KR102226254B1 - Distributed antenna system and service method thereof - Google Patents

Abstract

A subsystem included in a distributed antenna system according to another aspect according to the technical idea of the present invention includes a first band corresponding to a first band in a downlink signal including a downlink direction signal corresponding to each of at least one or more frequency bands. A second uplink signal corresponding to a second band isolated from the first band and a predetermined frequency or more in an uplink signal including an uplink direction signal corresponding to each of at least one frequency band and receiving a downlink signal is provided. A signal extraction module receiving and transmitting the second uplink signal in an uplink direction through a first transmission path; And a signal transmission module for transmitting the first downlink signal in a downlink direction through the first transmission path. 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 servicing by separating frequency bands of an uplink signal and a downlink signal from each other by a predetermined frequency or more 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 being 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.

In a distributed antenna system, configurations such as duplexers and filters are used to transmit and receive an uplink signal (UL) and a downlink signal (DL) through a single antenna. have. However, with the rapid increase of different frequency bands over a wide frequency range and the mixed use of frequency bands, efforts have been made to improve the performance of the duplexer and filter. Therefore, the performance of the duplexer and filter has a great influence on the performance of the distributed antenna system.

As a prior document related to this, there is a Korean Patent Application Publication No. KR10-1457704 (published on November 4, 2014).

The distributed antenna system and the service method of the distributed antenna system according to the technical idea of the present invention are to provide services by separating a downlink signal and an uplink signal from each other by a predetermined frequency band or more through a single transmission path.

A distributed antenna system and a service method of a distributed antenna system according to various embodiments of the present invention include an uplink signal obtained by extracting a signal of a specific frequency band from a plurality of uplink direction signals corresponding to each of a plurality of frequency bands, and a plurality of frequency bands. An object of the present invention is to provide a downlink signal obtained by extracting a signal of a specific frequency band from a plurality of downlink direction signals corresponding to each of the downlink signals by isolating a certain frequency band from each other through one transmission path.

A distributed antenna system and a service method of a distributed antenna system according to various embodiments of the present invention are to provide a service by separating an uplink signal and a downlink signal from each other by a predetermined frequency or more in one transmission path through a transmission path change. .

In the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present invention, by analyzing each signal and changing a transmission path according to the analysis result, an uplink signal and a downlink signal are mutually combined in one transmission path. The purpose is to provide services by isolating more than a certain frequency.

A subsystem included in a distributed antenna system according to another aspect according to the technical idea of the present invention includes a first band corresponding to a first band in a downlink signal including a downlink direction signal corresponding to each of at least one or more frequency bands. A second uplink signal corresponding to a second band isolated from the first band and a predetermined frequency or more in an uplink signal including an uplink direction signal corresponding to each of at least one frequency band and receiving a downlink signal is provided. A signal extraction module receiving and transmitting the second uplink signal in an uplink direction through a first transmission path; And a signal transmission module for transmitting the first downlink signal in a downlink direction through the first transmission path. It may include.

According to an exemplary embodiment, the downlink signal including a plurality of downlink direction signals corresponding to each of a plurality of frequency bands is received, and the first band corresponding to the first band among the received downlink signals Downlink signals can be extracted.

According to an exemplary embodiment, the distributed antenna system includes a plurality of transmission paths, and the signal extraction module allocates the received first downlink signal to a second transmission path among the plurality of transmission paths. A module, and the signal transmission module may transmit the first downlink signal through the allocated second transmission path.

According to an exemplary embodiment, the signal extraction module analyzes a signal to search for a transmission path for transmitting the first band, which is a frequency band of the first downlink signal, based on characteristics of each of the plurality of transmission paths. module; The signal allocation module may further include, based on a result of searching for the transmission path, allocating the first downlink signal to the second transmission path.

According to an exemplary embodiment, the signal extraction module receives the uplink signal including a plurality of uplink direction signals corresponding to each of a plurality of frequency bands, and the first band of the received uplink signals And extracting the second uplink signal corresponding to the second band separated by a predetermined frequency or more, and transmitting the extracted second uplink signal through the first transmission path.

According to an exemplary embodiment, the distributed antenna system includes a plurality of transmission paths, and the signal extraction module includes a signal allocation module that allocates the received second uplink signal to a second transmission path, and the The signal extraction module may transmit the second uplink signal through the second transmission path.

According to an exemplary embodiment, the signal extraction module analyzes a signal to search for a transmission path for transmitting the second band, which is a frequency band of the second uplink signal, based on characteristics of each of the plurality of transmission paths. module; The signal allocation module may further include, based on a result of searching for the transmission path, allocating the second uplink signal to the second transmission path.

A service method of a distributed antenna system according to an aspect of the inventive concept includes a first downlink corresponding to a first band in a downlink signal including a downlink direction signal corresponding to each of at least one or more frequency bands. Receiving a signal; In an uplink signal including an uplink direction signal corresponding to each of at least one or more frequency bands, a second uplink signal corresponding to a second band isolated from the first band by a predetermined frequency or more is received, and the second uplink signal Transmitting a link signal in an uplink direction through a first transmission path; And transmitting the first downlink signal in a downlink direction through the first transmission path. It may include.

According to an exemplary embodiment, the receiving of the first downlink signal includes receiving the downlink signal including the downlink direction signal corresponding to each of a plurality of frequency bands, and the received downlink And extracting the first downlink signal corresponding to the first band from among signals.

