WO2014010794A1

WO2014010794A1 - System and method for providing wireless network according to cell reconstruction

Info

Publication number: WO2014010794A1
Application number: PCT/KR2012/009907
Authority: WO
Inventors: 김형중; 곽도영; 이종식
Original assignee: 주식회사 케이티
Priority date: 2012-07-12
Filing date: 2012-11-22
Publication date: 2014-01-16
Also published as: KR101472575B1; KR20140010522A

Abstract

According to the present invention for providing a wireless network, a managing server receives traffic information on a radio unit group from a data unit, and, when receiving connection configuration information on the radio unit group from a remote hub unit, determines whether to separate one or more radio unit group(s) forming one cell on the basis of the traffic information or to set one radio unit group which forms one cell by combining a plurality of radio unit groups. The managing server transmits, to the remote hub unit, cell separation information or cell combination information generated on the basis of the determined result and requests a service to be provided to a terminal by means of a changed cell.

Description

System and method for providing wireless network according to cell reconfiguration

The present invention relates to a system and method for providing a wireless network according to cell reconfiguration.

Recently, as communication services change from voice-centric to data-centric, users are demanding more traffic than in the past. In order to satisfy the needs of these users, the cell radius of the base station is gradually set smaller, and the solution of sharing and distributing resources such as cloud communication system is the core of the network construction method.

The network construction method in the in-building environment includes a method using a repeater or femtocell using a radio frequency cable in the past. Recently, in building an inbuilding network, a neutral hosting method of establishing a common network and providing a service to a plurality of communication providers has been attracting attention. In order to apply the neutral hosting method to a cloud communication system, a RU (Radio Unit) that integrates wireless signals of a plurality of mobile operators and a Remote Hub Unit (RHU) for digitally converting optical signals for each operator's frequency band ), An optical link between the RU and the RHU is required.

In this architecture, network components except for data units (DUs) are jointly used by mobile operators, and in the case of forward (DU → RU), RHU receives wireless signals of each operator DU and binds them into broadband single band signals. send. In the reverse case, the wideband signal transmitted from the RU is filtered for each operator and then transmitted to each operator's DU.

When introducing such an in-building cloud network structure, since it is impossible to increase the wireless capacity of each carrier, there is a disadvantage that it is impossible to effectively respond to the traffic environment. That is, even if an individual communication provider generates traffic exceeding its own frequency radio capacity, it is impossible to increase its own radio capacity.

Accordingly, the present invention relates to a system and method for providing a wireless network according to cell reconfiguration, and more particularly, to a system and method for providing a wireless network that can accommodate different traffic for each operator / service in an in-building cloud network.

Wireless network providing system which is one feature of the present invention for achieving the technical problem of the present invention,

A radio unit group which is a pair of a main radio unit for processing a radio signal and a cascade radio unit connected to the main radio unit to perform a relay function, and the plurality of radio unit groups form a plurality of cells to form a terminal in a cell area A radio unit for providing services to the; A management server for monitoring the traffic occurring in the radio unit group and controlling to provide a wireless network by changing a cell shape through combining or separating radio group groups forming the cell based on the traffic amount; A remote hub unit interworking with the radio unit and the management server and changing the multiplexing of radio signals provided to the radio unit based on the information generated by the management server to transmit the radio unit to the radio unit whose cell shape is changed; And a data unit transferring information generated by the management server to the remote hub unit or transferring information collected by the remote hub unit to the management server, wherein at least one data unit is connected to one radio unit to process data information. It includes.

The management server may include: a traffic monitoring unit configured to receive traffic information of the radio unit group or the traffic information of the cell-forming radio unit group transmitted from the data unit or to provide the data unit with the traffic information of the radio unit; Based on the traffic information of the radio unit group received by the traffic monitoring unit and the connection shape information of the radio unit group received from the remote hub unit, it is determined whether to divide or merge the cells by dividing or combining the radio unit groups. A cell division / merge determination unit which generates shape information and transmits the shape information to the data unit; And a cell shape information storage unit configured to store cell shape information determined as an auxiliary radio unit group among the radio unit groups, and provide auxiliary radio unit information when cell merging or cell division is performed by the cell division / merge determination unit.

The remote hub unit is configured to transmit connection shape information of the radio unit group to the management server or to receive a radio signal multiplexing change request signal transmitted from the data unit based on cell shape information set by the management server. An information receiving unit; And a multiplexer configured to receive a radio signal multiplexing change request signal received by the cell shape information receiver, and to change and process multiplexing of a radio signal transmitted to the radio unit based on the received signal.

The data unit may include: a cell information generation unit configured to receive cell shape information transmitted from the management server and generate cell information for an auxiliary radio unit group; And requesting a multiplexing change to the remote hub unit, including cell information for the auxiliary radio unit group generated by the cell information generation unit, or receiving a multiplexing change completion message according to the requested multiplexing change request from the remote hub unit. It may include a multiplexed change request unit for transmitting to the management server.

