JP5306293B2 - Wireless communication system - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To obtain a radio communication system performing self-optimization of a cell with simple mechanism. <P>SOLUTION: A radio communication system of the invention comprises: a plurality of base stations 3 accommodating a mobile station 4; an MME/GW 2 accommodating the base stations 3 and performing mobility management of the mobile station 4; and an SON server (SON Server) 1 performing optimization of a cell by grouping the base stations 3. The SON server 1 comprises: an SON information collection part 11 collecting information related to the movement of the mobile station 4 from the MME/GW 2 and collecting information related to radio quality from the base stations 3; and an SON group generation part 12 obtaining a traffic line of the mobile station 4 subordinate to the base stations 3 based on the collected information, and grouping the base stations 3 based on the traffic line. The base stations 3 belonging to the same group form a group cell by transmitting the same control signal to the subordinate mobile station 4. <P>COPYRIGHT: (C)2012,JPO&amp;INPIT

Description

  The present invention relates to a wireless communication system that performs cell adjustment autonomously.

  In the WiMAX / Advanced WiMAX and LTE / LTE-Advanced systems that make up IMT (International Mobile Telecommunication) and IMT-Advanced, self-optimization of cells is performed using the SON (Self-Organizing Network) function. .

  Cell self-optimization control acquires performance information and control information statistics from mobile stations and base stations with the SON server (SON Server), and operates gateways and base stations according to control guidelines determined based on this information. Implemented by controlling.

  In 3GPP (3rd Generation Partnership Project), as shown in Non-Patent Document 1, standardization for automatically performing cell optimization is advanced as “Coverage and capacity optimization”.

  In addition, contributions have been issued for standardization, and proposals have been made for measures against coverage fall (dead zone) and cell interference (see Non-Patent Document 2). In Non-Patent Document 2, the transmission power and antenna angle of each base station are determined based on information on success / failure of handover of a mobile station, measurement information (the reception level of the local station and the level of neighboring cells), location information of the mobile station, and the like. It has been proposed to improve the coverage of each base station by adjusting.

3GPP TR36.902 (V9.0.0), 2009-09 “Coverage optimization” 3GPP TSG RAN WG3 R3-080755 31st March-3rd April, 2008

  The conventional SON technology is a cell self-optimization technology for a macro base station, and is trying to realize optimization of cell coverage by adjusting an antenna angle or the like. However, a pico base station or a femto base station constituting a small cell (pico cell or femto cell) that is expected to increase with the introduction of LTE or LTE-Advanced is a cell with a simpler mechanism than a macro base station. Realization of adjustment is desired.

  The present invention has been made in view of the above, and an object of the present invention is to obtain a wireless communication system that performs self-optimization of a cell with a simpler mechanism than in the past.

  In order to solve the above-described problems and achieve the object, the present invention provides a plurality of base stations that accommodate mobile stations, a gateway device that accommodates base stations and performs mobility management of mobile stations under the base station, and A wireless communication system including an SON server that optimizes cells by grouping base stations, wherein the SON server collects information related to movement of a mobile station from the gateway device, and receives radio quality from the base station. Information collecting means for collecting information on the mobile station, and the flow line of each mobile station existing under each base station in the system based on the information collected by the information collecting means, and each base station based on the obtained flow line Grouping means for grouping each base station belonging to the same group by transmitting the same control signal to each subordinate mobile station. And forming a group cell the cell was summarized.

  According to the present invention, the cell self-optimization can be realized with a simpler mechanism as compared with the conventional cell self-optimization that performs transmission power adjustment and antenna angle adjustment of the base station.

FIG. 1 is a diagram illustrating a configuration example of a wireless communication system according to the present invention. FIG. 2 is a diagram illustrating a configuration example of a subframe defined by 3GPP LTE. FIG. 3A is a diagram for explaining an effect when base stations are grouped based on a user flow line. 3-2 is a figure for demonstrating the effect at the time of grouping a base station based on a user flow line. FIG. 4A is a diagram for explaining an effect when base stations are grouped based on inter-cell interference. FIG. 4B is a diagram for explaining an effect when base stations are grouped based on inter-cell interference. FIG. 5 is a diagram illustrating an example of reception power of an uplink signal in each base station configuring a group cell. FIG. 6 is a diagram illustrating an example of reception power of an uplink signal in each base station configuring a group cell. FIG. 7 is a diagram illustrating a configuration example of a wireless communication system according to the second embodiment. FIG. 8 is a diagram illustrating a configuration example of a subframe used in the wireless communication system according to the second embodiment. FIG. 9 is a diagram illustrating a configuration example of a group cell. FIG. 10 is a diagram illustrating a frame configuration defined by LTE of 3GPP. FIG. 11 is a diagram illustrating a configuration example of a frame used in the wireless communication system according to the fourth embodiment. FIG. 12 is a diagram illustrating an example of information included in control information transmitted by the base station according to the fifth embodiment. FIG. 13 is a diagram illustrating a configuration example of subframes used in the wireless communication system according to the sixth embodiment. FIG. 14 is a diagram illustrating a configuration example of subframes used in the wireless communication system according to the seventh embodiment. FIG. 15 is a diagram for explaining the radio communication system according to the eighth embodiment.

  Embodiments of a wireless communication system according to the present invention will be described below in detail with reference to the drawings. Note that the present invention is not limited to the embodiments.