According to an exemplary embodiment, the distributed antenna system includes a plurality of transmission paths, and allocating the received first downlink signal to a second transmission path; Further comprising, and transmitting through the first transmission path, the first downlink signal may be transmitted through the allocated second transmission path.

According to an exemplary embodiment, the step of allocating the first downlink signal to the second transmission path comprises: a transmission path for transmitting the first band, which is a frequency band of the first downlink signal, the plurality of transmission paths. It may include searching based on characteristics of each path, and allocating the first downlink signal to the second transmission path based on a result of searching the transmission path.

According to an exemplary embodiment, the transmitting of the second uplink signal through the first transmission path includes receiving the uplink signal including the uplink direction signal corresponding to each of a plurality of frequency bands, and Extracting the second uplink signal corresponding to the second band isolated from the first band from among the received uplink signals by a predetermined frequency or more, and transmitting the extracted second uplink signal through the first transmission path. It may include the step of transmitting.

According to an exemplary embodiment, the distributed antenna system includes a plurality of transmission paths, and transmitting the second uplink signal through a first transmission path comprises: transmitting the received second uplink signal in a second Allocating a path and transmitting the second uplink signal through the allocated second transmission path.

According to an exemplary embodiment, the allocating the received second uplink signal to a second transmission path comprises: a transmission path for transmitting the second band, which is a frequency band of the second uplink signal, the plurality of And searching based on characteristics of each of the transmission paths and allocating the second uplink signal to the second transmission path based on a result of searching the transmission path.

In the distributed antenna system and the service method of the distributed antenna system according to the technical idea of the present invention, a downlink signal and an uplink signal may be separated from each other by a predetermined frequency band or more through a single transmission path.

A distributed antenna system and a service method of a distributed antenna system according to various embodiments of the present invention include an uplink signal obtained by extracting a signal of a specific frequency band from a plurality of uplink direction signals corresponding to each of a plurality of frequency bands, and a plurality of frequency bands. A downlink signal obtained by extracting a signal of a specific frequency band from a plurality of downlink direction signals corresponding to each can be serviced by isolating a certain frequency band or more from each other through a single transmission path.

In the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present disclosure, through a transmission path change, an uplink signal and a downlink signal may be separated from each other by a predetermined frequency or more in a single transmission path for service.

In the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present invention, by analyzing each signal and changing a transmission path according to the analysis result, an uplink signal and a downlink signal are mutually It can be isolated over a certain frequency and serviced.

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 remote unit according to various embodiments of the present disclosure.
3 is an exemplary diagram illustrating a service method of a distributed antenna system according to various embodiments of the present disclosure.
4 is an exemplary diagram illustrating a service method of a distributed antenna system when a signal extraction module according to various embodiments of the present disclosure is disposed in each path.
5 is an exemplary diagram illustrating a service method of a distributed antenna system when at least one transmission path shares one signal extraction module according to various embodiments of the present disclosure.
6 is an exemplary diagram of a distributed antenna system to which a service method of a distributed antenna system according to various embodiments of the present invention is applied.
7 is an exemplary diagram illustrating a frequency band allocated to each path of a distributed antenna system according to various embodiments of the present disclosure.
8 is a flowchart of a service method of a distributed antenna system according to an embodiment of the present invention.
9 is a flowchart of a service method of 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, or 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 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 hub unit 200 may be connected to the main unit 100 and may be connected to the first to third remote units 300a to 300c. Accordingly, the main unit 100 may be directly connected to the fourth to nth remote units 300d to 300n, and may be connected to the first to third remote units 300a to 300c through the hub unit 200. have.

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.

The remote unit 300 may output a 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.

In addition, 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 built-in antennas and the external antennas.

The remote unit 300 can receive a downlink signal from the main unit 100 or the hub unit 200, and the remote unit 300 is up from the terminal 5 or another remote unit 300. It can receive a link signal (UpLink Signal).

The remote unit 300 may transmit the received downlink signal in the downlink direction through the transmission path, and the remote unit 300 may transmit the received uplink signal in the uplink direction through the transmission path. Here, the transmission path may include a downlink path through which the downlink signal is transmitted to the terminal, and may include an uplink path through which the uplink signal is transmitted to the base station.

The remote unit 300 may extract a downlink signal corresponding to a specific frequency band from a plurality of received downlink direction signals. In addition, the remote unit 300 may extract an uplink signal corresponding to a specific frequency band from a plurality of received uplink direction signals.

The remote unit 300 may allocate a transmission path of a received downlink signal. In addition, the remote unit 300 may allocate a transmission path of the received uplink signal.

The remote unit 300 may analyze a path for transmitting the downlink signal based on the frequency band of the received downlink signal. In addition, the remote unit 300 may analyze a path for transmitting an uplink signal based on the frequency band of the received uplink signal.

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.

The configuration of the remote unit 300 will be described in detail with reference to FIG. 2.

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

Referring to FIG. 2, the remote unit 300 may include a signal extraction module 310 and a signal transmission module 330.

The signal extraction module 310 may receive a first downlink signal corresponding to the first band, receive a second uplink signal corresponding to a second band isolated from the first band by a predetermined frequency or more, and receive the received uplink signal. Link signals can be transmitted to the base station.

Here, a frequency band isolated over a certain frequency will be described with an example of a specific communication frequency band for each operator below.

