KR101437367B1 - Method and system for scheduling a mobile communication service - Google Patents

Abstract

In the present invention, a small base station (RAS) is installed for each layer in a large building, and small base stations of each layer are connected to a core network through an ACR, The base station manager sets offset and zone for each small base station and transmits the offset to each small base station based on the measured signal level and transmits the signal level to each small base station so that each small base station can perform offset- To a mobile communication service scheduling system and method.

A mobile communication service scheduling system according to the present invention includes: a radio access station (RAS) for converting transmission data into an RF signal, transmitting the measured data, measuring a level of an interference signal from neighboring cells, and transmitting the measured interference signal information; And transmitting the transmission data from the core network to the radio access station, generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information transmitted from the radio access station (RAS) And an access controller (ACR) for setting scheduling information for each radio access station (RAS) belonging to the interference group and transmitting the scheduling information to the radio access station (RAS), wherein the radio access station (RAS) The transmission data is scheduled.

According to the present invention, an ACR transmits scheduling information to each radio access station (RAS) using information on a user receiving a mobile communication service in a cell in a large building, RAS) performs scheduling based on the scheduling information, it is possible to minimize interference between cells in a large building.

In addition, in order to reduce interference between cells in a large building, frequency of use between adjacent cells is not used differently, so that efficiency of frequency usage is increased and a large number of users can be accommodated in the cell.

Further, even if the number of users is increased in each cell, the offset value of the scheduling information can be adjusted even if all the resources are used, so that deterioration of the performance of the mobile communication service in the large building can be prevented.

Mobile communication, scheduling, small base station, base station controller, ACR, RAS, core network, femtocell, offset, zone, preamble, OFDMA, data burst, downlink, symbol

Description

TECHNICAL FIELD The present invention relates to a mobile communication service scheduling system and a scheduling method,

The present invention relates to a mobile communication service scheduling system and method, and more particularly, to a mobile communication service scheduling system and method, in which a small base station (RAS) is installed for each layer in a large building having a plurality of layers, The mobile station measures the interference level of the neighboring cells in each of the small base stations and transmits them to the base station manager. Based on this, the base station manager calculates the offsets and zones according to each base station, To each of the small base stations so that each of the small base stations performs offset-based zone-specific scheduling, and a mobile communication service scheduling system and method.

Generally, a mobile communication service transmits a radio frequency (RF) signal from a base station, and a user receives a radio signal through a mobile communication terminal.

However, in a large city with a large number of buildings, when a user is located inside a building, a radio signal transmitted from the base station is diffracted by many buildings and may not be well received by the user's mobile communication terminal .

That is, there is a problem that system performance is insufficient to cover a room with a macro-type base station servicing a large outdoor area. In order to solve this problem, a femtocell-type small base station is being developed, and a radio access station (hereinafter referred to as RAS), which is a small base station, is installed in a large building, .

However, when a plurality of small base stations of a femtocell are installed in a building for such a mobile communication building service, a problem of interference between femtocells or femtocells and an external base station occurs very seriously, resulting in deterioration of performance at the cell boundary . That is, when a large number of RASs are installed in a building, there arises a problem that data transmitted from an arbitrary RAS is broken by interference due to transmission of the adjacent RAS.

In order to solve this problem, it is possible to solve the problem by changing the frequency band between adjacent cells. However, in this case, the number of usable frequency bands is reduced, thereby deteriorating the overall performance.

In order to solve the above-described problems, the present invention provides a small-sized base station (RAS) for each layer in a large building having a plurality of layers, a small base station of each layer being a core network, The interference level of the neighboring cell is measured and transmitted to the base station manager. Based on this, the base station manager sets offsets and zones for each small base station, Scheduling based on offsets, by which each small base station performs offset-based zone-by-zone scheduling.

According to an aspect of the present invention, there is provided a mobile communication service scheduling system including a radio access station for converting transmission data into an RF signal and transmitting the radio signal, measuring a level of an interference signal from a neighboring cell, RAS); And transmitting the transmission data from the core network to the radio access station, generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information transmitted from the radio access station (RAS) And an access controller (ACR) for setting scheduling information for each radio access station (RAS) belonging to the interference group and transmitting the scheduling information to the radio access station (RAS), wherein the radio access station (RAS) The transmission data is scheduled.

The scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS), and the offset value is represented by a symbol start number And the zone information is represented by the number of symbols.