Embodiment 1 FIG.
FIG. 1 is a diagram illustrating a configuration example of a wireless communication system according to the present embodiment. As shown in the figure, a wireless communication system according to the present embodiment includes an SON server (SON Server) 1, an MME / GW (Mobility Management Entity / Gateway) 2, a plurality of base stations (eNB: evolved Node B) 3, and a mobile device. It consists of a station (UE: User Equipment) 4.

  The SON server 1 includes a SON information collection unit 11 that collects and statistics radio transmission performance, user flow line information, base station load information, and user distribution information, and groups the base stations 3 in the system to move groups and interference groups. And a SON group generation unit 12 for generating a CoMP (Coordinated Multipoint) group.

  The MME / GW 2 accommodates a plurality of base stations 3 and performs mobility management of the mobile stations 4 communicating under these base stations 3. Also, an MME / GW information collection unit 21 that collects user movement information and user distribution information, and an MME / GW group control unit 22 that performs RAB (Radio Access Bearer) management and highly reliable data transmission processing are provided.

  Each base station 3 has the same configuration, radio performance measured at the mobile station (referred to as mobile station measured radio performance), radio performance measured at its own station (referred to as base station measured radio performance), and success / failure of handover. Base station information collection unit 31 that collects handed-over information such as handover information, base station operation load information, number of accommodated users, and the like, and base station transmission control unit 32 that performs transmission control through a radio interface with the mobile station, And a base station group control unit 33 for synchronizing access information such as connection information and an uplink bandwidth request between base stations constituting a group cell (details will be described later). The mobile station measurement radio performance and the base station measurement radio performance are collected through radio transmission control between the base station 3 and the mobile station 4. The mobile station measurement radio performance is the downlink radio communication quality, and the base station measurement radio performance is the uplink radio communication quality.

  The mobile station 4 includes a mobile station transmission control unit 41 that performs radio transmission control with the base station 3, and performs handover control information and received power information (RSSI: Received Signal Strength Indicator, CINR: Carrier Interference) through radio transmission control. The wireless performance measurement results (such as Noise Ratio) are reported to the base station.

  In the wireless communication system of the present embodiment configured as described above, information (collected information # 1) collected by the MME / GW information collecting unit 21 of the MME / GE 2 and the base station information collecting unit 31 of the base station 3 are collected. The information collected in step (collected information # 2) is collected in the SON server 1.

  The SON server 1 configuring the wireless communication system that performs autonomous cell adjustment according to the present embodiment is based on information (collected information # 1, # 2) collected from the MME / GW 2 and each base station 3. A plurality of base stations 3 are grouped as necessary to generate a mobile group, an interference group, and a CoMP group. Moreover, the base station 3 forms one cell together with other base stations belonging to the same group. The mobile group is a group of base stations that form a single cell by bundling a plurality of cells in accordance with the flow line (movement) of the user (mobile station 4). An interference group is a group of base stations that form a single cell by bundling a plurality of cells that create strong inter-cell interference. A CoMP group is a group of base stations that form a single cell by bundling a plurality of cells that perform CoMP (multi-point coordination). Hereinafter, a cell formed by bundling the cells of the grouped base stations is referred to as a group cell.

  Although FIG. 1 shows an example in which the SON server 1 (SON group generation unit 12) generates a movement group, an interference group, and a CoMP group, it is not essential to generate all of them. Only some of them may be generated. Moreover, you may make it produce | generate groups other than these.

  FIG. 2 is a diagram illustrating a configuration example of a subframe defined by 3GPP LTE (Long Term Evolution). This subframe is used for transmission of user bursts (stores user bursts) data channel area (including part of the synchronization signal), PDCCH (Physical Downlink Control Channel) that stores user burst mapping information, and feedback. A control channel region including a PCFICH (Physical Control Format Indicator Channel) for transmitting information and a PHICH (Physical Hybrid ARQ Indicator Channel) for transmitting HARQ (Hybrid ARQ) acknowledgment information.

  In the radio communication system of the present embodiment, the control information set in the control channel region shown in FIG. 2 is made to be the same between base stations in the group (the same control signal from each base station in the same group). Is transmitted). That is, in the group cell, it is possible to acquire the same control channel information even if the mobile station 4 moves to any cell in the group cell. Thereby, for example, in a group cell configured for the purpose of avoiding interference, in addition to making the control channel region interference-free, the coverage area can be expanded by the diversity effect. In the following description, for the sake of convenience, the same control channel information transmitted from each base station in the same group is referred to as group control channel information, and control channel information transmitted by non-grouped base stations (other Control channel information that is not the same as any base station) is called single control channel information for distinction. In the present embodiment, PDCCH information (group control channel information, single control channel information) for a plurality of group cells can be set in the control channel region. That is, the base station 3 can belong to the other group B while belonging to the group A. In addition, the base station 3 forms a group cell together with another base station and transmits group control information to a certain mobile station X, and transmits single control information to another mobile station Y. Can be performed simultaneously.

  As already described, in the radio communication system of the present embodiment, base stations 3 are grouped based on the flow line of the mobile station 4 (user flow line indicating the movement history of the mobile station 4) and inter-cell interference. A mobile group or an interference group is generated. When each base station 3 of the mobile group forms a group cell (hereinafter referred to as a mobile group cell), and when each base station 3 of the interference group is a group cell (hereinafter referred to as an interference group). In the case of forming a cell), the following effects can be obtained.

<Effect when moving group cell is formed>
FIGS. 3A and 3B are diagrams for explaining an effect when the base stations 3 are grouped based on the user flow line.