3G DL (Mhz) 3G UL (Mhz) LTE DL (Mhz) LTE UL (Mhz) Business A 600 ~ 630 640 ~ 655,710 ~ 725 1030 ~ 1050
1210 ~ 1235 1160 to 1200
1050 ~ 1060 Business B 655 ~ 670 730 ~ 745 675 ~ 705 1135-1155
1235-1250 1060-1090
1275 ~ 1290 C business 810 to 840 850 ~ 870 900 ~ 910 1010 ~ 1025
1290 ~ 1305 1100 ~ 1130
1255 ~ 1275

For example, a frequency band isolated over a certain frequency may mean a frequency band isolated over 100Mhz. Specifically, in the case where the communication frequency band used for each operator is as above, the LTE downlink (DL) band of 1010Mhz ~ 1025Mhz band of the C operator and the 900Mhz ~ 910Mhz band of 3G uplink (UL) band of the C operator are, In that the frequency difference is 100Mhz, it may be a frequency band isolated over a certain frequency. On the other hand, the 1135Mhz ~ 1155Mhz band, which is the LTE DL band of the B provider and the 1050Mhz ~ 1060Mhz band, which is the LTE UL band of the A provider, may not be a frequency band isolated over a certain frequency in that the frequency difference between the bands is 75Mhz. For another example, a frequency band isolated over a certain frequency may mean a frequency band having different communication methods (such as 3G and LTE). Specifically, in the case where the communication frequency band used by each operator is as above, the frequency difference between the bands is 10Mhz, but the frequency difference between the bands is the 600Mhz ~ 630Mhz band, which is the 3G DL band of the A company, and the 640Mhz ~ 655Mhz band, which is the 3G UL band of the A company. In that (3G) is the same, it may not be a frequency band isolated over a certain frequency. In addition, the 810Mhz ~ 840Mhz band, which is the 3G DL band of the C company and the 640Mhz ~ 655Mhz band, which is the 3G UL band of the A company, the difference in frequency between the bands is 155Mhz, but in that the communication method (3G) is the same, more than a certain frequency May not be an isolated frequency band. Meanwhile, the 1010Mhz ~ 1025Mhz band, which is the LTE DL band of the C provider and the 900Mhz ~ 910Mhz band, which is the 3G UL band of the C provider, the frequency difference between the bands is 100Mhz, but in that the communication methods (3G and LTE) are different, a certain frequency It may be a frequency band isolated above.

For another example, a frequency band isolated over a certain frequency may mean a frequency band different from the operator. Specifically, in the case where the communication frequency band for each operator is as above, the 810Mhz ~ 840Mhz band, which is the DL band of the C operator, and the 1255Mhz ~ 1275Mhz band, which is the LTE UL band of the C operator, the frequency difference between the bands is 415Mhz, and the communication method ( 3G and LTE) are also different, but in that both frequency bands are frequency bands of C service providers, they may not be isolated frequency bands for more than a certain frequency. On the other hand, in the 3G DL band of Operator A, 600Mhz ~ 630Mhz, and the 3G UL band of Business B, 675Mhz ~ 705Mhz, the frequency difference between the bands is 45Mhz, but the same communication method (3G), but the operator of the corresponding frequency band In that it is different, it can be said to be a frequency band isolated over a certain frequency.

As described above, a frequency isolated over a certain frequency may be defined differently according to conditions such as a frequency band, a communication method, and a service provider. In addition, the spacing of the isolated frequency bands can be changed by design or selection by a person skilled in the art, and is not limited to the above description.

According to an embodiment, the signal extraction module 310 may receive a downlink signal including a downlink direction signal corresponding to each of a plurality of frequency bands, and a first signal corresponding to a first band in the received downlink signal. Downlink signals can be extracted.

According to another embodiment, the signal extraction module 310 may receive an uplink signal including an uplink direction signal corresponding to each of a plurality of frequency bands, and a first band and a predetermined frequency or more in the received uplink signal. A second uplink signal corresponding to the isolated second band may be extracted, and the extracted second uplink signal may be transmitted to the base station through a transmission path.

In addition, the signal extraction module 310 may include a signal analysis module 311 and a signal allocation module 313.

The signal analysis module 311 may search for a transmission path for transmitting the downlink signal by comparing the frequency band of the received downlink signal with the characteristics of each of the plurality of transmission paths, and determine the frequency band of the received uplink signal. It is possible to search for a transmission path for transmitting an uplink signal by comparing the characteristics of each of the plurality of transmission paths.

The signal allocation module 313 may allocate a downlink signal received by the signal extraction module 310 to a specific path among a plurality of transmission paths, and the uplink signal received by the signal extraction module 310 may be assigned to a plurality of transmission paths. It can be assigned to a specific route. Here, the path for allocating the downlink signal and the path for allocating the uplink signal by the signal allocation module 313 may be the same path, and the path for allocating the downlink signal and the path for allocating the uplink signal are different paths. May be.

According to an embodiment, the signal allocation module 313 may allocate a transmission path to a path corresponding to a result of the signal analysis module 311 searching for a transmission path for transmitting a downlink signal, and the signal allocation module 313 ) May allocate a transmission path to a path corresponding to a result of the signal analysis module 311 searching for a transmission path for transmitting an uplink signal.

The signal transmission module 330 may transmit the downlink signal received by the signal extraction module 310 toward the terminal through a transmission path, and may receive an uplink signal transmitted from the terminal. Here, the signal transmission module 330 may include a plurality of antennas or may be connected to a plurality of antennas.

