second hub unit 200b, and the fourth remote unit 300d are connected may be referred to as a fourth basic path.

For example, the path abnormality detection module 110 may determine whether the first basic path for transmitting the base station signal from the main unit 100 to the first remote unit 300a through the first hub unit 200a is abnormal. I can.

In addition, the path anomaly detection module 110 may determine an abnormal location, which is a location where an abnormality occurs on the path, on all paths of the distributed antenna system 10.

Here, the abnormal position may mean a position of a configuration in which an abnormality occurs among all the lines connecting the units and the units in the distributed antenna system and all configurations including all units. Also, the abnormal position may mean a position of a basic path in which an abnormality has occurred among at least one or more basic paths included in the distributed antenna system. For example, the path abnormality detection module 110 may determine whether the hub unit 200 is abnormal, and may determine whether the remote unit 300 is abnormal. In addition, the path abnormality detection module 110 may determine whether there is an abnormality in the line between the main unit 100 and the hub unit 200, and determine whether there is an abnormality in the line between the hub unit 200 and the remote unit 300 can do. In addition, the path abnormality detection module 110, a first path, which is a path for transmitting a base station signal from the main unit 100 to the first remote unit 300a through the first hub 200a, in the main unit 100 The first hub unit 200a and the first hub unit 200a and the first hub unit 200a from the main unit 100 and a second path that is a path for transmitting a base station signal to the second remote unit 300b through the first hub 200a and the first remote unit 300a 2 It is possible to determine whether a fourth path, which is a path for transmitting a base station signal to the fourth remote unit 300d through the hub unit 200b, is abnormal.

The path anomaly detection module 110 may determine whether a basic path is abnormal through various methods. In addition, the path abnormality detection module 110 may determine whether the hub unit 200, the remote unit 300, or a line connecting each unit is abnormal through various methods. For example, the path abnormality detection module 110 may determine whether there is an abnormality based on whether or not a signal is received. For another example, the path anomaly detection module 110 may generate a test signal and transmit it through a basic path, and may determine whether or not there is an abnormality according to whether the corresponding test signal is fed back. The path control module 130 is a path that transmits a base station signal to the main unit 100 and the remote unit 300 connected through at least one or more units according to the abnormality of the basic path determined by the path abnormality detection module 110. The basic path may be controlled to change to a spare path through which the main unit 100 and the remote unit 300 are directly connected.

Here, the spare path is a path through which the main unit 100 is directly connected to one remote unit 300 and may mean a preliminary path used when an abnormality occurs in the basic path. In addition, since the main unit 100 and the remote unit 300 are directly connected to the spare path, other units or nodes other than the main unit 100 and the remote unit 300 may not exist on the spare path. The spare path is deactivated when the main path is normal, and when it is determined that the main path is abnormal, it may be changed to send and receive signals through the spare path. In addition, the path control module 130 is based on the abnormal position in the distributed antenna system determined by the path abnormality detection module 110, the main unit 100 and at least one of a plurality of remote units directly connected through each spare path. It can be controlled to select a remote unit.

The path control module 130 may generate a signal for controlling a path through which the remote unit 300 transmits a signal. In addition, the path control module 130 may generate a signal for controlling a path through which the hub unit 200 transmits a signal.

The main signal transmission module 150 may transmit a base station signal received from the base station to the remote unit 300 through the reserved path changed by the path control module 130.

In addition, the main signal transmission module 150 may transmit a base station signal received from the base station to the remote unit 300 through at least one spare path corresponding to at least one remote unit selected by the path control module 130.

For example, the main unit 100 may determine whether a basic path, which is a path for transmitting a base station signal to the first remote unit 300a through the first hub unit 200a, is abnormal. When the main unit 100 detects an abnormal state of the first hub unit 200a, a path for transmitting a base station signal to the first remote unit 300a is referred to as the main unit 100 and the first remote unit 300a. The base station signal may be transmitted to the first remote unit 300a through a separate spare path directly connected to the. A detailed description of this will be described later.

For another example, the main unit 100 may determine an abnormal position in the distributed antenna system. For example, the main unit 100 may determine an abnormality at the point of the second hub unit 200b in the determined distributed antenna system. The main unit 100 may transmit a base station signal to each of the third and fourth remote units 300c and 300d connected to the second hub unit 200b through the third and fourth spare paths. A detailed description of this will be described later.

