JP2013141151A - Base station, method for controlling base station, and program - Google Patents

Abstract

PROBLEM TO BE SOLVED: To perform control of appropriate groups according to communication states in a MU-MIMO (Multi User MIMO) system.SOLUTION: A base station comprises: transmission means which performs spatial multiplex on data corresponding to respective communication devices belonging to a group by using a plurality of antennas, and wirelessly transmits the spatially multiplexed data to the group; formation means which forms a group including the plurality of communication devices to which data is to be transmitted by the transmission means; and monitoring means which monitors communication states of the base station and the plurality of communication devices. The formation means forms a second group by excluding a part of communication devices belonging to the first formed group, and the transmission means determines whether to perform transmission by the first group or the second group according to the communication states monitored by the monitoring means.

Description

  The present invention relates to a radio base station that performs spatial multiplexing and transmits data to a plurality of terminal apparatuses.

A MIMO (Multiple-Input Multiple-Output Multiple Input Multiple Output) communication method that uses multiple antennas to spatially multiplex and communicate multiple different data streams in the same frequency band has been proposed in wireless LANs and cellular systems. ing. Furthermore, as a technique for improving the communication efficiency of the entire system using MIMO, there is a method of performing MIMO communication for a plurality of users (Multi User MIMO (hereinafter referred to as MU-MIMO)) (for example, Patent Document 1). A signal that is spatially multiplexed in MU-MIMO needs to be subjected to beam forming so that interference is reduced between a plurality of receiving terminal apparatuses. Beamforming is a technique for controlling the directionality of radio waves transmitted from a base station so that only signals that should be received by the terminal arrive at the antenna of each terminal apparatus. In realizing beam forming, a signal that weakens a signal to be received by another terminal apparatus is transmitted so that a signal to be received by another terminal apparatus does not arrive at each terminal apparatus.
In addition, it is necessary to appropriately select a combination of terminal devices that simultaneously transmit data by using CQI (Channel Quality Indication) from each terminal device so that the correlation among a plurality of terminal devices is reduced (user scheduling technique). There is also. IEEE 802.11ac, which is the next generation wireless LAN standard, proposes a method of previously grouping combinations of terminal devices that simultaneously transmit data in the MU-MIMO downlink and transmitting data to the group. Yes.
In the MU-MIMO grouping control described above, a large amount of calculation is required to determine a propagation path (channel response matrix H) for each user and to select a combination of users. It has been proposed (for example, Patent Documents 2 and 3).

JP 2010-28737 JP 2009-296598 A JP2010-4528

In the MU-MIMO downlink, when a plurality of terminal devices that transmit data at the same time are grouped, when a terminal device belonging to the group is disconnected, suitable control related to the transmission group that responds to this has not been studied. .
For example, if rescheduling is performed using CQI information from a terminal device other than the disconnected terminal device immediately after the terminal device is disconnected, it takes time to perform the rescheduling and a data transmission delay occurs. there is a possibility. Further, when transmission is continued to a group including the terminal device after the terminal device is disconnected, transmission efficiency is impaired because useless communication resources are allocated to the terminal device in which data to be transmitted does not exist.
The present invention has been made in view of the above-described problems, and an object of the present invention is to perform control related to an appropriate group according to a communication state in an MU-MIMO system.

As means for solving the above problems,
A base station that transmits data to a group to which a plurality of communication devices belong,
Transmitting means for spatially multiplexing data corresponding to each of the plurality of communication devices belonging to the group using a plurality of antennas and wirelessly transmitting to the group;
A first forming unit that forms a first group to which a plurality of communication devices that are targets of data transmission by the transmitting unit and that have correlations equal to or less than a predetermined value;
A second forming means for forming a second group based on the first group, excluding at least one communication device belonging to the first group;
The transmission means provides a base station that performs transmission to the first group or the second group in accordance with a communication state in a network controlled by the base station.

  By controlling the group to be transmitted according to the communication state, it is possible to reduce the delay in data transmission and improve the transmission efficiency of the entire system.