The description of the above-described distributed antenna system 10 and the remote unit 300 is an example for explanation, and may be variously configured according to a designer or user's selection. Accordingly, in addition to the digital processing configuration described above, an analog processing configuration may be implemented, or a digital processing configuration and an analog processing configuration may be mixed and implemented.

Based on the configuration and description of the above-described distributed antenna system 10 and remote unit 300, a service method of the distributed antenna system 10 and the distributed antenna system 10 according to various embodiments of the present invention will be described. do.

Hereinafter, for convenience of description, it is described that the remote unit 300 receives a downlink signal and an uplink signal and transmits each signal after various processing, but the present invention is not limited thereto, and the main unit 100 and the hub At least one configuration of the unit 200 or the remote unit 300 may receive a downlink signal and an uplink signal, and transmit each signal after various processing.

3 is an exemplary diagram illustrating a service method of a distributed antenna system according to various embodiments of the present disclosure.

Referring to FIG. 3, the remote unit 300 may include at least one or more transfer paths (Transfer Path 1, Transfer Path 2 to Transfer Path n). Here, each of the transfer paths is a downlink path, which is a path for transmitting a downlink signal transmitted from the base station, and an uplink path, which is a path for transmitting an uplink signal transmitted from the terminal. It may include, and may include a signal transmission module 330 for transmitting a downlink signal transmitted from the base station to the terminal or receiving an uplink signal transmitted from the terminal.

In addition, the remote unit 300 extracts a signal of a specific frequency band from a plurality of downlink direction signals corresponding to each of a plurality of frequency bands, or extracts a signal of a specific frequency band from a plurality of uplink direction signals corresponding to each of a plurality of frequency bands. It may include a signal extraction module 310 for extracting a signal. Here, a signal extraction module may be provided in each of the plurality of transmission paths, and a plurality of transmission paths may be provided in a form in which one signal extraction module is shared. A detailed description of this will be described later.

The remote unit 300 receives the downlink signal transmitted from the base station through at least a part of the downlink path among the transfer paths, and transmits the received downlink signal to the signal transmission module 330. It can be transmitted through the terminal direction. In addition, the remote unit 300 receives the downlink signal transmitted from the terminal and the uplink signal having a frequency separated by a predetermined frequency or more through the signal transmission module 330, and transmits the received uplink signal. Path) can be transmitted in the direction of the base station through an uplink path (UL Path). For example, the downlink signal may be a signal of 600Mhz band, and the uplink signal may be a signal of 800Mhz band. The frequency band of the downlink signal and the frequency band of the uplink signal expressed herein are for illustration only, and are not limited thereto.

According to an embodiment, the signal extraction module 310 of the remote unit 300 transfers the first downlink signal corresponding to the first band to a first downlink path included in the first transmission path 1. It can be received through at least a part of 1). The signal extraction module 310 of the remote unit 300 may transmit the received first downlink signal to the terminal using the first signal transmission module 330-1. In addition, the signal extraction module 310 of the remote unit 300 may receive a second uplink signal corresponding to a second band isolated from the first band by a predetermined frequency or more through the first signal transmission module 330-1. I can. The signal extraction module 310 of the remote unit 300 may transmit the received second uplink signal to the base station through the first uplink path (UL Path 1) included in the first transmission path (Transfer Path 1). have.

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, a downlink signal and an uplink signal may be isolated from each other by a predetermined frequency band or more through a single transmission path.

In the above description, although the downlink signal transmitted by the base station and the uplink signal transmitted by the terminal are expressed as being isolated from each other by a predetermined frequency or more, the present invention is not limited thereto. Receiving a plurality of downlink signals from at least one base station to extract a downlink signal of a specific frequency band, and receiving a plurality of uplink signals from at least one terminal An embodiment of extracting an uplink signal is also possible, which will be described in detail below.

4 is an exemplary diagram illustrating a service method of a distributed antenna system when a signal extraction module according to various embodiments of the present disclosure is disposed in each path.

Hereinafter, for convenience of description, the case of two transfer paths is described, but the present invention is not limited thereto, and it is natural that the number of transfer paths may be changed by design of a person skilled in the art.

In addition, for convenience of description, although the signal extraction module 310 and the signal transmission module 330 are expressed as being connected, the position of the signal extraction module 310 and the signal transmission module 330 is not limited thereto. It is natural that it can be changed by the design of a person skilled in the art.

4, the first signal extraction module 310-1 of the remote unit 300 is a downlink signal including a plurality of downlink direction signals corresponding to each of a plurality of frequency bands transmitted from at least one or more base stations. May be received through at least a part of the first downlink path (DL Path 1). The first signal extraction module 310-1 of the remote unit 300 may extract a first downlink signal corresponding to the first frequency band from the received downlink signal. The first signal transmission module 330-1 of the remote unit 300 may transmit the extracted first downlink signal toward the terminal.

In addition, the first signal transmission module 330-1 of the remote unit 300 may receive an uplink signal including a plurality of uplink signals corresponding to each of a plurality of frequency bands transmitted from at least one terminal. . The first signal extraction module 310-1 of the remote unit 300 may extract a second uplink signal corresponding to a second band isolated from the first frequency band by a predetermined frequency or more from the received uplink signal. . The first signal extraction module 310-1 of the remote unit 300 may transmit the extracted second uplink signal to the base station through at least a part of the first uplink path (UL Path 1).