The description of the above-described main unit 100 is an example for explanation, and may be variously configured according to a designer or user's selection. For example, each of the modules expressed as included in the main unit 100 may be implemented in a separate configuration and may be connected to the main unit 100 to operate.

Each of the modules of the above-described main unit 100 may be disposed not only in the main unit 100 but also in the hub unit 200 or the remote unit 300. In addition, each module of the main unit 100 may be implemented as a separate configuration, and may be connected to the hub unit 200 or the remote unit 300 to operate. Hereinafter, for convenience of description, it will be described that the main unit 100 determines whether there is an abnormality in the distributed antenna system and controls a path for transmitting a base station signal based on this, but is not limited thereto, and the main unit 100 ), at least one of the hub unit 200, the remote unit 300, or other separate configurations determines whether the path for transmitting the base station signal in the distributed antenna system is abnormal, and the path is determined based on the determined abnormality. Can be controlled.

3 is a block diagram of a configuration of a remote unit 300 according to various embodiments of the present disclosure.

1 and 3, the remote unit 300 includes a path change module 310, an upper signal reception module 330, a lower signal reception module 350, a signal processing module 370, and a remote signal transmission module ( 390).

The path change module 310 may change a signal transmission path according to a signal that controls a path through which a signal received from the main unit 100 is transmitted.

The upper signal receiving module 330 may receive a base station signal through a spare path directly connected to the main unit 100.

The lower signal reception module 350 may receive a base station signal from the hub unit 200 directly connected through a basic path.

In addition, the lower signal receiving module 350 may receive a base station signal from the remote unit 300 directly connected through a basic path.

The signal processing module 370 may perform signal processing for transmitting the received base station signal to another remote unit 300.

For example, the signal processing module 370 divides a base station signal received from the main unit 100 through a spare path into a frequency band that can be used by another remote unit 300, and divides the divided signal into another remote unit ( 300).

For another example, the signal processing module 370 converts a base station signal, which is a digital signal received through a spare path from the main unit 100, into an Ethernet format, and transfers data converted into the Ethernet format to another remote unit 300. Can be transmitted.

The remote signal transmission module 390 may transmit a base station signal received from the main unit 100 to another remote unit 300. In addition, the remote signal transmission module 390 may transmit a base station signal received from the main unit 100 to the hub unit 200.

In addition, the remote signal transmission module 390 may transmit a base station signal received from the main unit 100 to another remote unit 300 in correspondence with the transmission path changed by the path change module 310. In addition, the remote signal transmission module 390 may transmit the base station signal received from the main unit 100 to the hub unit 200 in correspondence with the transmission path changed by the path change module 310.

In addition, the remote signal transmission module 390 may transmit a base station signal processed for transmission to the other remote unit 300 to the other remote unit 300 according to the path control of the main unit 100. In addition, the remote signal transmission module 390 may transmit a base station signal processed for transmission to another remote unit 300 to the hub unit 200 corresponding to the path control of the main unit 100.

For example, the remote unit 300 may receive a base station signal from the main unit 100 through a spare path. The remote unit 300 may transmit the received base station signal to another remote unit 300, a hub unit 200, or a terminal (not shown) in response to the path control of the main unit 100.

For another example, the remote unit 300 may receive a base station signal from the main unit 100 through a spare path. The remote unit 300 may perform processing for transmitting the received base station signal to another remote unit 300. The remote unit 300 may transmit the processed base station signal to another remote unit 300.

The description of the above-described remote unit 300 is an example for description, and may be variously configured according to a designer's or a user's selection. For example, each module expressed as included in the remote unit 300 may be connected to the remote unit 300 in a separate configuration to operate.

Each of the modules of the above-described remote unit 300 may be disposed not only in the remote unit 300 but also in the hub unit 200 connected to the main unit 100 through at least one or more units. In addition, each module of the remote unit 300 may be implemented as a separate configuration, and may be connected to the hub unit 200 to operate. Hereinafter, for convenience of description, it will be described that the remote unit 300 receives the base station signal when there is an abnormality in the path through which the base station signal is transmitted, but is not limited thereto, and the main unit 100 and at least one or more The hub unit 200 connected through the unit may receive a base station signal when an abnormality occurs in the path.