It is a figure which shows the system configuration example in this invention. It is a figure which shows the structure of the base station in Example 1. FIG. It is a figure which shows the sequence of the system in Example 1. FIG. 3 is a flowchart illustrating transmission processing according to the first exemplary embodiment. It is a figure which shows the structure of the base station in Example 2. FIG. It is a figure which shows the sequence of the system in Example 2. FIG. 10 is a flowchart illustrating transmission processing according to the second embodiment. 10 is a flowchart illustrating transmission processing according to the third embodiment.

[Example 1]
An example of the overall configuration of the communication system of the present invention is shown in FIG. In FIG. 1, a base station 100, a terminal device 101, a terminal device 102, a terminal device 103, and a terminal device 104 form a wireless network. The base station 100 manages and controls the constructed network, and communicates with the terminal devices 101 to 104. The terminal device 101 to the terminal device 104 are connected to the base station 100 that has built the network, and communicate with the base station 100. Note that the terminal apparatuses 101 to 104 can shift to a power saving mode defined in IEEE 802.11, in which power consumption is reduced compared to the active state. A configuration diagram of the base station 100 in this embodiment is shown in FIG. The base station 100 includes a CPU 200, a memory 201, a power saving mode monitoring unit 202, a group forming unit 203, a radio unit 204, a packet transmitting unit 205, a packet receiving unit 206, and a communication control unit 207. A CPU (Central Processing Unit) 200 controls the entire base station 100 based on a control program stored in the memory 201. The power saving mode monitoring unit 202 detects a transition of the terminal device connected to the constructed network to the power saving mode. Further, the power saving mode monitoring unit 202 detects the transition of the active state from the power saving mode of the terminal device connected to the constructed network (detection of cancellation of the power saving mode). Group forming section 203 forms a group of terminal devices that spatially multiplex a plurality of data streams and transmit signals destined for the plurality of terminal devices. The group forming unit 203 groups a plurality of terminal devices using CQI (Channel Quality Indication) information collected from the terminal devices. Here, the CQI information is control information indicating reception quality measured by the wireless terminal device. The group forming unit 203 forms a combination of terminal devices that are less correlated with each other according to CQI information received from each terminal device as a group to be transmitted. The wireless unit 204 has a plurality of antennas, and transmits the wireless packet generated by the packet transmission unit 205 in the air. The radio unit 204 can spatially multiplex a plurality of data streams simultaneously in the same frequency band using a plurality of antennas, and wirelessly transmit data corresponding to each of a plurality of different terminal apparatuses (MU-MIMO). In addition, the wireless unit 204 receives the radio wave transmitted by the terminal device and sends it to the packet receiving unit 206. The packet transmission unit 205 generates data to be transmitted via the wireless unit 204 as a predetermined packet. The packet receiving unit 206 generates a predetermined packet using the radio wave received by the wireless unit 204. The communication control unit 207 performs calculations and controls necessary for transmitting data.

  The operation of the communication system having the above configuration will be described. First, the overall operation of the communication system will be described using the sequence diagram of FIG. In FIG. 3, the base station 100 requests the terminal apparatus 101 to the terminal apparatus 104 to transmit CQI information. Then, the group forming unit 203 performs scheduling based on the CQI information transmitted from each terminal device. Here, the group forming unit 203 determines that the terminal devices 101, 102, 103, and 104 have a correlation equal to or less than a predetermined value based on the CQI information and can perform transmission as one group. A group is formed (S300). Here, the predetermined value is a value for securing an arbitrary communication quality. The predetermined value may be a predetermined value, but may be a value that can be variably set according to the communication quality required by the system. And the group formation part 203 sets ID of the group to which the formed terminal device 101-the terminal device 104 belong to G1. In S300, a plurality of groups may be formed as basic groups based on the calculation result. And the group formation part 203 forms the derivative group except a part of terminal device 101-104 which belongs to the scheduled basic group (S301). Here, the derivative group is a group to which a plurality of terminal devices to which at least one terminal device is excluded from the basic group does not perform scheduling using CQI information from each terminal device. When a basic group is formed, scheduling is performed using CQI information from each terminal device, so that there is little correlation between the terminal devices in the same group. Therefore, in any combination of the terminal devices of the basic group, it is possible to perform MU-MIMO transmission with little correlation between the terminal devices and little interference. Here, a group to which the terminal devices 102 to 104 belong, excluding the terminal device 101 from the basic group, is further formed, a derived group to which the terminal devices 102 to 104 belong is formed, and the group ID is set to G2. In addition, the group forming unit 203 forms the G3 group to which the terminal devices 101, 103, and 104 belong, the G4 group to which the terminal devices 101, 102, and 104 belong, and the G5 group to which the terminal devices 101, 102, and 103 belong as derived non-loops. .