According to another embodiment, the second signal extraction module 310-2 of the remote unit 300 converts a third downlink signal corresponding to a third band transmitted from at least one base station to a second downlink path (DL Path). 2) can be received through. The second signal transmission module 330-2 of the remote unit 300 may transmit the received third downlink signal to the terminal. In addition, the second signal transmission module 330-2 of the remote unit 300 may receive a first uplink signal corresponding to a first band isolated from a third band transmitted from at least one terminal and a predetermined frequency or more. have. The second signal extraction module 330-2 of the remote unit 300 may transmit the received first uplink signal to the base station through a second uplink path (UL Path 2).

As described above, the method of extracting and servicing a signal of a specific frequency band from a downlink signal or an uplink signal, and a method of receiving and servicing a downlink signal and an uplink signal isolated over a certain frequency are simultaneously performed in one remote unit. It can also be implemented. According to the design of those skilled in the art, the remote unit only uses a method of extracting and servicing a signal of a specific frequency band from a downlink signal or an uplink signal, or receiving and serving a downlink signal and an uplink signal isolated over a certain frequency. It can also be used, it is natural that the two methods can also be used in combination.

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, an uplink signal obtained by extracting a signal of a specific frequency band from a plurality of uplink direction signals corresponding to each of a plurality of frequency bands and a plurality of A downlink signal obtained by extracting a signal of a specific frequency band from a plurality of downlink direction signals corresponding to each of the frequency bands of may be serviced by isolating a certain frequency band or more from each other through a single transmission path.

In the above description, each of the plurality of transmission paths includes a signal extraction module and is expressed as operating independently through this, but is not limited thereto, and a plurality of transmission paths share one signal extraction module according to the design of a person skilled in the art. It is natural that the present embodiment can be applied even in the case of the case.

In addition, an embodiment in which a plurality of transmission paths share one signal extraction module to change a transmission path according to a frequency band of a downlink signal or an uplink signal is also possible, which will be described in detail below.

5 is an exemplary diagram illustrating a service method of a distributed antenna system when at least one transmission path shares one signal extraction module according to various embodiments of the present disclosure.

Hereinafter, for convenience of description, the case of two transfer paths is described, but the present invention is not limited thereto, and it is natural that the number of transfer paths may be changed by design of a person skilled in the art.

In addition, for convenience of description, although the signal extraction module 310 and the signal transmission module 330 are expressed as being connected, the position of the signal extraction module 310 and the signal transmission module 330 is not limited thereto. It is natural that it can be changed by the design of a person skilled in the art.

5, the signal extraction module 310 of the remote unit 300 receives a first downlink signal corresponding to a first band transmitted from at least one base station through a first downlink path (DL Path 1). You can receive it. The signal allocation module 313 included in the signal extraction module 310 of the remote unit 300 may allocate the received first downlink signal to a second transmission path 2. The signal extraction module 310 of the remote unit 300 transmits the first downlink signal based on the allocated result by using the second signal transmission module 330-2 included in the second transmission path 2 It can be transmitted in the direction of the terminal.

In addition, the first signal transmission module 330-1 of the remote unit 300 may receive an uplink signal including a plurality of uplink direction signals corresponding to each of a plurality of frequency bands transmitted from at least one terminal. have. The signal extraction module 310 of the remote unit 300 may extract a second uplink signal corresponding to a second band isolated from the first band and a predetermined frequency or more from the received uplink signal. The signal allocation module 313 included in the signal extraction module 310 of the remote unit 300 may allocate the extracted second uplink signal as a second transmission path 2. The signal extraction module 310 of the remote unit 300 may transmit the second uplink signal to the base station using a second transmission path 2 based on the allocated result.

Here, the signal allocation module may allocate a transmission path according to a preset criterion. For example, a method of allocating a downlink signal and an uplink signal received through a first transmission path (Transfer Path 1) to a second transmission path (Transfer Path 2) may be a preset reference, and the first downlink path The downlink signal received through (DL Path 1) is allocated to the second signal transmission module 330-2, and the uplink signal received through the first signal transmission module 330-1 is a first uplink path (UL). The method of allocating with Path1) may be a preset standard. It is natural that the criteria allocated by the signal allocation module can be generated in various ways according to the design of a person skilled in the art.

As described above, the distributed antenna system and the service method of the distributed antenna system according to various embodiments of the present invention provide a service by separating an uplink signal and a downlink signal from each other by a predetermined frequency or more in one transmission path through a transmission path change. I can.

In addition, the signal allocation module may allocate a transmission path according to a predetermined analysis result. Hereinafter, a method of allocating a transmission path according to a predetermined analysis result will be described in detail.

The signal extraction module 310 of the remote unit 300 includes a downlink signal including a plurality of downlink signals corresponding to each of a plurality of frequency bands transmitted from at least one base station through a second downlink path (DL Path 2). Can receive signals. The signal extraction module 310 of the remote unit 300 may extract a second downlink signal corresponding to the second band from the downlink signal. The signal analysis module 311 included in the signal extraction module 310 of the remote unit 300 may analyze a transfer path for transmitting a second band, which is a frequency band of the second downlink signal. For example, the signal analysis module may analyze the characteristics of each of the plurality of transmission paths, compare the characteristics of each of the analyzed transmission paths with the second band, and calculate a result including information on a specific transmission path. . The signal allocation module 313 included in the signal extraction module 310 of the remote unit 300 transfers the second downlink signal to the first transmission path based on the analysis result of the signal analysis module 311. Can be assigned to. The second signal transmission module 330-2 of the remote unit 300 may transmit the second downlink signal to the terminal based on the allocated result.