The radio unit comprises: a signal receiving unit for receiving a signal in which two streams transmitted to the radio unit and the cascade radio unit transmitted from the remote hub unit are combined; And processing and providing a stream of a signal for providing a service to a terminal in a cell region among the signals received by the signal receiving unit, or generating a stream transmitted from a cascade radio unit and a stream of the radio unit as one signal and then generating the signal. It may include a signal processor for transmitting to the receiver.

In the radio unit, the radio unit and the radio unit group including the cascade radio unit may form a cell to provide the same service to a terminal, and the radio unit and the cascade radio unit are separated from each cell. By forming a, it is possible to provide different services to the terminal, respectively.

In the wireless network providing system, a plurality of management servers are each connected to a plurality of data units, the plurality of data units are connected to one remote hub unit, and the one remote hub unit is connected to one radio unit. Connected, different frequency bands may be allocated so that the plurality of management servers can use the one radio unit.

Wireless network providing method which is another feature of the present invention for achieving the technical problem of the present invention,

A method for providing a wireless network according to cell reconfiguration by a network providing system,

A management server constituting the network providing system receiving traffic information of a radio unit group from a data unit linked to the management server, and receiving connection shape information of the radio unit group from a remote hub unit; Determining whether to separate one or more radio unit groups forming one cell based on the traffic information, or to combine a plurality of radio unit groups into a radio unit group forming one cell; And transmitting the cell division information or the cell combining information generated based on the determination to the remote hub unit, and requesting to provide a service to the terminal through the changed cell.

The determining may include receiving an overload cell event from the one or more radio unit groups that formed the cell from the data unit when the one or more radio unit groups form one cell; And determining to separate a preset auxiliary radio unit group of the one or more radio unit groups from the radio unit group forming the cell.

The requesting to provide the service may include generating cell splitting information including shape information for the auxiliary radio group determined to be separated; Transmitting the cell division information to the remote hub unit, requesting a multiplexing change of a radio signal; And receiving a change complete signal indicating that the multiplexing change of the radio signal transmitted from the remote hub unit is completed.

After receiving through the digital unit, requesting the digital unit the traffic information generated in the radio unit groups after the division of the radio unit group; Receiving traffic level report information transmitted from radio unit groups after partitioning from the digital unit; And determining whether to adjust the coverage of the divided cell based on the received traffic level report information.

The determining may comprise: receiving one or more radio unit groups from each of the one or more radio unit groups, each cell forming one cell, and one or more radio unit groups forming each cell from the data unit; And determining, among the one or more radio unit groups, to generate a radio unit group, which is preset as an auxiliary radio unit, as a radio unit group which forms one cell by combining with another radio unit group.

The providing of the service may include: generating cell combining information including shape information about the auxiliary radio group; Transmitting the cell combining information to the remote hub unit to request multiplexing change of a radio signal; And receiving, via the digital unit, a change complete signal indicating that the multiplexing change of the radio signal transmitted from the remote hub unit is completed.

The radio unit group may be configured as a pair of a main radio unit for processing a radio signal and a cascade radio unit connected to the mail radio unit to perform a relay function.

The connection shape information may include one or more pieces of information of main radio unit group information, auxiliary radio unit information, traffic amount flowing in the optical line, and bandwidth information of the optical line.

According to the present invention, it is possible to provide a suitable wireless capacity for each network leasing provider by supporting an adaptive cell shape change according to traffic level for each operator, thereby providing a competitive wireless network in a common network leasing business.

1 is an exemplary diagram of an inbuilding cloud network environment according to a first embodiment of the present invention.

2 is a structural diagram of a management server according to a first embodiment of the present invention.

3 is a structural diagram of a data server according to a first embodiment of the present invention.

4 is a structural diagram of a remote hub unit according to the first embodiment of the present invention.

5 is a flowchart illustrating a method for providing a wireless network according to a first embodiment of the present invention.

6 is a flowchart illustrating a method for providing a wireless network according to a second embodiment of the present invention.

7 is an exemplary diagram of an inbuilding cloud network environment according to a second embodiment of the present invention.

8 is a structural diagram of a radio unit according to a second embodiment of the present invention.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

Throughout the specification, when a part is said to "include" a certain component, it means that it can further include other components, without excluding other components unless specifically stated otherwise.

In the present specification, a terminal is a mobile station (MS), a mobile terminal (MT), a subscriber station (SS), a portable subscriber station (PSS), a user device (User). It may also refer to an Equipment (UE), an Access Terminal (AT), or the like, and may include all or some functions of a mobile terminal, a subscriber station, a portable subscriber station, a user device, and the like.

In the present specification, a base station (BS) is an access point (AP), a radio access station (Radio Access Station, RAS), a Node B (Node B), a base transceiver station (Base Transceiver Station, BTS), MMR ( Mobile Multihop Relay) -BS and the like, and may include all or part of functions such as an access point, a radio access station, a Node B, a base transceiver station, and an MMR-BS.