FIG. 4 is an exemplary diagram illustrating a method of changing a transmission path according to a state of a path through which a signal is transmitted in a distributed antenna system in which a hub unit is implemented in a ring structure according to various embodiments of the present disclosure to provide a service.

Hereinafter, for convenience of description, the main unit 100 and the first to third remote units 300a to 300d are expressed as being connected through the first to third preliminary paths L1 to L3, but the present invention is not limited thereto. For example, the main unit 100 may be connected to the fourth to seventh remote units (300d to 300g) through respective spare paths, and only the first remote unit (300a) among the plurality of remote units (300a to 300g) is the first It can also be connected through a spare path (L1). In this way, the number of spare routes directly connected to the main unit 100 may be changed by design of a person skilled in the art.

Referring to FIG. 4, according to an embodiment of the present invention, the main unit 100 is a path for transmitting a base station signal to the first remote unit 300a through the first hub unit 200a. You can judge the presence or absence of an abnormality. When an abnormality in the first hub unit 200a is detected, the main unit 100 may change the path for transmitting the base station signal from the first basic path to the first spare path L1. The main unit 100 may transmit a base station signal to the first remote unit 300a through a first spare path L1 that is a changed path. The first remote unit 300a may transmit the received base station signal to the second remote unit 300b according to the path control of the main unit 100. In addition, the first remote unit 300a may perform signal processing for transmitting the received base station signal to the fifth remote unit 300e, and may transmit the processed base station signal to the fifth remote unit 300e. .

According to another embodiment, the main unit 100 may determine whether a first basic path, which is a path for transmitting a base station signal to the first remote unit 300a through the first hub unit 200a, is abnormal. When an abnormality is detected in the line between the main unit 100 and the first hub unit 200a, the main unit 100 changes the path for transmitting the base station signal from the first basic path to the first spare path L1. I can. The main unit 100 may transmit a base station signal to the first remote unit 300a through a first spare path L1 that is a changed path. The first remote unit 300a may transmit the received base station signal to the first hub unit 200a in response to path control of the main unit 100. In addition, the first remote unit (300a) can divide the received base station signal into a frequency band that can be used by the second and fifth remote units (300b, 300e) corresponding to the path control of the main unit (100), The divided base station signal may be transmitted to the second and fifth remote units 300b and 300e.

As described above, in the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present invention, it is possible to check whether an abnormality exists in a path for transmitting a base station signal and, if an abnormality occurs, a path for transmitting a base station signal can be changed. .

According to another embodiment, the main unit 100 may detect an abnormal position in the distributed antenna system 10. When the main unit 100 detects an abnormality in the first remote unit 300a, the main unit 100 may select a second remote unit 300b that cannot transmit a base station signal through a basic path. The main unit 100 may transmit a base station signal to the selected second remote unit 300b through the second spare path L2. The second remote unit 300b may receive a base station signal from the main unit 100 through the second spare path L2. The second remote unit 300b may radiate the received base station signal through a connected antenna.

According to another embodiment, the main unit 100 may detect an abnormal location in the distributed antenna system. The main unit 100 may detect an abnormal state of a line between the first hub unit 200a and the first remote unit 300a and an abnormal state of the second hub unit 200b. The main unit 100 may select a first remote unit 300a and a third remote unit 300c that cannot transmit a base station signal through a basic path, corresponding to the detected abnormal position of the distributed antenna system. The main unit 100 may transmit a base station signal to the first remote unit 300a through the first spare path L1, and the main unit 100 may transmit a third remote unit through the third spare path L3. The base station signal can be transmitted to (300c). The first remote unit 300a and the third remote unit 300c may receive a base station signal from the main unit 100 through a first spare path L1 and a third spare path L3, respectively. The first remote unit 300a may transmit the received base station signal to the fifth remote unit 300e according to the path control of the main unit 100. In addition, the first remote unit 300a may convert the received base station signal into an Ethernet format, and the base station signal converted into the Ethernet format corresponds to the path control of the main unit 100, and the second remote unit 300b Can be transferred to. The third remote unit 300c may radiate the received base station signal through an included antenna.