In addition, the offset value and the zone information are set in consideration of the number of users or quality of service (QoS) level for each RAS.

Also, the radio access station (RAS) acquires the preamble-based signal strength received from the neighboring cell or the strength of a pilot signal in a data burst as the interference signal information.

In addition, the radio access station RAS transmits the interference signal information together with the preamble index or its own base station ID to the access controller (ACR).

In addition, the radio access station (RAS) does not transmit the interference signal information to the access controller (ACR) when the interference signal information has a value below a predetermined level.

Also, the access controller (ACR) resets the scheduling information when the number of users connected to the radio access stations (RAS) is added or the usage mode information is changed for each radio access station (RAS) .

In addition, when the data usage rate of the downlink requested by the user increases and the quality of service (QoS) can not be satisfied for each user, the radio access station (RAS) transmits a request message for releasing the scheduling information To the access controller (ACR).

Also, the access controller (ACR) transmits the release instruction of the scheduling information to the radio access station (RAS) or re-sets the scheduling information and transmits the reset information to the radio access station (RAS).

The ACR generates a new interference group and generates new scheduling information according to the changed interference group and transmits the new interference group to the RAS (RAS) .

According to another aspect of the present invention, there is provided a method for scheduling a mobile communication service, the method comprising: a radio access station (RAS) for converting transmission data into an RF signal and outputting the received data; (RAS) for measuring a level of an interference signal coming from a neighboring cell and generating interference signal information according to the level of the interference signal, To the access controller (ACR); (b) generating, by the access controller (ACR), an inter-cell interference group having an interference signal level equal to or higher than a predetermined level with respect to the interference signal information; (c) setting the scheduling information of the radio access station (RAS) belonging to the interference group by the connection controller (ACR); (d) the connection controller (ACR) transmitting the scheduling information to each of the radio access stations (RAS); And (e) the radio access station (RAS) scheduling the transmission data based on the scheduling information.

Also, the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS), and the offset value is a symbol start number And the zone information is represented by the number of symbols.

In addition, the offset value and the zone information are set in consideration of the number of users or the quality of service (QoS) level for each radio access station (RAS).

In the step (a), the radio access station (RAS) acquires the preamble-based signal strength received from the neighboring cell or the strength of a pilot signal in the data burst as the interference signal information do.

In the step (a), the radio access station (RAS) transmits the interference signal information together with a preamble index or its own base station ID to the access controller (ACR).

In addition, the step (a) does not transmit to the access controller (ACR) when the interference signal information of the radio access station (RAS) has a value lower than a certain level.

In addition, in the step (c), when a user is added for each of the radio access stations (RAS) or a change is made to the usage mode information for each of the radio access stations (RAS), each of the radio access stations The number of users per RAS is determined again.

In the step (e), the number of users whose RAS exceeds the scheduling information increases or the data usage rate of a downlink requested by the user increases, QoS) is not satisfied, a request message for releasing the scheduling information is transmitted to the access controller (ACR).

In step (e), the connection controller (ACR) transmits a release command of the scheduling information to the radio access station (RAS) according to the request message, or re-sets the scheduling information, RAS).

According to another aspect of the present invention, there is provided a connection controller (ACR) comprising: a communication unit for communicating with a core network or a plurality of radio access stations (RAS); A control unit configured to set scheduling information for each radio access station (RAS) based on interference signal information received from the plurality of radio access stations (RAS) and transmit the scheduling information to each radio access station (RAS); An interference group generation unit for generating interference groups between cells having interference signal levels of a predetermined level or higher based on the interference signal information; And a scheduling information setting unit for setting scheduling information for each radio access station (RAS).

The mobile communication terminal further includes a usage mode information DB storing usage mode information related to the idle state and the traffic state of the user terminal according to the RASs.

Here, the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS).

When the number of users connected to each of the radio access stations (RAS) is added or the usage mode information of each radio access station (RAS) is changed, the control unit controls the radio access station (RAS) The scheduling information is reset according to the scheduling information.

In addition, the control unit may be configured to, when receiving a request message for releasing the scheduling information from the radio access station (RAS), transmit the cancel command of the scheduling information to the radio access station (RAS) And transmits it to the radio access station (RAS).

When the level of the interference signal changes and the interference group needs to be changed, the control unit generates a new interference group through the interference group generation unit, and generates new scheduling information through the scheduling information generation unit And transmits it to the radio access station (RAS) through the communication unit.