  FIG. 3A shows a handover occurrence point when the mobile station 4 moves along the user flow line 57 in a state where the cells 51 to 56 of six base stations (not shown) are not grouped. It is shown. As shown in the figure, in a transmission scheme in which each base station independently creates a different control channel region (each base station sets and transmits a single control channel information in the control channel region), handover is performed at the cell boundary of each base station. When the mobile station 4 moves along the user flow line 57, a total of three handovers occur at the points 58-1 to 58-3.

  On the other hand, FIG. 3-2 shows a case where the mobile station 4 moves along the user flow line 57 in a state where the base stations of the cells 51 to 56 shown in FIG. 3A are grouped into two mobile groups. It shows a handover occurrence point. As shown in the figure, in a state in which base stations are grouped to form a group cell (mobile group cell) (the same group control channel information is transmitted from each base station in the same group), the cells 51 to 53 are bundled. A handover occurs at the boundary between the formed mobile group cell (group cell # 1) and the mobile group cell (group cell # 2) formed by bundling the cells 54-56. Therefore, when the mobile station 4 moves along the user flow line 57, a handover occurs only at the point 58-2. That is, when the cells 51 to 56 are not grouped, the handover that has occurred three times is reduced to one time.

  In this way, by forming a mobile group cell, it is possible to reduce a handover occurrence rate in IMT-Advanced in which a small cell such as a femto base station is introduced.

<Effect of forming interference group cell>
FIGS. 4-1 and FIGS. 4-2 are figures for demonstrating the effect at the time of grouping the base station 3 based on inter-cell interference.

  FIG. 4A illustrates an example of signal levels in a state where the three base stations (base stations # 1 to # 3) are not grouped. In this figure, a point where the CINR (Carrier Interference Noise Ratio) in the path loss model IMT Advanced Urban Micro NLOS (Non Line Of Site) is 1 dB when the transmission power of each base station is 100 mW is shown as a line 61.

  On the other hand, FIG. 4-2 shows an example of signal levels in a state where three base stations (base stations # 1 to # 3) are grouped. The configuration is the same as that shown in FIG. 4A except that the same control channel is transmitted from the station. In FIG. 4B, a point where CINR is 1 dB is a line 62.

  In an area of 400 m × 400 m, the coverage area when 3 base stations transmit independently (in the case shown in FIG. 4A) is 11%, but a group cell is composed of 3 base stations. In this case (in the case shown in FIG. 4B), the coverage area is 25% due to the macro diversity effect. Thus, by configuring a group cell by autonomous cell adjustment, it is possible to eliminate inter-cell interference and to expand a coverage area by a diversity effect.

  Since both the mobile group cell and the interference group cell are formed by neighboring base stations, it is clear that the occurrence rate of handover can be reduced even when the interference group cell is formed. On the other hand, even when a mobile group cell is formed, it is clear that inter-cell interference can be reduced and the coverage area can be expanded in addition to the effect of reducing the occurrence rate of handover. Therefore, the difference between the mobile group cell and the interference group cell is only information used when grouping is performed. That is, the difference is whether the main purpose is to suppress the frequency of occurrence of handover or the main purpose is to reduce inter-cell interference.

  As described above, the radio communication system according to the present embodiment copes with the problem that the handover frequency increases or the interference area increases by performing cell adjustment autonomously based on the user flow line. Reduction and increased coverage. Therefore, unlike the conventional optimization technology that mainly assumes macro base stations (optimization technology by adjusting the transmission power and antenna angle of each base station), especially cell miniaturization (picocell, femtocell) ) Is effective in improving the problem that the handover frequency increases and the interference area increases.

  Next, a method for autonomously controlling a mobile group by obtaining a user flow line based on handover success information of the mobile station 4 in the radio communication system of the present embodiment will be described. This control is performed by the SON server 1 shown in FIG.

  For example, in the state shown in FIG. 3A (in the state where each base station transmits single control channel information), when a handover occurs and the handover is successful, the base station 3 involved in this handover The base station information collection unit 31 transmits information indicating that a handover has occurred (hereinafter referred to as handover success information) to the SON information collection unit 11 of the SON server 1 via the MME / GW2. The SON information collection unit 11 of the SON server 1 accumulates handover success information acquired from the base station 3. The handover success information includes at least information (cell ID) indicating the handover source cell and information (cell ID) indicating the handover destination cell. By statistically processing the handover success information, user movement information, that is, user flow lines can be obtained, and a movement group can be created. Creation of a mobile group (grouping of base stations) is performed by the SON group generation unit 12 at a predetermined timing based on a user flow line (handover success information). The cell ID may be read as base station identification information (base station ID). The handover success information may be transmitted by both the handover source base station 3 and the handover destination base station 3.

  On the other hand, in the state shown in FIG. 3B, since the group cell exists, the mobile station 4 cannot recognize the individual base station 3, and only the handover between the group cells occurs. Therefore, handover success information (cell ID corresponding to the handover source base station 3 and cell ID corresponding to the handover destination base station 3) cannot be collected, and it is difficult to obtain a user flow line from the handover result. Therefore, the base station information collection unit 31 of each grouped base station 3 measures the reception power of the uplink signal and transmits the result (uplink reception power information) to the SON information collection unit 11 of the SON server 1. The SON information collection unit 11 obtains the user flow line of each mobile station 4 inside the group cell based on the uplink received power information. A method for acquiring a user flow line inside the group cell is described below.