As described above, in the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present disclosure, an abnormal position in the distributed antenna system may be detected and a path for transmitting a base station signal may be changed according to the detected abnormal position.

In the above-described distributed antenna system 10, the main unit 100 and the first hub unit 200a are connected, and the other hub units 200b to 200c and the first remote unit 300a are connected to the first hub unit 200a. ) Is expressed as a connected structure, but is not limited thereto, and the connection structure between units of the distributed antenna system 10 may be changed by design of a person skilled in the art.

For example, in a structure in which the main unit 100 and a plurality of hub units 200 are connected, the distributed antenna system 10 may be implemented in a structure in which a base station signal is transmitted according to an error in a basic path. It will be described in detail below.

FIG. 5 is a diagram illustrating a method of changing a transmission path according to a state of a signal transmission path in a distributed antenna system implemented in a structure in which a plurality of hub units are connected to a main unit according to various embodiments of the present invention to provide a service. It is an exemplary diagram.

Hereinafter, for convenience of description, the main unit 100 and the first to second hub units 200a to 200b are expressed as being directly connected, but the present invention is not limited thereto. For example, the main unit 100 and three or more hub units 200 may be directly connected, and the main unit 100 and one or more remote units 300 may be directly connected. In this way, the number of units directly connected to the main unit 100 may be changed by design of a person skilled in the art.

In addition, hereinafter, for convenience of explanation, the first remote unit 300a is directly connected to the first hub unit 200a, and the second remote unit 300b is directly connected to the third hub unit 200c. However, it is not limited thereto. For example, two or more remote units 300 may be directly connected to the first hub unit 200a, and two or more remote units 300 may be directly connected to the third hub unit 300c. As such, the number of units connected to the hub unit 300 may be changed by design of a person skilled in the art.

Referring to FIG. 5, according to an embodiment of the present invention, the main unit 100 includes a first basic path, which is a path for transmitting a base station signal to the first remote unit 300a through the first hub unit 200a. You can judge the presence or absence of an abnormality. When an abnormality is detected in the first hub unit 200a, the line between the main unit 100 and the first hub unit 200a, or the line between the first hub unit 200a and the first remote unit 300a, The main unit 100 may change the path for transmitting the base station signal from the first basic path to the first spare path L1. The main unit 100 may transmit a base station signal to the first remote unit 300a through the first spare path L1. The first remote unit 300a may transmit the received base station signal to the third remote unit 300c according to the path control of the main unit 100. In addition, the first remote unit 300a may perform signal processing for transmitting the received base station signal to the fourth remote unit 300d according to the path control of the main unit 100, and the processed base station signal It can be transmitted to the fourth remote unit (300d).

According to another embodiment, the main unit 100 may detect an abnormal position in the distributed antenna system 10. When the main unit 100 detects an abnormality in the third hub unit 200c, the main unit 100 may select a second remote unit 300b that cannot transmit a base station signal through a basic path. The main unit 100 may transmit a base station signal to the selected second remote unit 300b through the second spare path L2. The second remote unit 300b may receive a base station signal from the main unit 100 through a second spare path L2, and the received base station signal is an antenna included in correspondence with the path control of the main unit 100. It can be radiated through.

6 is a flowchart illustrating a method of determining and servicing an abnormal state of a basic path in a distributed antenna system according to various embodiments of the present disclosure.

Referring to FIG. 6, the main unit may determine whether a basic path, which is a path for transmitting a signal from the main unit to the remote unit, has an error (S6100). When the main unit determines that there is an error in the basic path, the path for transmitting signals from the main unit to the remote unit may be changed from the basic path to a spare path in which the main unit and the remote unit are directly connected (S6300). The main unit may transmit a base station signal to a remote unit directly connected through the changed spare path (S6500). In addition, when the main unit determines that there is no error in the basic path, the main unit may transmit a base station signal to the remote unit through the basic path (S6500).

The remote unit may transmit the received base station signal based on a preset path (S6700).

According to an embodiment, the remote unit may perform signal processing to transmit the received base station signal to another remote unit (S6510). The remote unit may transmit the processed base station signal based on a preset path (S6700).

According to another embodiment, the remote unit may change the signal transmission path corresponding to the signal transmission path control signal of the main unit (S6530). The remote unit may transmit the received base station signal based on the changed signal transmission path (S6700).