Hereinafter, a system and method for providing a wireless network in an inbuilding cloud network according to an embodiment of the present invention will be described with reference to the accompanying drawings.

As illustrated in FIG. 1, each operator management server 100 for a plurality of operators is connected one-to-one with a data unit 200 that processes a data signal when a service provider provides a service to a user. In addition, a plurality of data units for a plurality of operators share a single Remote Hub Unit (RHU) 300.

The remote hub unit 300 interworks with the radio unit 400, and one radio unit 400 forms a plurality of cells (hereinafter, referred to as a 'cell forming radio unit group') 410 to 430. It is divided into This allows operators to provide services to users by varying cell capacity independently in accordance with traffic levels in the carrier frequency bands given to them. In the embodiment of the present invention, when two or more radio unit groups form one radio unit group for convenience of description, it is referred to as a cell-forming radio unit group, but is not necessarily limited thereto.

In this case, the cell-forming radio unit groups 410 to 430 are allocated to different frequency domains according to a plurality of operators, and in FIG. 1, the radio unit 400 allocated to the first operator is divided into three cell-forming radio groups according to the traffic level. 410 to 430) are shown as an example. However, radio units are not necessarily assigned to three groups in this way.

The first operator management server 100-1 is a server for managing the first operator data unit 200-1 and monitors traffic generated from the radio unit group. The first operator management server 100-1 controls to separate or merge the cells generated by the cell-forming radio unit group as shown in FIG. 1 based on the monitored traffic amount. The radio unit 400 assigned to the first operator in three groups forms three service cells, each providing a service to the user terminal.

The first cell-forming radio unit group 410 is described with four radio units as an example. The first radio unit group 410-1 is referred to as a 'main radio unit group' and the second radio unit group 410-2 is referred to as an 'secondary radio unit group'. Herein, the first radio unit group 410-1 is set as the main radio unit group, and the second radio unit group 410-2 is set as an auxiliary radio unit group.

In addition, the auxiliary radio unit group refers to a radio unit group that can be divided from the cell-forming radio unit group to form an independent cell when the cell-forming radio unit group needs to separate a cell as traffic increases. In addition, the radio unit group is composed of one radio unit and a radio unit cascaded (cascade) to the radio unit (hereinafter referred to as 'cascade radio unit' for convenience of description) Will be explained.

Accordingly, the first cell-forming radio unit group 410 shown in FIG. 1 includes a first radio unit group 410-1 consisting of a first radio unit and a first cascade radio unit, and a second radio unit and a second cascade. The second radio unit group 410-2 consisting of radio units forms a single cell to provide services to users. The cascade radio unit performs the role of a repeater to extend cell coverage.

The structure of the operator management server (hereinafter, referred to as a "management server") 100 and the remote hub unit 300 in this network environment will be described with reference to FIGS. 2 and 3.

As shown in FIG. 2, the management server 100 includes a traffic monitoring unit 110, a cell division / merge determination unit 120, and a cell shape information storage unit 130.

The traffic monitoring unit 110 receives the traffic information of the radio unit group or the traffic information of the cell-forming radio unit group transmitted from the data unit 200. Here, the radio unit group is a radio unit forming the same cell, but the traffic monitoring unit 110 receives the traffic information from the data unit 200 according to a preset time, but is not necessarily limited thereto. In addition, the traffic monitoring unit 110 may request the data unit 200 to provide traffic information.

The cell division / merge determination unit 120 divides or merges cells based on the traffic information of the radio unit group received by the traffic monitoring unit 110 and the connection shape information of the radio unit group received from the remote hub unit 300. Determine whether or not. That is, it is determined to divide a cell for a cell in which an overload cell event has occurred, and a cell of a radio unit group in which a cell load drop event occurs is determined to merge with a cell of another radio unit group.

The cell shape information including the determined cell division or cell merge is generated and transmitted to the data unit 200. At this time, when dividing the cell, it is informed that the auxiliary radio unit group stored in the cell shape information storage unit 130 to be described later is divided into an independent radio unit group forming a new cell.

In addition, the cell division / merge determination unit 120 receives a change complete message indicating that the multiplexing change of the radio signal according to the cell change is completed from the data unit. According to the received change completion message, the management server 100 provides a new service to users through a new cell created through a radio unit, or forms a merged service to users by forming two or more cells into one cell. Can provide. Here, the connection shape information includes main radio unit information, auxiliary radio unit information, connection information indicating how the radio unit is connected, bandwidth information of an optical line, and the like.

In the embodiment of the present invention, the cell division / merge determination unit 120 is implemented with a self organizing network (SON) technology, which is a network for establishing a communication network that adapts itself to changes in traffic conditions of the surrounding environment and operators. It will be described, but is not necessarily limited to this. Along with this, the structures of the digital unit 200 and the remote hub unit 300 are also described using SON technology as an example.