  Then, the packet transmission unit 205 inputs information related to the group configuration formed in the Group ID Management of the Action frame defined by IEEE 802.11 in order to notify the formed group configuration, and forms a packet. The wireless unit 204 transmits the formed packet to the terminal devices 101, 102, 103, and 104 (S302). That is, in the present embodiment, the group configurations formed in S300 and S301 are notified in advance to the terminal devices 101 to 104.

  Thereafter, the terminal apparatus 101 transmits a packet notifying that the power saving mode is set to the base station 100 (S303). This is done by setting the PM bit in the MAC frame defined in IEEE 802.11 to 1. The terminal apparatus 101 that has transmitted a packet notifying that the power saving mode is set shifts to the power saving mode (S305). On the other hand, in the base station 100, the power saving mode monitoring unit 202 detects that the terminal device 101 shifts to the power saving mode by receiving the data packet of the power saving mode setting transmitted by the terminal device 101 (S304). When any of the terminal devices belonging to the base station 100 detects the transition to the power saving mode as a result of monitoring the communication state of the network, the base station 100 detects the MU to the basic group to which the terminal device shifted to the power saving mode belongs. -Prohibit MIMO transmission. While the terminal device is in the power saving mode, the base station 100 does not belong to the basic group to which the terminal device does not belong or the derived group derived from the basic group to which the terminal device belongs. MU-MIMO transmission is performed using groups. That is, when there is data to be transmitted to the terminal apparatuses 102 to 104 when the terminal apparatus 101 is in the power saving mode, the base station 100 is formed by the derivation group forming process of S301 by the MU-MIMO method. Send data to the group. Here, the data is simultaneously transmitted to the derived group (terminal devices 102 to 104) of group ID G2 (S306). That is, when there is a terminal in the power saving mode, in response to this, the terminal device is switched from the group to which the terminal device belongs to the group formed by excluding the terminal device, and data is transmitted by the MU-MIMO method. Take control. The transmission process of S306 will be described in further detail using the flowchart shown in FIG.

  In step S401, the communication control unit 207 determines whether there is data in the transmission queue. If there is no data in the transmission queue, the process ends. If there is data in the transmission queue, in S402, the communication control unit 207 confirms whether the destination of the data in the transmission queue is a terminal device in the power saving mode. In the case of the terminal device in the power saving mode, the process proceeds to S403, and the communication control unit 207 performs control to suspend transmission, and ends the process. Note that the data addressed to the terminal device in the power saving mode is transmitted again when there is a request from the terminal device or when the terminal device cancels the power saving mode.

  If the destination is not the power saving mode terminal device, in S404, the terminal is switched to the MU-MIMO group to which the data destination terminal device belongs and the terminal device in the power saving mode does not belong. In this embodiment, a group (G2) to which the terminal devices 102 to 104 belong is formed in advance in S301 excluding the terminal device 101. That is, when the terminal device 101 shifts to the power saving mode, the calculation for determining the propagation path information for each user for group formation, the selection of the combination of users, and the notification of the group configuration are not performed again. In response, switch to the MU-MIMO group G2.

  In step S405, the communication control unit 207 searches the transmission queue, confirms whether there is destination data for the terminal devices belonging to the switched MU-MIMO group, and acquires them as much as possible. In step S <b> 406, the packet transmission unit 205 creates a MU-MIMO packet based on the data acquired by the communication control unit 207 and transmits the MU-MIMO packet via the wireless unit 204.

  Returning to FIG. 3, if the terminal device 101 is in the power saving mode as a result of performing the processing of FIG. The selected MU-MIMO group G2 is selected. Then, the terminal devices 102 to 104 belonging to the group G2 transmit the destination data as MU-MIMO packets.