According to another embodiment, the remote unit may perform signal processing to transmit the received base station signal to another remote unit (S6510). The remote unit may change the signal transmission path according to the signal transmission path control signal of the main unit (S6530). The remote unit may transmit the processed base station signal based on the changed signal transmission path (S6700).

7 is a flowchart illustrating a method of determining and servicing an abnormal location in a distributed antenna system according to another embodiment of the present invention.

Referring to FIG. 7, the main unit may determine whether the distributed antenna system is abnormal (S7100). When it is determined that there is an abnormal condition in the distributed antenna system, the main unit may detect a location where the abnormality is found (S7300). The main unit may select a remote unit that cannot be transmitted through the basic path according to the detected abnormal location, and change the path for transmitting the signal to a spare path corresponding to the selected remote unit (S7500). The main unit may transmit a base station signal to the remote unit through the set reserved path (S7700). In addition, when the main unit determines that there is no abnormal state in the distributed antenna system, the base station signal may be transmitted to the remote unit through the set basic path (S7700).

The remote unit may transmit the received base station signal according to a path controlled by the main unit (S7900).

According to an embodiment, the remote unit may perform signal processing to transmit the received base station signal to another remote unit (S7710). The remote unit may transmit the processed base station signal based on a preset path (S7900).

According to another embodiment, the remote unit may change the signal transmission path in response to the signal transmission path control signal of the main unit (S7730). The remote unit may transmit the received base station signal based on the changed signal transmission path (S7900).

According to another embodiment, the remote unit may perform signal processing to transmit the received base station signal to another remote unit (S7710). The remote unit may change the signal transmission path in response to the signal transmission path control signal of the main unit (S7730). The remote unit may transmit the processed base station signal based on the changed signal transmission path (S7900).

In the description of FIGS. 1 to 7 above, for convenience of explanation, it has been described as a content of transmitting a base station signal from the main unit 100 to the remote unit 300 through a basic path and a spare path, but is not limited thereto. Even when a terminal signal is transmitted from the remote unit 300 to the main unit 100, a basic path and a spare path may be used. In addition, when transmitting a terminal signal from the remote unit 300 to the main unit 100, functions that are changed according to the change in the signal transmission direction of each module of the main unit 100 and each of the modules of the remote unit 300 are However, since it is sufficiently inferred from the above explanations, the explanation is reduced. In the above, the technical idea of the present invention has been described in detail with reference to various embodiments, but the technical idea of the present invention is not limited to the above embodiments, and those of ordinary skill in the art within the scope of the technical idea of the present invention Various modifications and changes are possible by this.

1a~1n: BTS 10: Distributed antenna system
30: POI 50: NMS
100: main unit 110: path abnormality detection module
130: path control module 150: main signal transmission module
200a to 200n: Hub unit 300a to 300n: Remote unit
310: path change module 330: upper signal receiving module
350: lower signal reception module 370: signal processing module
390: remote signal transmission module

Claims (12)