The cell shape information storage unit 130 stores cell shape information that may be an auxiliary radio unit group among radio unit groups allocated by operators. This is to provide information when a plurality of radio unit groups form a radio unit group for forming a cell, and the cell division / merge determination unit 120 divides the information into independent radio unit groups according to traffic conditions. to be. In the embodiment of the present invention, since the radio unit includes all six radio unit groups, the cell shape information storage unit 130 is described with an example of storing cell shape information for six radio unit groups.

Next, a structure of the data unit 200 that processes data in connection with the management server 100 and the remote hub unit 300 or requests a multiplexing change to the remote hub unit 300 will be described with reference to FIG. 3. do.

As shown in FIG. 3, the data server 200 includes a cell information generation unit 210 and a multiplexing change request unit 220.

The cell information generation unit 210 receives the cell shape information transmitted from the cell division / merge determination unit 120 of the management server 100 to receive cell information for a secondary radio unit group (hereinafter referred to as 'cell information'). Create Here, the cell information includes auxiliary radio unit group information to be separated or combined according to a decision of the management server 100 and frequency band information of the corresponding auxiliary radio unit group.

The multiplexing change request unit 220 includes the cell information generated by the cell information generation unit 210 and requests the multiplexing change to the remote hub unit 300. When receiving the change completion message indicating that the multiplexing change is completed from the remote hub unit 300, the change is transmitted to the cell division / merge determination unit 120 of the management server 100.

In the embodiment of the present invention, only the components of the data unit 200 required for cell formation are shown, but may include components that perform the functions of the general data unit 200.

Next, the remote hub unit 300 that changes the cell shape of the radio unit 400 and combines radio signals based on the cell shape information determined by the management server 100 in association with the data unit 200 and the radio unit 400. The structure of will be described with reference to FIG. In the embodiment of the present invention, only the structure necessary for changing the cell shape is mentioned, but it is obvious that the structure for performing a function of a general remote hub unit is obvious, and a detailed description thereof will be omitted.

As shown in FIG. 4, the remote hub unit 300 includes a cell shape information receiver 310 and a multiplexer 320.

The cell shape information receiving unit 310 transmits connection shape information of a radio unit group to the management server 100 or a data unit connected to the management server 100 based on the cell shape information set by the management server 100 ( Receive a wireless signal multiplexing change request signal transmitted from 200). The connection shape information is collected and transmitted to the management server 100 by the cell shape information receiver 310 whenever a radio unit group is created or changed.

The radio signal multiplexing change request signal includes information on a radio frequency band and a radio unit to be split or merged. The cell shape information receiver 310 is controlled by the cell division / merge determination unit 120. Here, the multiplexing change request signal includes target radio unit group information to be divided or merged with frequency band information.

The multiplexer 320 receives the radio signal multiplexing change request signal received by the cell shape information receiver 310, and changes and processes multiplexing of the radio signals transmitted to the radio unit based on the multiplexer 320. In addition, a change completion message indicating that the multiplexing change is completed is transmitted to the data unit 200 to be delivered to the management server 100.

For example, if the cell shape information includes information for merging two conventionally independent cells into one cell, it is necessary to transmit the frequency bands transmitted to the independent radio unit groups to one radio unit group, that is, the auxiliary radio unit. Cell Formation into Groups A radio group merged into a radio unit group changes the radio multiplexing to operate in the relay mode. On the contrary, if the cell shape information includes information for dividing a cell into two independent cells, the radio signal can be transmitted to the two radio unit groups so that the independent auxiliary radio unit group operates in the sector mode in the role of the existing relay. To handle multiplexing changes.

A method of providing a wireless network by changing a cell shape based on traffic capacity of each service provider in the network environment described above will be described with reference to FIGS. 5 and 6. The first embodiment of FIG. 5 is a flowchart when traffic increases, and the second embodiment of FIG. 6 shows a flowchart when traffic decreases. The first embodiment of FIG. 5 will be described by taking a first radio unit group connected to the first data unit shown in FIG. 1 as an example.

5 is a flowchart illustrating a wireless network providing method according to a first embodiment of the present invention, and FIG. 6 is a flowchart illustrating a wireless network providing method according to a second embodiment of the present invention.

First, a network providing method for when traffic increases in an arbitrary cell-forming radio unit group will be described with reference to FIG. 5.

As illustrated in FIG. 5, the first data unit transmits traffic information generated in the first cell-forming radio unit group 410 to the management server 100 (S100). A detailed description of how the first data unit collects information on traffic generated in the first cell-forming radio unit group 410 will be omitted.

The cell shape information receiver 310 of the remote hub unit 300 transmits connection shape information of the first cell-forming radio unit group 410 to the management server 100 (S101). Here, the connection shape information of the first cell-forming radio unit group 410 includes main radio unit information, auxiliary radio unit information, connection information indicating how the radio unit is connected, bandwidth information of an optical line, and the like.

For example, since the main radio unit in FIG. 3 is the first radio unit group 410-1, the main radio unit information includes information about the first radio unit group 410-1. Since the auxiliary radio unit group in FIG. 1 is the second radio unit group 410-2, the auxiliary radio unit information includes information about the second radio unit group 410-2.