  FIG. 5 shows each base station 3 (base station # 1, base station # 1, base station # 1) when the mobile station 4 in continuous communication moves along the user flow line 57 in the state shown in FIG. It is a figure showing an example of a time change of reception intensity of an uplink signal from this mobile station 4 in (# 2 and # 3). Here, it is assumed that the cell of the base station # 1 is the cell 51, the cell of the base station # 2 is the cell 52, and the cell of the base station # 3 is the cell 53. In this case, the SON information collection unit 11 of the SON server 1 determines that the mobile station 4 exists in the vicinity of the base station 3 receiving the uplink signal with the maximum received signal strength, and receives the signal at each base station 3. The movement of the mobile station 4 is detected by monitoring the change in power. That is, when the base station 3 where the reception power of the uplink signal is maximum changes, it is determined that the mobile station 4 has moved from the base station 3 before the change to the base station 3 after the change. The cell ID corresponding to the base station 3 is stored as the above handover success information (handover source cell ID, handover destination cell ID). In detecting the movement inside the group cell, a threshold may be set for time or signal strength in order to suppress frequent fluctuations of the base station 3 where the received signal strength is maximum. In the case where a threshold is given to time, after the base station 3 having the maximum received signal strength has changed, the base station 3 having the maximum received signal strength has not changed again during the threshold time. It is assumed that the movement of the mobile station 4 is detected. On the other hand, when a threshold value is given to the signal strength, after the base station 3 having the maximum received signal strength changes, the signal strength of the base station 3 that has received the maximum received signal strength and the newly received signal strength are It is assumed that the movement of the mobile station 4 is detected when the difference from the maximum signal strength of the base station 3 exceeds the threshold signal strength.

  When the uplink communication of the mobile station 4 is bursty, the time change of the reception strength of the uplink signal at the base stations # 1, # 2, # 3 constituting the group cell # 1 shown in FIG. As shown in the solid line part of FIG. Even in such a case, similarly to the method described above, the movement information of the mobile station 4 can be acquired by the change of the base station having the maximum received signal strength. However, when the uplink no-communication period (see FIG. 6) of the mobile station 4 is long, the acquired movement information (movement result determined based on the reception power of the uplink signal) is different from the actual user flow line. There is a risk of information. Therefore, a threshold is set for the uplink no-communication period, and when the base station with the maximum received signal strength changes before and after the uplink no-communication period exceeds this threshold, it is excluded from the user's mobile information detection target. Also good.

  In this way, user movement information in the group cell is acquired by monitoring the reception strength of the uplink signal at each base station. Thereby, the accuracy of the information collected for the purpose of grasping the user flow line can be maintained even in the state where the group cell is located. That is, even if the user flow line changes after setting the group cell, an effect of reflecting the change in the user flow line in the group configuration can be obtained.

  As described above, in the wireless communication system according to the present embodiment, the user flow line is obtained based on the mobile station result of the mobile station and the uplink signal reception result of the base station, and the base stations are grouped based on the user flow line. The same control channel information (group control channel information) is transmitted from each base station in the same group. As a result, cell self-optimization can be realized with a simpler mechanism as compared with the conventional cell self-optimization that performs transmission power adjustment and antenna angle adjustment of the base station.

Embodiment 2. FIG.
In the present embodiment, in a radio communication system that performs autonomous cell adjustment, a method for generating group control channel information that is the same control channel information (such as PDCCH) transmitted from each base station of a cell constituting a group cell explain.

  FIG. 7 is a diagram illustrating a configuration example of the radio communication system according to the present embodiment, for generating control channel information (group control channel information, single control channel information) transmitted from each base station 3 to each cell. The apparatus and functional configuration are shown. The description of the SON server 1 and the mobile station 4 is omitted for simplification.

  In FIG. 7, the MME / GW 2 corresponding to the MME / GW 2 described in the first embodiment is connected to each base station 3, and further generates group control channel information to belong to the group cell (to the group cell). Connected to a group cell base station transmission control device 5 that performs transmission control of a mobile station that is in the area of communication). The MME / GW 2 collects predetermined information used for transmission control of mobile stations belonging to the group cell from each base station, and further outputs the collected information to the group cell base station transmission control device 5.

  The base station 3 corresponds to the base station 3 described in the first embodiment. The group cell base station transmission control device 5 generates group control channel information to be transmitted from the base station of each cell constituting the group cell. The group control channel information for transmission control is generated based on information received from each base station 3 via the MME / GW 2 (information collected from each base station 3 by the MME / GW 2). In FIG. 7, the group cell base station transmission control device 5 is described as an independent device different from the MME / GW 2, the base station 3, and the SON server 1 (not shown). The function (transmission control operation) of the cell base station transmission control device 5 may be performed by the MME / GW 2 or the SON server 1. Moreover, you may make it represent by one base station in the base station which forms the group cell on behalf. That is, the group cell base station transmission control device 5 may be realized as a single device or may be realized as a part of a function provided with a certain device (SON server 1, MME / GW 2 or base station 3).

  The group cell base station transmission control device 5 includes a high-reliability data transmission unit, PDCP (Packet Data Convergence Protocol), RRC (Radio Resource Control), RLC (Radio Link Control), and MAC (Media Access Control). Execute radio transmission control of the mobile station to which it belongs.