In addition, the signal extraction module 310 of the remote unit 300 is a second band transmitted from at least one terminal through the second signal transmission module 330-2 and a third band corresponding to a third band isolated by a predetermined frequency or more. 3 Can receive uplink signals. The signal analysis module 311 included in the signal extraction module 310 of the remote unit 300 analyzes the characteristics of each of the plurality of transmission paths in order to transmit the third band, which is the frequency band of the third uplink signal, A result including information on the second transmission path (Transfer Path2) may be calculated by comparing the characteristics of each of the analyzed transmission paths with the third band. The signal allocation module 313 included in the signal extraction module of the remote unit 300 allocates the third uplink signal to the second transmission path 2 based on the analysis result of the signal analysis module 311. I can. The signal extraction module 310 of the remote unit 300 may transmit the third uplink signal to the base station through the second uplink path (UL Path2) based on the allocated result.

In this embodiment, for convenience of explanation, the signal analysis module is expressed by comparing the characteristics of each of the plurality of transmission paths and the frequency band of the signal, but is not limited thereto, and transmits signals in various ways according to the design of a person skilled in the art. It is natural that you can analyze the path to do it.

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, by analyzing each signal and changing the transmission path according to the analysis result, the uplink signal and the downlink signal are Signals can be serviced by separating them over a certain frequency.

6 is an exemplary diagram of a distributed antenna system to which a service method of a distributed antenna system according to various embodiments of the present invention is applied.

Referring to FIG. 6, the remote unit 300 may include a signal transmission module 330, an amplifier, a filter, a combiner (divider), and the like for each transmission path.

The remote unit 300 may receive a downlink signal corresponding to the 800Mhz band transmitted from the base station through a first transmission path (Transfer Path 1). The remote unit 300 may perform predetermined signal processing such as amplifying and filtering the received downlink signal. The first signal extraction module 310-1 of the remote unit 300 receives a downlink signal corresponding to the 800Mhz band subjected to signal processing, and transmits the received downlink signal through the first signal transmission module 330-1. It can be transmitted in the direction of the terminal.

The remote unit 300 generates an uplink signal including an uplink direction signal corresponding to 600Mhz band, an uplink direction signal corresponding to 700Mhz band, and an uplink direction signal corresponding to 900Mhz band transmitted from at least one terminal. 1 It can be received through the signal transmission module (330-1). The first signal extraction module 310-1 may extract an uplink signal corresponding to a 600Mhz band from the received uplink signal. The first signal extraction module 310-1 may process the extracted uplink signal corresponding to the 600Mhz band for a predetermined signal and then transmit it to the base station through a first transmission path 1.

The remote unit 300 transmits a downlink signal including a downlink direction signal corresponding to the 600Mhz band and a downlink direction signal corresponding to the 800Mhz band transmitted from at least one base station through a second transmission path (Transfer Path 2). You can receive it. The remote unit 300 may process a downlink signal with a predetermined signal. The second signal extraction module 310-2 of the remote unit 300 may extract a downlink signal corresponding to a 600Mhz band from a downlink signal subjected to a predetermined signal processing. The remote unit 300 may allocate a downlink signal corresponding to the extracted 600Mhz band to a third transmission path (Transfer Path 3). The remote unit 300 may transmit a downlink signal corresponding to the 600Mhz band to the terminal through the third signal transmission module 330-3 based on the allocation result.

The remote unit 300 may receive an uplink signal corresponding to the 900Mhz band transmitted from at least one terminal through the third signal transmission module 330-3. The remote unit 300 checks the characteristics of the second transmission path (Transfer Path 2) and the third transmission path (Transfer Path 3), and analyzes the characteristics of each path and the 900Mhz band to obtain a second transmission path (Transfer Path 2). Analysis results including information on can be calculated. The second signal extraction module 310-2 of the remote unit 300 may allocate an uplink signal corresponding to the received 900Mhz band as a second transmission path 2 according to the analysis result. The second signal extraction module 310-2 of the remote unit 300 performs a predetermined signal processing on the uplink signal corresponding to the 900Mhz band, and then establishes a second transmission path based on the allocated result. Can be used to transmit in the direction of the base station.

The remote unit 300 includes a downlink direction signal corresponding to 600Mhz band transmitted from at least one base station, a downlink direction signal corresponding to 700Mhz band, a downlink direction signal corresponding to 800Mhz band, and a downlink corresponding to 900Mhz band. A downlink signal including a direction signal may be received through a third transmission path (Transfer Path 3). The remote unit 300 may process the received downlink signal with a predetermined signal. The second signal extraction module 310-2 of the remote unit 300 may extract a downlink signal corresponding to a 900Mhz band from a downlink signal that has undergone a predetermined signal processing process. The remote unit 300 checks the characteristics of the second transmission path (Transfer Path 2) and the third transmission path (Transfer Path 3), analyzes the characteristics of each path and the 900Mhz band, and performs a third transmission path (Transfer Path 3). Analysis results including information on can be calculated. The second signal extraction module 310-2 of the remote unit 300 may allocate a downlink signal corresponding to the received 900Mhz band to a third transmission path 3 according to the analysis result. The remote unit 300 may transmit a downlink signal corresponding to the 900Mhz band to the terminal through the third signal transmission module 330-3 based on the allocation result.