Determining whether a first basic path, which is a path for transmitting a base station signal, to a first remote unit connected to the main unit through at least one or more units, from the main unit;
Controlling the first basic path to be changed to a first spare path to which the main unit and the first remote unit are directly connected, based on whether the determined first basic path is abnormal;
Controlling, by the main unit, to transmit the base station signal to the first remote unit through the first spare path; And
Controlling, by the first remote unit, to receive the base station signal from the main unit; Including,
The first basic path is a path connecting the main unit and the first remote unit through the at least one unit, and the first spare path is a path between the main unit and the first remote unit without going through the at least one unit. It is a path that connects units directly,
The determining whether the first basic path is abnormal may include detecting an abnormal location where an abnormality has occurred on the path of the distributed antenna system, and
The controlling to change to the first preliminary path may include controlling to select at least one remote unit from among a plurality of remote units directly connected to the main unit through each preliminary path based on the detected abnormal location. Containing; a service method of a distributed antenna system.
The method of claim 1,
Controlling the first remote unit to process to transmit the base station signal to another remote unit; And
Controlling the first remote unit to transmit the processed base station signal to the other remote unit;
Further comprising,
Distributed antenna system service method.
The method of claim 2,
The step of controlling the first remote unit to transmit the processed base station signal to another remote unit,
The first remote unit receiving path control of the main unit, and controlling the first remote unit to transmit the processed base station signal to the other remote unit according to the path control of the main unit.
Containing,
Distributed antenna system service method.
The method of claim 1,
The step of determining whether the first basic path is abnormal,
Determining whether or not the first basic path, which is a path for transmitting the base station signal, from the main unit to the first remote unit connected to the main unit through at least one hub unit;
Including,
Transmitting, by the first remote unit, the base station signal to the at least one hub unit;
Further comprising,
Distributed antenna system service method.
The method of claim 4,
Transmitting, by the first remote unit, the base station signal to the at least one hub unit,
Receiving, by the first remote unit, path control of the main unit; and
Controlling, by the first remote unit, to transmit the processed base station signal to the at least one hub unit in response to path control of the main unit
Containing,
Distributed antenna system service method.
The method of claim 1,
Controlling, by the main unit, to transmit the base station signal to the first remote unit through the first spare path,
Controlling, by the main unit, to transmit the base station signal to the selected at least one remote unit through the reserved path corresponding to at least one remote unit selected from among the plurality of remote units;
Including,
Controlling, by the first remote unit, to receive the base station signal from the main unit,
Controlling the selected at least one remote unit to receive the base station signal from the main unit;
Containing,
Distributed antenna system service method.
In the subsystem included in the distributed antenna system,
The subsystem,
Main unit; And
Includes; a first remote unit connected to the main unit through at least one or more units,
The main unit,
A path abnormality detection module for determining whether a first basic path, which is a path for transmitting a base station signal to the first remote unit, is abnormal;
A path control module configured to change the first basic path to a first spare path to which the main unit and the first remote unit are directly connected, based on whether the determined first basic path is abnormal; And
Including; a main signal transmission module for controlling to transmit the base station signal to the first remote unit through the first spare path,
The first remote unit,
Including; a higher level signal receiving module for controlling to receive the base station signal from the main unit,
The first basic path is a path connecting the main unit and the first remote unit through the at least one unit, and the first spare path is a path between the main unit and the first remote unit without going through the at least one unit. It is a path that connects units directly,
The path anomaly detection module, on the path of the distributed antenna system, detects an abnormal location where an abnormality occurs on the path,
The path control module, based on the detected abnormal location, controls to select at least one remote unit from among a plurality of remote units directly connected to the main unit through respective spare paths.
The method of claim 7,
The first remote unit,
A signal processing module controlling the first remote unit to process the base station signal to transmit the base station signal to another remote unit; And
A remote signal transmission module for controlling the first remote unit to transmit the processed base station signal to the other remote unit;
It further includes,
Subsystem.
The method of claim 8,
The path control module,
Generates a signal for controlling the signal transmission path of the first remote unit,
The first remote unit,
A path change module configured to change a path through which a signal is transmitted based on the signal for controlling the signal transmission path;
It further includes,
The remote signal transmission module,
Controlling to transmit the base station signal processed by the first remote unit to the other remote unit based on a path through which the changed signal is transmitted,
Subsystem.
The method of claim 7,
The path abnormality detection module,
It is determined whether or not a first basic path, which is a path for transmitting a signal from the main unit to the first remote unit connected through the main unit and at least one hub unit, is abnormal,
The first remote unit,
A remote signal transmission module for transmitting the base station signal to the at least one hub unit to which the first remote unit is directly connected;
It further includes,
Subsystem.
The method of claim 10,
The path control module,
Generates a signal for controlling the signal transmission path of the first remote unit,
The first remote unit,
A path change module configured to change a path through which a signal is transmitted, based on a signal controlling the signal transmission path;
It further includes,
The remote signal transmission module,
Controlling to transmit the processed base station signal by the first remote unit to the at least one hub unit based on a path through which the changed signal is transmitted,
Subsystem.
The method of claim 7,
The main signal transmission module,
Control to transmit the base station signal to the selected at least one remote unit through the reserved path corresponding to at least one selected remote unit among the plurality of remote units,
The upper signal receiving module,
Controlling the selected at least one remote unit to receive the base station signal from the main unit,
Subsystem.

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