  Each base station 3 includes a group cell base station transmission control unit 32-1 and a single cell base station transmission control unit 32-2. The group cell base station transmission control unit 32-1 includes a group cell MAC processing unit and a HARQ unit (UM). The HARQ unit (UM) performs HARQ (Hybrid Automatic Repeat Request) in an unacknowledged mode (UM). The group cell base station transmission control unit 32-1 receives the group control channel information generated and transmitted by the group cell base station transmission control device 5 when the self (own base station) constitutes a group cell. Receive and transmit to the mobile station 4 under its control. The single cell base station transmission control unit 32-2 includes PDCP (Packet Data Convergence Protocol), RRC (Radio Resource Control), RLC (Radio Link Control), MAC (Media Access Control), and HARQ unit (AM). The HARQ unit (AM) performs HARQ in an acknowledged mode (AM). This single cell base station transmission control unit 32-2 generates single control channel information in a state in which a group cell is not formed (a state in which the single cell base station transmission control unit 32-2 is operating as a single cell base station) and directs it to the subordinate mobile station 4 To send.

  Thus, in the wireless communication system of the present embodiment, group cell base station transmission control device 5 generates group control channel information, and single control channel information is the single cell base of base station 3 that transmits this information. Generated by the station transmission control unit 32-2. The base station 3 can simultaneously perform an operation as a base station constituting a group cell and an operation as a base station not constituting a group cell. For example, it is possible to transmit group control channel information to the subordinate mobile station A and transmit individual control channel information to other mobile stations B. In this case, the base station 3 combines and transmits the group control channel information received from the group cell base station transmission control device 5 and the single control channel information generated by the single cell base station transmission control unit 32-2 of its own device. .

  Next, an operation of generating and transmitting group control channel information and single control channel information in the radio communication system of the present embodiment will be described with reference to FIG.

  The group cell base station transmission control device 5 performs RRC and PDCP processing and generates PDCCH information by MAC in order to synchronize transmission of the RRC message and user data in each base station constituting the group cell. In addition, the group cell base station transmission control device 5 is, for example, highly reliable data that performs data transmission control using an erasure correction code in order to avoid short-term resynchronization processing synchronization among a plurality of base stations constituting the group cell. A transmission unit is provided, and the RLC operates in a non-delivery confirmation mode. Further, the RRC of the group cell base station transmission control device 5 sets the HARQ of each base station 3 constituting the group cell to the non-delivery confirmation mode, and further, the HARQ burst size in each base station 3 constituting the group cell, In order to make the modulation degree and the error correction rate the same, these setting values are determined and notified to the group cell MAC processing unit in the group cell base station transmission control unit 32-1 of each base station 3 constituting the group cell. To do. This notification is performed using, for example, a CGroup_MAC_Config_Req message.

  In each base station 3 constituting the group cell, when the group MAC processing unit of the group cell base station transmission control unit 32-1 receives the above CGroup_MAC_Config_Req message from the RRC of the group cell base station transmission control device 5, it is designated by a message. According to the set contents, the HARQ part is set to the non-delivery confirmation operation mode, and the burst size, the modulation factor, and the error correction rate are set to designated values. When the group cell MAC processing unit receives the MAC PDU (Protocol Data Unit) and the PDCCH information of the group cell from the group cell base station transmission control device 5, the group cell MAC processing unit receives the group cell from the control channel region of the subframe shown in FIG. A PDCCH region that can be used in a single cell (a cell that does not form a group cell) is calculated by subtracting a region in which PDCCH information is set (corresponding to the “PDCCH region used in a group cell”). The group cell MAC processing unit notifies this calculation result (PDCCH region usable in a single cell) to the MAC of the single cell base station transmission control unit 32-2. Upon receiving this notification, the MAC MAP generation unit, upon receiving the PDCCH region size information usable in this single cell, constructs a PDCCH for the single cell within this size (see “Single cell shown in FIG. 8”). The control information is set in the “PDCCH region that can be used in”).

  When the group cell MAC processing unit of the group cell base station transmission control unit 32-1 receives an uplink bandwidth request from the mobile station 4 belonging to the group cell, the request cell transmits the request content to the MAC of the group cell base station transmission control device 5. Then, the MAC of the group cell base station transmission control device 5 performs the uplink band allocation of the mobile station 4 and generates a group cell PDCCH information element for the uplink burst. This information is transmitted to the group cell MAC processing unit, and the uplink band indicated by this information is allocated to the requesting mobile station 4.

  Thereby, the transmission control of the mobile station 4 belonging to the group cell is performed by the group cell base station transmission control device 5, and the transmission control of the mobile station 4 belonging to the single cell is performed by the single cell base station transmission control unit 32-2 (base The PDCCH construction by the hybrid configuration executed in the station 3) becomes possible, and the base station belonging to the group cell can synchronize the PDCCH of the group cell and construct the PDCCH of the single cell.

  In this Embodiment, the base station 3 of each cell which comprises a group cell transmits the uplink signal received from the mobile station 4 to the group cell base station transmission control apparatus 5 with the received strength. The group cell base station transmission control device 5 discriminates the same uplink signal from each base station 3 and compares the received strengths, so that the user movement described in Embodiment 1 with reference to FIGS. Obtain information. Thereby, the accuracy of the information collected for the purpose of grasping the user flow line can be maintained even in the group transmission state, and the user flow line is changed after the group transmission is set as in the first embodiment. Even if it exists, the change of the user flow can be reflected in the group configuration.