According to another aspect of the present invention, there is provided a method for scheduling a mobile communication service of an access router (ACR) according to the present invention, the method comprising the steps of: receiving, by a radio access station (RAS) (ACR), comprising the steps of: (a) receiving interference signal information for neighboring cells from the radio access station (RAS); (b) generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information; (c) setting scheduling information for each radio access station (RAS) in the interference group; And (e) transmitting scheduling information for each radio access station (RAS) to each of the radio access stations (RAS).

According to another aspect of the present invention, there is provided a radio access station (RAS) comprising: a communication unit for communicating with an access controller (ACR) for transmitting transmission data or a mobile communication terminal in a cell; A control unit for converting the transmission data into an RF signal and transmitting the resultant data, measuring a level of an interference signal coming from neighboring cells and transmitting the measurement result as interference signal information, or scheduling the transmission data based on the scheduling information; An interference signal information generation unit for generating interference signal information by measuring a level of the interference signals received through the communication unit; A scheduling information storage for storing the scheduling information received from the access controller (ACR); And a scheduling execution unit that performs scheduling of the transmission data according to the scheduling information.

According to another aspect of the present invention, there is provided a method for scheduling a mobile communication service of a radio access station (RAS), the method comprising: a movement of a radio access station (RAS) receiving transmission data from an access controller (ACR) A method for scheduling a communication service, comprising the steps of: (a) measuring a level of an interference signal from a neighboring cell and transmitting the interference signal information to the access controller (ACR) according to the result; (b) receiving scheduling information from the access controller (ACR) after transmitting the interference signal information; And (c) scheduling the transmission data based on the received scheduling information.

Here, the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS), the offset value is represented by a symbol start number, (Zone) information is represented by the number of symbols.

According to another aspect of the present invention, there is provided a recording medium for use in a mobile communication service scheduling method of an access controller (ACR) for transmitting transmission data received from a core network to a plurality of radio access stations (RAS) The method comprising the steps of: (a) receiving interference signal information for neighboring cells from the radio access station (RAS); (b) generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information; (c) setting scheduling information for each radio access station (RAS) in the interference group; And (d) transmitting scheduling information for each radio access station (RAS) to each of the radio access stations (RAS).

According to another aspect of the present invention, there is provided a recording medium for recording a program for processing a mobile communication service scheduling method of a radio access station (RAS) that receives transmission data from an access control unit (ACR) (A) measuring a level of an interference signal coming from a neighboring cell and transmitting the interference signal information to the access controller (ACR) according to a result of the measurement; (b) receiving scheduling information from the access controller (ACR) after transmitting the interference signal information; And (c) scheduling the transmission data based on the received scheduling information.

Here, the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS).

The offset value is represented by a symbol start number, and the zone information is represented by the number of symbols.

According to the present invention, an ACR transmits scheduling information to each radio access station (RAS) using information about a user receiving a mobile communication service in a cell in a large building, and each radio access station (RAS) By performing scheduling based on the scheduling information, interference between cells in a large building can be minimized.

In addition, in order to reduce interference between cells in a large building, frequency of use between adjacent cells is not used differently, so that efficiency of frequency usage is increased and a large number of users can be accommodated in the cell.

Further, even if the number of users is increased in each cell, the offset value of the scheduling information can be adjusted even if all the resources are used, so that deterioration of the performance of the mobile communication service in the large building can be prevented.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings, wherein like reference numerals refer to the like elements throughout. Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings.

It is assumed that the embodiment of the present invention is applied to a portable Internet system capable of using a high-speed wireless Internet service at a low price while moving about a mobile communication service in a large building.

The portable Internet system can access various information and contents by accessing the Internet in a stationary environment of indoor and outdoor conditions, a moving environment of a walking speed and a medium to low moving level by using various types of portable terminals such as a notebook, a PDA, and a handheld PC Service. In addition, it is an IP (Internet Protocol) based wireless data system that provides mobility of 60 Km / h and has a downlink transmission rate of 24.8 Mbps and an uplink transmission rate of 5.2 Mbps with uplink and downlink asymmetric transmission characteristics.

In addition, the portable Internet system uses the frequency band of 2.3 GHz and uses a time division duplex (TDD) as a duplex scheme and a time division duplex (TDD) scheme as a multiple access scheme (Orthogonal Frequency Division Multiple Access (OFDMA)).