The traffic monitoring unit 110 of the management server 100 receives the traffic information of the first cell-forming radio unit group 410 from the data unit 200, and the cell division / merge determination unit 120 receives the remote hub unit ( Upon receiving the connection shape information of the first cell-forming radio unit group 410 from the cell 300, the cell division / merge determination unit 120 determines whether to divide the cell of the first cell-forming radio unit group 410. do. That is, since the first embodiment describes when traffic increases, for example, the cell division / merge determination unit 120 transmits to the first cell-forming radio unit group 410 from the traffic information received through step S100. It is confirmed that an overload cell event has occurred (S102).

Then, the cell division / merge determination unit 120 separates the first radio unit group 410-1 and the second radio unit group 410-2 of the first cell forming radio unit group 410 to separate two independent cells. Determine to form. Here, the method of determining whether the cell division / merge determination unit 120 separates and forms a cell may be performed in various ways. In the embodiment of the present invention, the secondary radio unit cell is described as an example. It is not limited together.

When the cell division / merge determination unit 120 determines to separate the cells, the cell separation shape information of the auxiliary radio unit stored in the cell shape information storage unit 130, that is, the second radio unit group 410-2. Information is transmitted to the data unit 200 (S103). The data unit 200 generates cell information for the auxiliary radio unit group based on the cell separation shape information of the auxiliary radio unit group received in step S103 (S104).

The wireless multiplexing change request signal is transmitted to the remote hub unit 300 requesting to change the multiplexing of the wireless signal based on the generated cell information for the auxiliary radio unit group (S105). The radio multiplexing change request signal includes information about a frequency band and a split target radio unit, that is, a second radio unit.

The multiplexer 320 of the remote hub unit 300 that receives the radio multiplexing change request signal transmitted from the data unit changes the multiplexing of the radio signal based on the received change request signal (S106). That is, two streams of radio signals transmitted to the first cell-forming radio unit group 410 are separated into two and are transmitted to the first radio unit group 410-1 and the second radio unit group 410-2, respectively. Change multiplexing to allow The multiplexing change method is already known, and detailed descriptions thereof will be omitted in the embodiments of the present invention.

The multiplexer 300 transmits a change complete signal indicating that the multiplexer has changed the multiplexing to the management server 100 via the data unit 200 (S107 and S108). At the same time, the first radio unit group 410-1 continuously provides a service provided to users through the existing first cell-forming radio unit group 410 (S109). However, the second radio unit group 410-2 separated from the first cell forming radio unit group 410 forms a new new cell, thereby providing a new service to users (S110).

Through the above procedure, the first cell-forming radio unit group 410 is divided into a cell area by the first radio unit group 410-1 and a cell area by the second radio unit group 410-2, and then managed. The traffic monitoring unit 110 of the server 100 requests traffic information of the first radio unit group 410-1 and the second radio unit group 410-2 from the data unit 200 (S111). This is to check whether an error occurs in providing services to users in the newly formed cell area and to adjust the coverage based on the error.

The data unit 200 transmits a traffic level report request message requesting to report the current traffic state to the first radio unit group 410-1 and the second radio unit group 410-2 (S112 and S113). . The traffic level report signals transmitted from the first radio unit group 410-1 and the second radio unit group 410-2 are respectively received (S114 and S115). Here, the traffic level report signal includes information such as a received signal strength indicator (RSSI) of the uplink, a radio signal output degree in a corresponding frequency domain, and a service call request call to the formed cell.

The data unit 200 manages the traffic level report signal for the traffic level of the first radio unit group 410-1 and the traffic level of the second radio unit group 410-2 received through steps S114 and S115. Transmit to 100 (S116). The cell division / merge determination unit 120 of the management server 100 that receives the traffic level report signal receives the first radio unit group 410-1 based on the information included in the traffic level report received by the traffic monitoring unit 110. In step S117, it is determined whether the coverage adjustment of the second radio unit group 410-2 is necessary.

For example, if an error occurs in providing a service to a user in a cell created by the first radio unit group 410-1, the management server 100 transmits to the first radio unit group 410-1. Decide to extend the cell's coverage by The management server 100 transmits the signal for the coverage adjustment instruction thus determined to the data unit 200 (S118), and the data unit 200 receiving the coverage adjustment instruction uses a method of adjusting pilot power down. By adjusting the coverage of the cell generated by the radio unit (S119). In this case, steps S111 to S119 may be selectively executed.

Meanwhile, a network providing method for when traffic is reduced will be described with reference to FIG. 6. Before describing FIG. 6, the first data unit 200 for the first operator has a state in which the first radio unit group 410-1 and the second radio unit group 410-2 maintain independent cells, respectively. This assumes that the service is being provided to users.

As illustrated in FIG. 6, the first data unit transmits traffic information generated in the first radio unit group 410-1 and the second radio unit group 410-2 to the management server 100 (S200). A detailed description of how the first data unit collects information on traffic generated in the first radio unit group will be omitted.