  As described above, the radio communication system according to the present embodiment generates a control signal (group control channel information) transmitted by the base stations of the cells constituting the group cell, and distributes the control signal to each base station. A transmission control device is provided. Thereby, the same control channel information (group control channel information) can be transmitted from the base station of each cell constituting the group cell.

Embodiment 3 FIG.
In the present embodiment, a method for improving the efficiency of adjacent cell search of mobile station 4 in the radio communication system described in Embodiments 1 and 2 will be described with reference to FIG. FIG. 9 shows a configuration example of a group cell when the mobile station 4 moves on the user flow line shown in the figure. In this example, the cells 71 to 73 are group cells # 1, and the cells 74 to 76 are group cells. In cell # 2, cells 77 to 79 constitute group cell # 3.

  In the wireless communication system shown in the first and second embodiments, the SON server 1 that collects and manages information (collected information # 1, collected information # 2) collected by the MME / GW 2 and the base station 3 is a group cell. The movement information of the mobile station 4 located in # 2, that is, the history of which of the base stations of the cells 74 to 76 existed in the vicinity is grasped. When a certain mobile station 4 exists in the vicinity of the base station of the cell 76 at a certain point in time, especially when the mobile station 4 has a history of movement in the order of the cell 74 → the cell 75 → the cell 76, the SON server 1 It is determined that there is a high possibility of handover to group cell # 3 among group cell # 1 and group cell # 3, which are neighboring cells of # 2 (predicting that the movement destination in the next handover will be group cell # 3) . Then, the mobile station 4 is notified individually of a neighboring cell list in which the group cell # 3 is given high priority. The mobile station 4 can perform an efficient neighbor cell search by performing an operation referring to this neighbor cell list. That is, the search for the group cell # 1 can be omitted by preferentially searching for the group cell # 3 that is highly likely to be a handover destination. In the SON server 1, the generation of the adjacent cell list may be performed by the SON group generation unit 12, or an adjacent cell list generation unit may be separately provided and performed here.

  As described above, in the radio communication system according to the present embodiment, adjacent cells that are more likely to be handed over are individually predicted for each mobile station 4 based on the movement history of each mobile station 4, and the predicted adjacent cells are given high priority. Each mobile station 4 is notified individually of the adjacent cell list set as the cell (preferentially searched for cells). Thereby, the mobile station 4 can perform a cell search efficiently with reference to the notified neighboring cell list.

Embodiment 4 FIG.
In this embodiment, a method in the case where one base station constructs a plurality of group cells in the wireless communication system described in Embodiments 1 to 3 will be described. In this embodiment, an example in which the LTE synchronization method is applied will be described.

  First, the configuration of a frame used in 3GPP LTE will be described. FIG. 10 is a diagram illustrating a frame configuration defined by LTE of 3GPP. As shown in FIG. 10, one frame is composed of 10 subframes of subframes # 0 to # 9 and has a length of 10 ms. One subframe includes two slots (slots # 1 and # 2), and each slot includes seven symbols (OFDM symbols). PCFICH, PHICH, and PDCCH are arranged in the three symbols from the beginning of slot # 1 of each subframe. In subframes # 0 and # 5, synchronization channels (PSS: Primary Synchronization Signal, SSS: Secondary Synchronization Signal) for establishing synchronization and acquiring a cell ID (identifier) are arranged. Also, broadcast information (PBCH: Physical Broadcast Channel) of the cell in which this frame is transmitted is arranged immediately after the synchronization channel of subframe # 0. In a system to which LTE is applied, a mobile station receives a synchronization channel, establishes synchronization, acquires a cell ID, and further, a scramble pattern and a pseudo-random parameter that are physical layer parameters necessary for decoding a control channel Get a sequence.

  Next, the structure of the frame used in the radio communication system of this embodiment will be described. FIG. 11 is a diagram illustrating a configuration example of a frame used in the wireless communication system according to the present embodiment, in which a part of the frame illustrated in FIG. 10 is changed.

  Specifically, it is configured to use subframes in time division for each group cell, subframes # 0 to # 4 are assigned to group cell # 1, and subframes # 5 to # 9 are assigned to group cell #. 2 is assigned. Then, synchronization channels (PSS, SSS) are set in subframes # 0 and # 5. Information corresponding to the corresponding group cell is set in these subframes # 0 and # 5. That is, a synchronization signal composed of the cell ID of group cell # 1 is set in the synchronization channel of subframe # 0, and a synchronization signal composed of the cell ID of group cell # 2 is set in the synchronization channel of subframe # 5. Also, broadcast information (PBCH) of group cell # 1 is set immediately after the synchronization channel of subframe # 0, and broadcast information (PBCH) of group cell # 2 is set immediately after the synchronization channel of subframe # 5.

  The subframes # 0 to # 4 assigned to the group cell # 1 and the subframes # 5 to # 9 assigned to the group cell # 2 can be set and used for a single cell. However, when a single cell using subframes # 0 to # 4 and a single cell using subframes # 5 to # 9 use the same cell ID (when subframes # 0 to # 9 are assigned to one single cell) ) Omits broadcast information (PBCH) of subframe # 5. That is, the configuration is the same as that of the frame shown in FIG.

  As described above, in the radio communication system according to the present embodiment, one frame is divided into subframes # 0 to # 4 and # 5 to # 9 by using a frame configuration used in 3GPP LTE. Assigned to group cell. Thereby, the base station 3 belongs to two groups, and can communicate with the mobile station 4 in each group.