On the other hand, in order to provide the multimedia service requested by the service subscribers with the desired service quality on the portable Internet, QoS (Quality of Service) according to the demand of each user should be provided. IP-based Internet networks do not guarantee high quality because they provide Best Effort Service. Accordingly, an integrated service (IETE) proposed by the Internet Engineering Task Force (IETE) has been developed as a way to guarantee QoS.

A typical method for guaranteeing QoS is to use resource reservation parameters (Resource Reservation Protocol (RSVP)) to allocate network resources according to the demand of QoS, to manage the bandwidth according to the request of QoS, Quality parameters are used to ensure quality. However, such a conventional method requires the subscriber terminal, which is a client of the multimedia service, to directly participate in a complicated signal processing task for guaranteeing QoS, so that the burden to be borne by the subscriber terminal increases, The requirements of the subscriber terminal such as the memory, the central processing unit, and the peripheral device are increased.

In order to solve this problem, in the present invention, inter-layer handover is supported through ACR, and an interference signal level of a neighboring cell is measured in an RAS installed in each layer and transmitted to ACR. And sets an offset value and zone information for each RAS so as not to overlap with the interference group, and transmits the offset value and zone information to each RAS.

Therefore, each RAS performs scheduling of transmission data based on the offset value and zone information.

1 is a block diagram schematically illustrating a configuration of a mobile communication service scheduling system according to an embodiment of the present invention.

Referring to FIG. 1, a mobile communication service scheduling system 100 according to the present invention includes a core network 110, an ACR 120, and RASs 130 to 134.

The core network 110 is a backbone network for transmitting and receiving data of a mobile communication service and receives packet data from an external packet data service such as the Internet (not shown) and transmits the packet data to the ACR 120.

The ACR 120 is a base station controller of the portable Internet network and is an access controller that receives a plurality of RASs 130 to 134 and connects the RASs 130 to 134 or the RASs 130 to 134 and the core network 110 . The ACR 120 performs a handover control function between the RASs 130 and 134, a handover function between the ACRs, a handover function between the base station and the RASs 130 to 134, a packet routing function, and an internet connection function. Thus, the ACR 120 provides interlayer handover through communication with the RASs 130-134 of each layer.

In addition, the ACR 120 may determine whether the mobile communication terminals located in the cells of the respective RASs 130 to 134 are in an idle state or a traffic state, for a plurality of RASs 130 to 134 connected to the ACR 120, Mode information is stored in the database. That is, the ACR 120 stores terminal status information for each RAS 130 to 134 as a database.

In addition, the ACR 120 receives interference signal information from a plurality of RASs 130 to 134, and generates inter-cell interference groups having interference signal levels of a certain level or higher with respect to the received interference signal information. Then, the ACR 120 stores usage mode information for each RAS in the DB, and determines the number of users for each RAS in the interference group based on the usage mode information. The ACR 120 sets an offset value and zone information for the number of users in the interference group for each RAS 130 to 134 so as not to overlap with the interference group, (Zone) information to each RAS 130 to 134 as scheduling information.

The RASs 130 to 134 may be installed in one or more layers from the first floor to the second floor to the nth floor in the building, Converts the data into an RF signal, and transmits it to a mobile communication terminal in each layer.

The RASs 130 to 134 transmit the interference signal information that measures the interference signal level of the neighboring cell to the ACR 120 and then receive an offset value and zone information from the ACR 120 And performs scheduling of transmission data on the basis thereof.

2 is a diagram for explaining data resource allocation in an OFDMA mobile communication system to which an embodiment of the present invention is applied.

Referring to FIG. 2, an OFDMA-based mobile communication system such as WiMAX (WiBro) uses a resource allocation scheme as shown in FIG. 2 on the downlink. In Fig. 2, the horizontal direction indicates the number of OFDMA symbols and the vertical direction indicates the number of sub-channels.

In the OFDMA-based mobile communication system, a downlink for transmitting a data burst from the RAS 130 to a mobile communication terminal and an uplink for transmitting a data burst to the RAS 130 to 134 in the mobile communication terminal Link (Up Link) is used.

The type of signal used in the downlink is composed of preamble information, MAP information and data burst information. The preamble information is information for the mobile communication terminal to recognize its own cell, and the MAP information is information about the number of OFDMA symbols and the number of subchannels occupied by the data burst. The preamble information includes, for example, a preamble index or a base station ID.