The cell shape information receiver 310 of the remote hub unit 300 transmits connection shape information between the first radio unit group 410-1 and the second radio unit group 410-2 to the management server 100. (S201). The traffic monitoring unit 110 of the management server 100 receives the traffic information of the first radio unit group 410-1 and the second radio unit group 410-2 from the first data unit 200, and transmits the cell. When the division / merge determination unit 120 receives the connection shape information of the first radio unit group 410-1 and the second radio unit group 410-2 from the remote hub unit 300, the cell division / merge determination is performed. The unit 120 determines whether to merge the cell generated by the first radio unit group 410-1 and the cell generated by the second radio unit group 410-2.

That is, since the second embodiment describes a case where the traffic is reduced by way of example, the cell division / merge determination unit 120 determines the first radio unit group 410-1 and the traffic information from the traffic information received through step S200. It is confirmed that a cell load drop event has occurred in the second radio unit group 410-2 (S202). Then, the cell division / merge determination unit 120 merges the first radio unit group 410-1 and the second radio unit group 410-2 to form one cell, that is, the first cell forming radio unit group 410. Determine to form the cell formed by.

When the cell division / merge determination unit 120 determines to merge the cells, the cell division / merge determination unit 120 transmits a cell merge request message to the data unit 200 (S203). In this case, the cell merge request message includes information indicating which radio unit of the first radio unit group 410-1 and the second radio unit group 410-2 is to be a secondary radio unit. In the embodiment of the present invention, setting the second radio unit group 410-2 as an auxiliary radio unit will be described as an example.

The data unit 200 transmits a radio multiplexing change request signal to the remote hub unit 300 requesting to change the multiplexing of the radio signal based on the cell merge request message received in step S203 (S204). The radio multiplexing change request signal includes information about a frequency band and a merging target radio unit, that is, a second radio unit.

The multiplexer 320 of the remote hub unit 300 that receives the radio multiplexing change request signal transmitted from the data unit changes the multiplexing of the radio signal based on the received change request signal (S205). That is, the streams of two radio signals that have been transmitted to the first radio unit group 410-1 and the second radio unit group 410-2 may be combined and transmitted to the first cell-forming radio unit group 410. Change the multiplexing so that it is.

When a change completion signal indicating that the multiplexing has been changed is transmitted to the data unit 200 (S206), the data unit 200 transmits the cell information generated by the existing second radio unit group 410-2. Delete (S207). This is because the second radio unit group 410-2 is merged into the auxiliary radio unit of the first radio unit group 410-1 to form one first cell forming radio unit group 410. Accordingly, the first radio unit group provides the same cell service as the service provided to the users through the existing first radio unit group.

After merging the cell area by the first radio unit group 410-1 and the cell area by the second radio unit group 410-2 to the cell by the first cell forming radio unit group 410 through the above procedure. The traffic monitoring unit 110 of the management server 100 requests the traffic information of the first radio unit group from the data unit 200 (S208). Data unit 200 is a traffic level report request message requesting to report the current traffic status to the first radio unit group 410-1 and the second radio unit group 410-2 merged into the first radio unit group. (S209 and S210), and receives the traffic level report signals transmitted from the first radio unit group 410-1 and the second radio unit group 410-2, respectively (S211 and S212).

The data unit 200 manages the traffic level report signal for the traffic level of the first radio unit group 410-1 and the traffic level of the second radio unit group 410-2 received through steps S211 and S212. Transmit to 100 (S213). The cell division / merge determination unit 120 of the management server 100 that receives the traffic level report signal may use the first radio unit group 410-1 or the traffic monitoring unit 110 based on the information included in the traffic level report. It is determined whether coverage adjustment of the second radio unit group 410-2 is necessary (S214).

The management server 100 transmits a signal for indicating a coverage adjustment to the data unit 200 (S215), and the data unit 200 having received the coverage adjustment instruction uses a radio frequency control method such as downgrading the pilot power. The coverage of the cell generated by the unit is adjusted (S216). In this case, steps S203 to S216 may be selectively executed.

The in-building cloud network environment according to the first embodiment described above has described a method of dividing or combining cells between radio units in which a plurality of radio units are connected to the remote hub unit 300 in a star manner. Next, a case of splitting or combining cells between radio units connected in a cascade manner will be described.

As shown in FIG. 7, each operator management server for a plurality of operators is connected one-to-one with a data unit used in providing a service in a corresponding provider. And multiple data units for multiple operators share one remote hub unit 300 'jointly. The remote hub unit 300 'cooperates with a radio unit, and one radio unit may be divided into a plurality of cell-forming radio unit groups 410-3 and 410-4 and provided to operators.

In this case, the cell-forming radio unit groups 410-3 and 410-4 are allocated to different frequency domains according to a plurality of operators. In FIG. An example of assigning to a group is shown. However, radio units are not necessarily assigned to three groups in this way.