The remote unit 300 may receive an uplink signal corresponding to the 800Mhz band transmitted from at least one terminal through the second signal transmission module 330-2. The second signal extraction module 310-2 of the remote unit 300 may allocate an uplink signal corresponding to the received 800Mhz band to a third transmission path 3. The second signal extraction module 310-2 of the remote unit 300 performs a predetermined signal processing on the uplink signal corresponding to the 800Mhz band, and then uses a third transmission path (Transfer Path 3) based on the allocated result. Thus, it can be transmitted in the direction of the base station.

The above-described frequency band and path configuration are only expressed for convenience of description, and are not limited thereto. It is natural that the frequency band, the configuration of the path, the number of paths, and the like may be changed according to the design of those skilled in the art.

7 is an exemplary diagram illustrating a frequency band allocated to each path of a distributed antenna system according to various embodiments of the present disclosure.

6 to 7, the remote unit 300 may receive a downlink signal of an 800Mhz band through a first downlink path (DL Path 1), and a first uplink path (UL Path 1). Through the 600Mhz band uplink signal can be transmitted. In addition, the remote unit 300 may receive a downlink signal of 600Mhz band through a second downlink path (DL Path 2), and an uplink signal of 900Mhz band through a second uplink path (UL Path 2). Can be transmitted. In addition, the remote unit 300 may receive a downlink signal of 900Mhz band through a third downlink path (DL Path 3), and an uplink signal of 800Mhz band through a third uplink path (UL Path 3). Can be transmitted.

As described above, the distributed antenna system according to various embodiments of the present disclosure may transmit an uplink signal and a downlink signal that are isolated from each other in a predetermined frequency band in one path.

The above-described frequency band is expressed as a specific band for convenience of description, but is not limited thereto, and it is natural that it may be changed according to a design of a person skilled in the art.

8 is a flowchart of a service method of a distributed antenna system according to an embodiment of the present invention.

Referring to FIG. 8, the remote unit may receive a first downlink signal corresponding to the first band transmitted from the base station (S1000). The remote unit may transmit the first downlink signal corresponding to the received first band to the terminal through the transmission path (S2000).

In addition, the remote unit may receive a second uplink signal corresponding to the first band transmitted from the terminal and the second band isolated over a predetermined frequency (S1000). The remote unit may transmit a second uplink signal corresponding to the received second band to the base station through a transmission path (S2000).

According to an embodiment of the present invention, the remote unit may receive a downlink signal including a plurality of downlink signals corresponding to each of a plurality of frequency bands (S1000). The remote unit may extract a first downlink signal corresponding to the first band from the received downlink signal (S1010). The remote unit may transmit the first downlink signal corresponding to the extracted first band to the terminal through the transmission path.

In addition, the remote unit may receive an uplink signal including a plurality of uplink signals corresponding to each of a plurality of frequency bands transmitted from the terminal (S1000). The remote unit may extract a second uplink signal corresponding to a second band isolated from the first band and a predetermined frequency or more from the received uplink signal (S1010). The remote unit may transmit a second uplink signal corresponding to the extracted second band to the base station through a transmission path.

9 is a flowchart of a service method of a distributed antenna system according to another embodiment of the present invention.

Referring to FIG. 9, the remote unit may receive a first downlink signal corresponding to the first band transmitted from the base station (S1000). The remote unit may transmit the first downlink signal corresponding to the received first band to the terminal through the transmission path (S2000).

In addition, the remote unit may receive a second uplink signal corresponding to the first band transmitted from the terminal and the second band isolated over a predetermined frequency (S1000). The remote unit may transmit a second uplink signal corresponding to the received second band to the base station through a transmission path (S2000).

According to an embodiment of the present invention, the remote unit may receive a first downlink signal corresponding to the first band transmitted from the base station through the first transmission path (S1000). The remote unit may allocate the first downlink signal corresponding to the received first band to the second transmission path (S1030). The remote unit may transmit the first downlink signal corresponding to the first band to the terminal through the second transmission path according to the allocation result (S2000).

In addition, the remote unit may receive a second uplink signal corresponding to the first band transmitted from the terminal and the second band isolated over a predetermined frequency (S1000). The remote unit may allocate a second uplink signal corresponding to the received second band to the second transmission path (S1030). The remote unit may transmit a second uplink signal corresponding to the second band to the base station through the second transmission path according to the allocation result (S2000).

According to another embodiment of the present invention, the remote unit may receive a first downlink signal corresponding to the first band transmitted from the base station (S1000). The remote unit may analyze the characteristics of each of the first band and the plurality of transmission paths, which is the frequency band of the received first downlink signal (S1031). The remote unit may allocate the first downlink signal to the second transmission path according to the analysis result (S1030). The remote unit may transmit the first downlink signal corresponding to the first band to the terminal through the second transmission path according to the allocation result (S2000).

In addition, the remote unit may receive a second uplink signal corresponding to the first band transmitted from the terminal and the second band isolated over a predetermined frequency (S1000). The remote unit may analyze the characteristics of each of the second band and the plurality of transmission paths, which is the frequency band of the received second uplink signal (S1031). The remote unit may allocate the second uplink signal to the second transmission path according to the analysis result (S1030). The remote unit may transmit a second uplink signal corresponding to the second band to the base station through the second transmission path according to the allocation result (S2000).