In a downlink (DL) -map (MAP) in which data is transmitted from the RASs 130 to 134 to the mobile communication terminal, the ACR 120 uses subchannel offsets and OFDMA symbol offsets , The mobile communication terminal transmits a scheduling information to the RASs 130 to 134 indicating a starting point of a data burst to be received and designating the number of subchannels and the number of OFDMA symbols.

Each of the RASs 130 to 134 transmits a data burst including traffic data to a mobile communication terminal located in a cell controlled by the RAS 130 to 134 based on the scheduling information. Accordingly, the mobile communication terminal recognizes the location of its data in the downlink frame, and receives the traffic data by demodulating the data burst allocated to the mobile communication terminal.

3 is a block diagram schematically showing the internal structure of the ACR according to the present invention.

3, an ACR 120 according to the present invention includes a communication unit 310, a control unit 320, an interference group generating unit 330, a scheduling information setting unit 340, and a usage mode information DB (Data Base) 350).

The communication unit 310 performs communication with the core network 110 or the RASs 130 to 134.

The controller 320 sets scheduling information for each RAS 130 to 134 based on the interference signal information received from the RASs 130 to 134 and controls the RASs 130 to 134 to transmit the scheduling information.

The interference group generating unit 330 generates inter-cell interference groups having interference signal levels of a certain level or higher based on the interference signal information received from the respective RASs 130 to 134. That is, the interference group generator 330 generates an interference group for each preamble index whose interference signal level has a value equal to or higher than a certain level.

The scheduling information setting unit 340 determines the number of users for each RAS 130 to 134 in the interference group and sets an offset value and zone information corresponding to the number of users for each RAS 130 to 134 And generates it as scheduling information.

The use mode information DB 350 stores usage mode information on the number of users connected to each RAS 130 to 134 or the idle state or traffic state of the user terminal for each RAS 130 to 134 .

4 is a block diagram schematically showing the internal configuration of the RAS according to the present invention.

4, each of the RASs 130 to 134 includes a communication unit 410, a control unit 420, an interference signal information generation unit 430, a scheduling information storage unit 440, and a scheduling execution unit 450 ).

The communication unit 410 communicates with the ACR 120, or communicates with a mobile communication terminal or the like in the cell.

The control unit 420 converts the transmission data into an RF signal and transmits it, or measures the level of the interference signal coming from the neighboring cell and transmits it as interference signal information, or controls the transmission data to be scheduled based on the scheduling information.

The interference signal information generation unit 430 receives the interference signal from the neighboring cell through the communication unit 610 and measures the level of the interference signals to generate interference signal information.

The scheduling information storage unit 440 stores scheduling information received from the ACR 120, i.e., an offset value and zone information.

The scheduling execution unit 450 performs scheduling of the transmission data according to the scheduling information.

6 is a flowchart illustrating a mobile communication service scheduling method according to an embodiment of the present invention.

In the mobile communication service system 100 according to the present invention, one or more RASs 130 to 134 are installed for each layer in a building, and RASs 130 to 134 for each layer are allocated to a plurality of ACRs 120 The ACR 120 is connected to the core network 110 and performs the following operations.

Referring to FIG. 6, each of the RASs 130 to 134 is installed for each layer in the building, and then measures the level of the interference signal coming from the adjacent cell at power-on (S610). At this time, the interference signal may be a preamble-based signal strength transmitted from a neighboring base station or an intensity of a pilot signal in a data burst.

Therefore, each of the RASs 130 to 134 measures the level of the interference signal coming from the adjacent RAS cell, and includes the own base station ID, the base station ID, the preamble index, and the like in the measured interference signal level And transmits it to the ACR 120 (S620).

At this time, each of the RASs 130 to 134 divides the measured interference signal level by the preamble index or the base station ID, and transmits it to the ACR 120. The RAS 130-134 transmits the preamble index itself or the ACR 120, Lt; / RTI >

On the other hand, the ACR 120, which receives the interference signal level for each preamble index or base station ID from each RAS 130 to 134, generates an interference group for each preamble index in which the level of the mutual interference signal is equal to or greater than a certain level (S630) . That is, the ACR 120 generates inter-cell interference groups having interference signal levels of a certain level or higher.

Next, the ACR 120 determines the number of users for each RAS 130 to 134 in the interference group (S640). That is, since ACR 120 stores usage mode information for each RAS 130 to 134 in the database, the number of users for each RAS in the interference group is determined based on the usage mode information.