The first operator management server 100 ′ is a server for managing the first operator data unit 200 ′ and monitors traffic generated from the radio unit. The first operator management server 100 ′ controls to separate or merge cells generated according to radio unit groups based on the amount of traffic monitored. Radio unit groups 410 to 430 allocated to the first operator in three groups form three cells to provide services to user terminals, respectively.

The first radio unit group 410-3 according to the second embodiment of the present invention will be described with an example that three radio units are configured unlike the first cell-forming radio unit group 410 according to the first embodiment. The first radio unit group is referred to as a 'main radio unit group' and the second radio unit group is referred to as a 'secondary radio unit group'. A radio unit group is composed of one radio unit and one to one radio unit cascaded to the radio unit.

The cascaded radio units perform the role of repeaters to expand cell coverage. In this case, the cascaded radio units may provide a service to a user by forming an independent cell like a cascaded radio unit of the second radio unit according to cell characteristics. That is, although the second radio unit is included in the first radio unit group as an auxiliary radio unit of the first cell-forming radio unit 410-3, the second cascade radio unit 410-4 cascaded with the second radio unit. ) Is not included in the first cell shaping radio unit group 410-3, and forms a cell independently to provide a service to a user.

In other words, when an overload occurs in a specific cell of the first operator, only a specific radio unit (a second cascade radio unit in FIG. 6) among a plurality of radio units providing a service in that cell receives traffic, and the remaining radio units Low traffic can occur. The total traffic of the first radio unit (radio unit # 1), the first cascade radio unit (radio unit # 1 '), and the second radio unit (radio unit # 2) is equal to the second cascade radio unit (radio unit # 2'). ), Set the cell to "Radio Unit # 1, Radio Unit # 1 ', Radio Unit # 2, Radio Unit # 2'", "Radio Unit # 1, Radio Unit # 1 ', Radio Unit # 2" + It is advantageous to separate into "Radio Unit # 2 '".

In this case, the cascade radio unit has independent radio resources, thus doubling the stream in the optical path. Therefore, when the remote hub unit 300 'transmits two streams to the radio unit # 2, the radio unit # 3, and the radio unit # 4 at the same time, the second radio unit and the second cascade radio unit process only the streams transmitted thereto. do. Conversely, in the case of uplink, when the second radio unit combines the stream transmitted from the second cascade radio unit and its stream to the remote hub unit 300 ′, the remote hub unit 300 ′ demultiplexes it. Each cell of the data unit is transferred.

The structure of the radio unit for this will be described with reference to FIG. Before describing FIG. 8, the second radio when the radio unit and the cascade radio unit do not generate one cell but generate separate cells such as the second radio unit and the second cascade radio unit shown in FIG. 7. The structure of a unit is demonstrated as an example.

As shown in FIG. 8, the radio unit 400 ′ includes a signal receiver 411 and a signal processor 412.

The signal receiver 411 receives a signal in which two streams transmitted to the radio unit and the cascade radio unit transmitted from the remote hub unit 300 are combined. The signal transmitted from the signal processor 412 is transmitted to the remote hub unit 300. The signal receiver 411 is implemented with a SON technology for receiving a control signal from the cell division / merge determination unit 120 of the management server 100 to form a flexible cell for each operator to control the operator's management server 100 '. Receiving will be described as an example.

The signal processor 412 processes only the stream to be used by the radio unit 400 'from the signal received by the signal receiver 411, and provides a service to users in the cell area formed by the radio unit 400'. If the radio unit including the signal processor 412 is not a cascade radio unit, the stream transmitted from the cascade radio unit and the stream of the radio unit itself are combined to generate a signal, and then transmitted to the signal receiver 411. The signal processor 412 may receive a control signal from the remote hub unit 300 ′, and select a stream corresponding to a sector served by the service provider from among wireless signal streams for each operator band flowing in the optical path of the radio unit.

Since the cell forming method according to the second embodiment of the present invention is the same as the cell forming method described in the first embodiment, a detailed description thereof will be omitted.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

Claims

A radio unit group which is a pair of a main radio unit for processing a radio signal and a cascade radio unit connected to the main radio unit to perform a relay function, and the plurality of radio unit groups form a plurality of cells to form a terminal in a cell area A radio unit for providing services to the;

A management server for monitoring the traffic occurring in the radio unit group and controlling to provide a wireless network by changing a cell shape through combining or separating radio group groups forming the cell based on the traffic amount;

A remote hub unit interworking with the radio unit and the management server and changing the multiplexing of radio signals provided to the radio unit based on the information generated by the management server to transmit the radio unit to the radio unit whose cell shape is changed; And

Data unit for transmitting the information generated by the management server to the remote hub unit or the information collected by the remote hub unit to the management server, at least one connected to one radio unit to process data information

Wireless network providing system comprising a.
The method of claim 1,

The management server,

A traffic monitoring unit for receiving the traffic information of the radio unit group or the traffic information of the cell-forming radio unit group transmitted from the data unit or requesting the data unit to provide the traffic information of the radio unit;

Based on the traffic information of the radio unit group received by the traffic monitoring unit and the connection shape information of the radio unit group received from the remote hub unit, it is determined whether to divide or merge the cells by dividing or combining the radio unit groups. A cell division / merge determination unit which generates shape information and transmits the shape information to the data unit; And

A cell shape information storage unit storing cell shape information determined as an auxiliary radio unit group among the radio unit groups and providing auxiliary radio unit information when a cell is merged or divided by the cell division / merge determination unit.