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 5a~5n: Terminal
10: distributed antenna system 30: POI
50: NMS 100: main unit
200: hub unit 300a to 300n: remote unit
310: signal extraction module 311: signal analysis module
313: signal allocation module 330: signal transmission module

Claims (14)

In the subsystem included in the distributed antenna system,
In a downlink signal including a downlink direction signal corresponding to each of at least one or more frequency bands, a first downlink signal corresponding to a first band is received,
In an uplink signal including an uplink direction signal corresponding to each of at least one or more frequency bands, a second uplink signal corresponding to a second band isolated from the first band by a predetermined frequency or more is received, and the second uplink signal A signal extraction module for transmitting a link signal in an uplink direction through a first transmission path; And
A signal transmission module for transmitting the first downlink signal in a downlink direction through the first transmission path;
Including,
In the signal extraction module, each of a plurality of transmission paths in a state capable of transmitting the first downlink signal and the second uplink signal includes a first downlink signal and a second uplink signal having a predetermined frequency or higher. Allocating the first transmission path to transmit in isolation,
Subsystem.
The method of claim 1,
The signal extraction module,
Receiving the downlink signal including a plurality of downlink direction signals corresponding to each of a plurality of frequency bands, and extracting the first downlink signal corresponding to the first band from among the received downlink signals,
Subsystem.
The method of claim 1,
The distributed antenna system includes the plurality of transmission paths,
The signal extraction module,
A signal allocation module for allocating the received first downlink signal to the first transmission path among the plurality of transmission paths
Including,
The signal transmission module,
Transmitting the first downlink signal through the assigned first transmission path,
Subsystem.
The method of claim 3,
The signal extraction module,
A signal analysis module for searching a transmission path for transmitting the first band, which is a frequency band of the first downlink signal, based on characteristics of each of the plurality of transmission paths;
Including more,
The signal allocation module,
Allocating the first downlink signal to the first transmission path based on a result of searching the transmission path,
Subsystem.
The method of claim 1,
The signal extraction module,
Receiving the uplink signal including a plurality of the uplink direction signals corresponding to each of a plurality of frequency bands, and corresponding to the second band isolated from the first band and a predetermined frequency or more among the received uplink signals Extracting the second uplink signal and transmitting the extracted second uplink signal through the first transmission path,
Subsystem.
The method of claim 1,
The distributed antenna system includes the plurality of transmission paths,
The signal extraction module,
Signal allocation module for allocating the received second uplink signal to the first transmission path
Including,
The signal extraction module,
Transmitting the second uplink signal through the first transmission path,
Subsystem.
The method of claim 6,
The signal extraction module,
A signal analysis module for searching a transmission path for transmitting the second band, which is a frequency band of the second uplink signal, based on characteristics of each of the plurality of transmission paths;
Including more,
The signal allocation module,
Allocating the second uplink signal to the first transmission path based on a result of searching the transmission path,
Subsystem.
Receiving a first downlink signal corresponding to a first band from a downlink signal including a downlink direction signal corresponding to each of at least one or more frequency bands;
Receiving a second uplink signal corresponding to a second band isolated from the first band by a predetermined frequency or more from an uplink signal including an uplink direction signal corresponding to each of at least one frequency band;
Each of the plurality of transmission paths in a state capable of transmitting the first downlink signal and the second uplink signal is configured to transmit the first downlink signal and the second uplink signal by separating the first downlink signal and the second uplink signal by a predetermined frequency or more. 1 allocating a transmission path;
Transmitting the second uplink signal in an uplink direction through the first transmission path; And
Transmitting the first downlink signal in a downlink direction through the first transmission path
Containing,
Distributed antenna system service method.
The method of claim 8,
Receiving the first downlink signal,
Receiving the downlink signal including the downlink direction signal corresponding to each of a plurality of frequency bands,
Extracting the first downlink signal corresponding to the first band from among the received downlink signals
Containing,
Distributed antenna system service method.
The method of claim 8,
The distributed antenna system includes the plurality of transmission paths,
Allocating the received first downlink signal to the first transmission path;
Including more,
Transmitting through the first transmission path,
Transmitting the first downlink signal through the assigned first transmission path,
Distributed antenna system service method.
The method of claim 10,
Allocating the first downlink signal to the first transmission path,
Searching for a transmission path for transmitting the first band, which is a frequency band of the first downlink signal, based on characteristics of each of the plurality of transmission paths;
Allocating the first downlink signal to the first transmission path based on a result of searching the transmission path
Containing,
Distributed antenna system service method.
The method of claim 8,
Transmitting the second uplink signal through the first transmission path,
Receiving the uplink signal including the uplink direction signal corresponding to each of a plurality of frequency bands; and
Extracting the second uplink signal corresponding to the second band isolated from the first band from among the received uplink signals by a predetermined frequency or more; and
Transmitting the extracted second uplink signal through the first transmission path
Containing,
Distributed antenna system service method.
The method of claim 8,
The distributed antenna system includes the plurality of transmission paths,
Transmitting the second uplink signal through the first transmission path,
Allocating the received second uplink signal to the first transmission path; and
Transmitting the second uplink signal through the assigned first transmission path
Containing,
Distributed antenna system service method.
The method of claim 13,
Allocating the received second uplink signal to the first transmission path,
Searching for a transmission path for transmitting the second band, which is a frequency band of the second uplink signal, based on characteristics of each of the plurality of transmission paths; and
Allocating the second uplink signal to the first transmission path based on a result of searching for the transmission path,
Distributed antenna system service method.

Images