Embodiment 5 FIG.
In the present embodiment, a modification of the fourth embodiment will be described. In the fourth embodiment, the case where subframes in one frame are equally allocated to two group cells has been described, but in this embodiment, the case where the number of subframes allocated to each group cell is variable will be described. .

  In the radio communication system according to the present embodiment, for example, a group indicating group attributes for each subframe shown in FIG. 12 with respect to broadcast information (PBCH of subframes # 0 and # 5) shown in FIG. A configuration index (value of 0 to 6) is set and transmitted.

  In FIG. 12, group configuration index 0 indicates that subframes # 0 to # 4 are assigned to group cell # 1 (G1), and subframes # 5 to # 9 are assigned to group cell # 2 (G2). Indicates. The group configuration index 1 indicates that subframes # 0 to # 3 are assigned to group cell # 1 (G1), and subframes # 4 to # 9 are assigned to group cell # 2 (G2). The group configuration index 2 indicates that subframes # 0 to # 2 are assigned to group cell # 1 (G1), and subframes # 3 to # 9 are assigned to group cell # 2 (G2). The group configuration index 3 indicates that subframes # 0 to # 1 are assigned to group cell # 1 (G1), and subframes # 2 to # 9 are assigned to group cell # 2 (G2). The group structure index 4 indicates that subframes # 0 to # 4 and # 9 are assigned to group cell # 1 (G1), and subframes # 5 to # 8 are assigned to group cell # 2 (G2). Show. In the group structure index 5, subframes # 0 to # 4, # 8 to # 9 are assigned to group cell # 1 (G1), and subframes # 5 to # 7 are assigned to group cell # 2 (G2). Indicates that In the group structure index 6, subframes # 0 to # 4, # 7 to # 9 are assigned to group cell # 1 (G1), and subframes # 5 to # 6 are assigned to group cell # 2 (G2). Indicates that

  In this way, by notifying the mobile station 4 with broadcast information of subframes belonging to each group cell, for example, the frame configuration according to the load factor for each group cell (the number of mobile stations under each group cell) That is, the number of subframes allocated to each group can be adaptively changed.

Embodiment 6 FIG.
In this embodiment, in the wireless communication system described in Embodiments 1 to 3, a method in which one base station constructs a plurality of group cells by a method different from Embodiments 4 and 5 will be described.

  In the wireless communication system of the present embodiment, the base station 3 uses a subframe having the configuration shown in FIG. That is, a subframe configured to have a PDCCH that applies scrambling and a pseudo sequence using a different cell ID for each group cell and to share a subframe in units of physical resource units is used.

  The details of the subframe having the configuration shown in FIG. 13 will be described. A control channel composed of three symbols is a group cell to which scrambling using a cell ID (cell ID # 1) of group cell # 1 and a pseudo sequence are applied. PDCCH for # 1 cell (group cell # 2 PDCCH region) and PDCCH for group cell # 2 (group cell # 2 PDCCH region) to which the scramble and pseudo sequence using the cell ID (cell ID # 2) of group cell # 2 are applied ). The subframe includes a group cell # 1 region and a group cell # 2 region. In the group cell # 1 region, the data burst of the group cell # 1 to which the scramble and pseudo sequence with the cell ID # 1 is applied. To map. In the group cell # 2 area, the data burst of the group cell # 2 to which the scramble and the pseudo sequence with the cell ID # 2 are applied is mapped.

  In addition, it is possible to set a PDCCH for a single cell in the PDCCH of group cell # 2, and when setting a PDCCH for a single cell, scramble the cell ID of the single cell and apply a pseudo sequence. The data burst to be mapped is mapped to the area for group cell # 2.

  In addition, it is possible to set PDCCH of two or more group cells in a control channel of 3 symbols, and mapping data bursts belonging to a plurality of groups to the 4th symbol and later of slot # 1 and slot # 2 Is possible.

  Thus, by enabling PDCCHs belonging to a plurality of group cells to be set in a subframe, one base station can transmit data bursts of a plurality of group cells.

Embodiment 7 FIG.
In the present embodiment, a modification of the sixth embodiment will be described. The present embodiment is characterized in that the subframe transmitted from the base station includes PDCCH information and a cell ID of different group cells in the PDCCH of the group cell (see FIG. 14).

  FIG. 14 is a diagram illustrating a configuration example of a subframe used in the radio communication system according to the present embodiment. In this subframe, PDCCH information of different group cells in the PDCCH (group cell # 1 PDCCH) of the group cell The element is set.

  In the subframe having the configuration shown in FIG. 14, scramble and pseudo sequence using the cell ID (cell ID # 1) of group cell # 1 are applied to the PDCCH (group cell # 1 PDCCH region) of group cell # 1. Further, the PDCCH of group cell # 1 includes an area for setting the PDCCH information element of group cell # 2. This PDCCH information element of group cell # 2 includes the cell ID (cell ID # 2) of group cell # 2. In the group cell # 1 area, the data burst of the group cell # 1 to which the scramble by the cell ID # 1 and the pseudo sequence are applied is mapped. In the group cell # 2 area, the data burst of the group cell # 2 to which the scramble and the pseudo sequence with the cell ID # 2 are applied is mapped.

  In addition, PDCCH information elements of a plurality of group cells can be set in the PDCCH of group cell # 1. The PDCCH information element included in the PDCCH of group cell # 1 may be a PDCCH information element of a single cell.