The ACR 120 sets offset and zone information as shown in FIG. 5 for the number of users for each RAS in the interference group (S650).

The ACR 120 may set an offset for each RAS for a (27-1-M) symbol except for the preamble 1 symbol and the M symbol used for the MAP, when 27 symbols are used in the downlink, for example. 5 is a diagram illustrating an example in which the ACR sets offset and zone information for each RAS in an interference group. As shown in FIG. 5, the ACR 120 transmits a first offset (Offset1) and a first zone (Zone1) to the RAS1 so that the ACS 120 does not overlap the offset and the zone for each RAS included in the interference group Sets a second offset (Offset2) and a second zone (Zone2) for RAS2, and sets a third offset (Offset3) and a third zone (Zone3) for RAS3. At this time, the ACR 120 can set offset and zone information considering the number of connected users and the required QoS level for each RAS. In the case of WiMAX, an offset can be represented by a symbol start number as shown in FIG. 2, and a zone can be expressed by the number of symbols as shown in FIG.

The ACR 120 transmits the set offset and zone information to each of the RASs 130 to 134 included in the interference group among the RASs connected to the ACR 120 (S660).

The ACR 120 performs step S640 of setting the number of users for each RAS in the interference group when the number of users for each RAS increases or the usage mode information for each RAS is changed in the interference group (S662).

Each of the RASs 130 to 134 receives the offset and zone information from the ACR 120, and performs scheduling for the data bursts based on the offset (S670).

Each RAS 130-134 can send a request to the ACR 120 to cancel the offsets if an abnormal condition, e.g., a data rate of the downlink requested by the user, S672). If there is a change in the level of the interference signal received from the neighboring cell (S674), the interfering signal level is transmitted to the ACR 120 again by performing the step S610 of measuring the interference signal level of the neighboring cell.

The RASs 130 to 134 may request the ACR 120 to cancel the offset even when there is an increase in the number of users exceeding the offset and zone information received from the ACR 120. [

The ACR 120 may reset the offset and the zone information to be transmitted to the RASs 130 to 134 or may transmit the offset release command to the RASs 130 to 134 Lt; / RTI >

As described above, according to the present invention, a small base station (RAS) is provided for each layer in a large building composed of a plurality of layers, and small base stations of each layer are connected to the core network through a base station controller (ACR) The small base station measures the interference signal level of the neighboring cell and transmits it to the base station manager. In the base station manager, the offset and the zone for each small base station are set and transmitted to each small base station, Based zone-by-zone scheduling in accordance with the present invention.

It will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the spirit and scope of the present invention as defined by the following claims and their equivalents. Only. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents are to be construed as being included within the scope of the present invention do.

The present invention can be applied to a wireless communication system installed in a multi-layered building.

Further, the present invention can be applied to a wireless communication system in which a small base station of a femtocell type is installed in a plurality of layers in a building.

Further, the present invention can be applied to a wireless communication system using a communication method such as WCDMA, CDMA, WiBro, etc. in a plurality of layers in a building.

1 is a block diagram schematically showing a configuration of a mobile communication service scheduling system according to an embodiment of the present invention;

2 is a view for explaining data resource allocation in an OFDMA mobile communication system to which an embodiment of the present invention is applied,

FIG. 3 is a schematic view showing the internal structure of the ACR according to the present invention,

FIG. 4 is a block diagram schematically showing an internal configuration of a RAS according to the present invention,

5 is a diagram illustrating an example in which an ACR sets offset and zone information for each RAS in an interference group, and

6 is a flowchart illustrating a mobile communication service scheduling method according to an embodiment of the present invention.

Description of the Related Art

100: mobile communication service scheduling system 110: core network

120: ACR 130 to 134: RAS

310 communication unit 320 control unit

330: interference group generation unit 340: scheduling information setting unit

350: use mode information DB 410:

420: Control section 430: Interference signal information generating section

440: Scheduling information storage unit 450: Scheduling execution unit

Claims (36)