Wireless network providing system comprising a.
The method of claim 1,

The remote hub unit,

A cell shape information receiving unit which transmits connection shape information of the radio unit group to the management server or receives a radio signal multiplexing change request signal transmitted from the data unit based on cell shape information set by the management server; And

A multiplexer for receiving a radio signal multiplexing change request signal received by the cell shape information receiving unit and changing and processing the multiplexing of a radio signal transmitted to the radio unit based on the received signal;

Wireless network providing system comprising a.
The method of claim 1,

The data unit,

A cell information generation unit receiving cell shape information transmitted from the management server and generating cell information for an auxiliary radio unit group; And

Requesting the multiplexing change to the remote hub unit including the cell information for the auxiliary radio unit group generated by the cell information generation unit, or receiving and managing the multiplexing change completion message according to the requested multiplexing change request from the remote hub unit; Multiplexing change request unit to send to server

Wireless network providing system comprising a.
The method of claim 1,

The radio unit,

A signal receiving unit for receiving a signal in which two streams transmitted to the radio unit and the cascade radio unit are transmitted from the remote hub unit; And

The signal receiving unit processes and provides a stream of signals for providing a service to a terminal in a cell region among the signals received, or generates a stream transmitted from a cascade radio unit and a stream of the radio unit itself as one signal, and then the signal receiving unit Signal processing unit to transmit to

Wireless network providing system comprising a.
The method of claim 5,

The radio unit,

A radio unit group including the radio unit and the cascade radio unit may form one cell to provide the same service to a terminal.

The radio unit and the cascade radio unit is separated from each other to form a cell, the wireless network providing system that can provide different services to the terminal, respectively.
The method of claim 1,

The wireless network providing system,

A plurality of management servers are each connected to a plurality of data units, the plurality of data units are connected to one remote hub unit, the one remote hub unit is connected to one radio unit,

And a different frequency band is allocated so that the plurality of management servers can use the one radio unit.
A method for providing a wireless network according to cell reconfiguration by a network providing system,

A management server constituting the network providing system receiving traffic information of a radio unit group from a data unit linked to the management server, and receiving connection shape information of the radio unit group from a remote hub unit;

Determining whether to separate one or more radio unit groups forming one cell based on the traffic information, or to combine a plurality of radio unit groups into a radio unit group forming one cell; And

Transmitting cell division information or cell combining information generated based on the determination to the remote hub unit, and requesting to provide a service to the terminal through the changed cell;

Wireless network providing method comprising a.
The method of claim 8,

The determining step,

If the at least one radio unit group forms one cell,

Receiving an overload cell event from at least one radio unit group that has formed the cell from the data unit; And

Determining that a preset auxiliary radio unit group of the one or more radio unit groups is to be separated from the radio unit group forming the cell

Wireless network providing method comprising a.
The method of claim 9,

Requesting to provide the service,

Generating cell division information including shape information for the auxiliary radio group determined to be separated;

Transmitting the cell division information to the remote hub unit, requesting a multiplexing change of a radio signal; And

Receiving a change complete signal indicating that a multiplexed change of a radio signal transmitted from the remote hub unit is completed;

Wireless network providing method comprising a.
The method of claim 10,

After receiving via the digital unit,

Requesting traffic information generated in the radio unit groups after the division of the radio unit group to the digital unit;

Receiving traffic level report information transmitted from radio unit groups after partitioning from the digital unit; And

Determining whether to adjust coverage of the divided cell based on the received traffic level report information;

Wireless network providing method comprising a.
The method of claim 8,

The determining step,

The one or more groups of radio units each form one cell,

Receiving a cell load drop event from the group of one or more radio units that formed each cell from the data unit; And

Determining that, among the one or more radio unit groups, a radio unit group preset as an auxiliary radio unit is combined with another radio unit group to generate a radio unit group forming one cell;

Wireless network providing method comprising a.
The method of claim 12,

To provide the service,

Generating cell combining information including shape information for the auxiliary radio group;

Transmitting the cell combining information to the remote hub unit to request multiplexing change of a radio signal; And

Receiving, via the digital unit, a change complete signal informing that the multiplexing change of the radio signal transmitted from the remote hub unit is completed;

Wireless network providing method comprising a.
The method of claim 8,

The radio unit group comprises a pair of a main radio unit for processing a radio signal and a pair of cascade radio units connected to the mail radio unit to perform a relay function.
The method of claim 8,

The connection shape information includes at least one of main radio unit group information, auxiliary radio unit information, traffic amount flowing in the optical line, and bandwidth information of the optical line.