  In this way, by setting PDCCH information elements of a plurality of group cells in the PDCCH of group cell # 1 in the subframe, one base station can transmit data bursts of the plurality of group cells.

Embodiment 8 FIG.
In the present embodiment, the radio communication system described in the fourth, fifth, sixth, and seventh embodiments, that is, one base station 3 forms a plurality of group cells (or configures a group cell and a single cell). In the radio communication system, a method for improving the accommodation efficiency of the mobile station 4 when one base station 3 configures cells (group cell, single cell) having different cover area sizes will be described.

  FIG. 15 is a diagram for explaining the radio communication system according to the present embodiment. In FIG. 15, the cells 81 to 87 form the group cell # 1, but the base station 3 of each cell operates to form the group cell # 1 (the same control channel information as other base stations). Operation for generating and transmitting the group control channel information) and the operation for providing the single cells 81 to 87 (operation for generating and transmitting the single control channel information that is unique to the base station) It is also assumed that

  At this time, as described in the first and second embodiments, the SON server 1 of the wireless communication system transmits the movement information of the mobile station 4 located in the group cell # 1, that is, the base stations of the cells 81 to 87. It keeps track of where it was. Therefore, the SON server 1 analyzes this movement information, and the mobile station 4 located in the group cell # 1 exists in the vicinity of one base station 3 (for example, the base station of the cell 84) for a certain period or more. When it is detected that the mobile station 4 is moving (not moving), the mobile station 4 is handed over from the group cell # 1 to the single cell (cell 84). For example, the SON server 1 instructs the MME / GW 2 to hand over the mobile station 4 to a single cell (cell 84), and the MME / GW 2 transmits a control signal to the mobile station 4 to H.84 is handed over. The mobile station 4 that has received this control signal performs handover and moves to the cell 84.

  As described above, in the radio communication system according to the present embodiment, the movement amount of each mobile station 4 located in the group cell is confirmed, and the mobile station 4 having a small movement amount is handed over to a single cell. did. Thereby, it is possible to move the mobile station 4 with less movement to a single cell while reducing the handover occurrence rate. As a result, the mobile stations 4 can be distributed to group cells and single cells, and efficient use of each cell can be realized.

  As described above, the wireless communication system according to the present invention is useful as a system having a function of performing cell optimization and forming one cell (group cell) by a plurality of base stations, It is suitable for a radio communication system in which one cell is formed by a small base station (pico base station or femto base station).

1 SON Server
2 MME / GW
3 Base station (eNB)
4 Mobile station (UE)
DESCRIPTION OF SYMBOLS 5 Group cell base station transmission control apparatus 11 SON information collection part 12 SON group production | generation part 21 MME / GW information collection part 22 MME / GW group control part 31 Base station information collection part 32 Base station transmission control part 32-1 Group cell base Station transmission control unit 32-2 Single cell base station transmission control unit 33 Base station group control unit 41 Mobile station transmission control unit 51-56, 71-79, 81-87 Cell 57 User flow line

Claims (10)

A radio having a plurality of base stations that accommodate mobile stations, a gateway device that accommodates base stations and manages the movement of mobile stations under the base station, and an SON server that optimizes cells by grouping the base stations A communication system,
The SON server
Information collecting means for collecting information on movement of a mobile station from the gateway device and collecting information on radio quality from the base station;
Grouping means for obtaining the flow line of each mobile station existing under each base station in the system based on the information collected by the information collecting means, and grouping the base stations based on the obtained flow line;
With
A base station belonging to the same group forms a group cell in which a plurality of cells are grouped by transmitting the same control signal to each subordinate mobile station. The grouping means includes
When determining the flow line, the flow line under the base station that is not grouped is obtained based on the handover result, and the flow line under the grouped base station is based on the reception quality of the uplink signal at each base station. The wireless communication system according to claim 1, wherein the wireless communication system is obtained. A group cell base station transmission control device that generates a control signal to be transmitted from each base station belonging to the group and distributes it to each base station belonging to the group;
The wireless communication system according to claim 1, further comprising: Apply 3GPP LTE,
The base station
The wireless communication system according to claim 3, wherein one or a plurality of types of control information is set and transmitted for a frame defined by 3GPP LTE. The base station
As a result of grouping by the grouping means, if it belongs to a plurality of groups,
The wireless communication system according to claim 4, wherein a plurality of types of control information corresponding to each group to which the group belongs is set in the frame and transmitted. The wireless communication system according to claim 5, wherein the base station assigns each subframe constituting the frame equally to communication in each group. The base station adaptively allocates each subframe constituting the frame to communication in each group based on the number of mobile stations corresponding to each group. The wireless communication system according to 1. The wireless communication system according to claim 5, wherein the base station divides each subframe constituting the frame into a plurality of regions, and assigns the regions to communication in each group. The SON server
Based on the flow line obtained by the grouping means, each mobile station predicts a cell to move in the next handover, further generates a neighbor cell list including information on the prediction result, and performs a cell search at the time of handover execution. Neighboring cell list generation means for notifying each mobile station for reference in operation,
The wireless communication system according to claim 1, further comprising: The base station
In the state belonging to the group generated by the grouping means, the function as a base station that forms a group cell and the operation as a base station that does not form a group cell are performed in parallel,
When there is a mobile station that is in a group cell and has been communicating under its own station for a certain period of time, by operating as a base station that does not form the group cell for the mobile station The wireless communication system according to any one of claims 1 to 9, wherein control for handover to a single cell is executed.