A radio access station (RAS) for converting transmission data into an RF signal and transmitting the measured data, measuring a level of an interference signal coming from neighboring cells, and transmitting the measured interference signal information; And Receiving the transmission data from the core network and transferring the transmission data to the radio access station, generating inter-cell interference groups having interference signal levels of a predetermined level or higher with respect to the interference signal information transmitted from the radio access station (RAS) And an access controller (ACR) for setting scheduling information for each radio access station (RAS) belonging to an interference group and transmitting the scheduling information to the radio access station (RAS) And the radio access station (RAS) schedules the transmission data based on the scheduling information. delete delete delete delete delete delete delete delete delete delete A radio access station (RAS) for converting transmission data into an RF signal and outputting the converted data; and an access controller (ACR) for receiving the transmission data from the core network and transmitting the data to the radio access station In this case, (a) measuring a level of an interference signal coming from a neighboring cell of the radio access station (RAS) and transmitting interference signal information according to the level of the interference signal to the access controller (ACR); (b) generating, by the access controller (ACR), an inter-cell interference group having an interference signal level equal to or higher than a predetermined level with respect to the interference signal information; (c) setting the scheduling information of the radio access station (RAS) belonging to the interference group by the connection controller (ACR); (d) the connection controller (ACR) transmitting the scheduling information to each of the radio access stations (RAS); And (e) scheduling the transmission data by the radio access station (RAS) based on the scheduling information; The mobile communication service scheduling method comprising: 13. The method of claim 12, Wherein the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS). 14. The method of claim 13, Wherein the offset value is represented by a symbol start number and the zone information is represented by a number of symbols. 14. The method of claim 13, Wherein the offset value and the zone information are set in consideration of a number of users or a quality of service (QoS) level for each radio access station (RAS). delete delete 13. The method of claim 12, Wherein the step (a) does not transmit the interference signal information to the access controller (ACR) when the interference signal information in the radio access station (RAS) has a value below a predetermined level. Service scheduling method. 13. The method of claim 12, The method of claim 1, wherein, in the step (c), when a user is added for each of the radio access stations (RAS) or a change occurs in usage mode information for each radio access station (RAS) ), And sets the scheduling information according to the determined number of users. delete 19. The method of claim 18, In step (e), the connection controller (ACR) transmits a release command of the scheduling information to the radio access station (RAS) according to a request message for releasing the scheduling information, or resets the scheduling information, To the access station (RAS). A communication unit for communicating with a core network or a plurality of radio access stations (RAS); A control unit configured to set scheduling information for each radio access station (RAS) based on interference signal information received from the plurality of radio access stations (RAS) and transmit the scheduling information to each radio access station (RAS); An interference group generation unit for generating interference groups between cells having interference signal levels of a predetermined level or higher based on the interference signal information; And A scheduling information setting unit configured to set scheduling information for each of the radio access stations (RAS); Lt; / RTI > 23. The method of claim 22, Wherein the scheduling information includes an offset value and zone information of an OFDMA downlink symbol for each radio access station (RAS). 23. The method of claim 22, A usage mode information DB storing usage mode information related to the idle state or the traffic state of the user terminal for each wireless access station (RAS); ≪ / RTI > 23. The method of claim 22, Wherein the control unit controls the scheduling information setting unit to set the number of users connected to each of the radio access stations RAS by the number of users connected to the radio access stations RAS, And resets the scheduling information. delete 23. The method of claim 22, Wherein the control unit generates a new interference group through the interference group generating unit and generates new scheduling information according to the new interference group through the scheduling information generating unit when the level of the interference signal changes and the interference group needs to be changed, To the radio access station (RAS) through a communication unit. A mobile communication service scheduling method of an access controller (ACR) for transmitting transmission data received from a core network to a plurality of radio access stations (RAS) connected to the core network, (a) receiving interference signal information for a neighboring cell from the radio access station (RAS); (b) generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information; (c) setting scheduling information for each radio access station (RAS) in the interference group; And (d) transmitting scheduling information for each radio access station (RAS) to each of the radio access stations (RAS); (ACR). ≪ / RTI > delete delete delete delete 1. A recording medium on which a program for processing a mobile communication service scheduling method of an access controller (ACR) for transmitting transmission data received from a core network to a plurality of radio access stations (RAS) (a) receiving interference signal information for a neighboring cell from the radio access station (RAS); (b) generating inter-cell interference groups having interference signal levels higher than a predetermined level with respect to the interference signal information; (c) setting scheduling information for each radio access station (RAS) in the interference group; And (d) transmitting scheduling information for each radio access station (RAS) to each of the radio access stations (RAS); Is recorded on the recording medium. delete delete delete

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