  Thereafter, the terminal device 101 transmits a packet notifying that the power saving mode is to be canceled to the base station 100 (S307). This is done by setting the PM bit in the MAC frame defined in IEEE 802.11 to 0. The terminal apparatus 101 that has transmitted a packet notifying that the power saving mode is to be released then shifts to an active state. On the other hand, in the base station 100, the power saving mode monitoring unit 202 detects that the terminal device 101 shifts to the active state by receiving the data packet for canceling the power saving mode transmitted by the terminal device 101. When one of the terminal devices belonging to the base station 100 detects a transition from the power saving mode to the active state as a result of monitoring the communication state of the network, the base station 100 moves to the basic group to which the prohibited terminal device belongs. Cancel the prohibition of MU-MIMO transmission. That is, when the terminal apparatus 101 shifts to the active state and the base station 100 has data to be transmitted to any of the terminal apparatuses 101 to 104, the base station 100 performs the basic group forming process of S300 according to the MU-MIMO method. Send data to the group formed by That is, the data is simultaneously transmitted to the group (terminal devices 101 to 104) having the group ID: G1 (S308).

  As described above, according to the present embodiment described above, a derived group excluding a part of the terminal devices belonging to the scheduled basic group is formed, and the formed basic and derived group configuration is notified to the terminal station. The group can be switched in response to the communication status. It is possible to switch groups without recalculating calculation of propagation path information for group formation, selection of combinations, and notification of group configuration. Therefore, by controlling the MU-MIMO group in response to the communication state, the transmission efficiency of the entire system can be improved by efficiently allocating communication resources while reducing the data transmission delay due to the rescheduling process. Can be improved.

  In this embodiment, derived groups G2, G3, G4, and G5 are formed by removing any one terminal device from the basic group. However, for example, the G6 group to which the terminal devices 103 and 104 belong, the G7 group to which the terminal devices 102 and 104 belong, and other groups excluding a plurality of terminal devices from the basic group may be comprehensively formed. As in this embodiment, a group combination excluding terminal devices that may shift to or cancel the power saving mode may be formed as a derived group. With such a configuration, it is possible to improve transmission efficiency by switching the MU-MIMO group according to the network conditions while reducing the burden and time of schedule processing.

[Example 2]
The configuration of the base station 100 according to the present embodiment is such that, instead of the power saving mode monitoring unit 202 of the first embodiment, the connection state monitoring unit 502 detects the disconnection of the terminal device connected to the constructed network. Assume that it is configured (FIG. 5).

  The operation of the communication system at this time will be described. In the sequence diagram of FIG. 6, the control of S600 to S602 is the same as S300 to S302 of the first embodiment. However, supplementary explanation will be given for the control suitable for the present embodiment regarding the formation of the basic group (S600) and the formation of the derived group (S601).

  In S600, the group forming unit 503 performs determination of propagation path information for each user and selection of a combination of users with a large amount of calculation as well-known prior art in order to form a basic group. On the other hand, in S601, the group forming unit 503 diverts the propagation path for each user determined by the basic group to form a derived group. In S601, the user combination is selected from the basic group without performing scheduling using the CQI information from each terminal device so that the correlation between the terminal devices is reduced. The excluded combination is set as group G2. Therefore, in S601, a derived group is formed with a smaller calculation amount than in S600.

  After S602, when there is data to be transmitted to the terminal apparatuses 101 to 104 when the terminal apparatus 101 is in the connected state, the base station 100 is formed by the basic group forming process of S600 according to the MU-MIMO method. Send data to the selected group. That is, the data is simultaneously transmitted to the group (terminal devices 101 to 104) having the group ID: G1 (S603).

  Thereafter, the terminal apparatus 101 transmits a packet notifying that the terminal apparatus 101 is disconnected (leaves from the network) to the base station 100 (S604). This is a MAC frame disconnection packet defined in IEEE 802.11. Thereafter, it is unnecessary to transmit data to the terminal device 101 unless the terminal device 101 is connected to the network again. Therefore, performing data transmission to the MU-MIMO group to which the terminal apparatus 101 belongs is not preferable in view of transmission efficiency. In the base station 100, the connection state monitoring unit 502 detects that the terminal device 101 is disconnected by receiving the disconnected packet transmitted by the terminal device 101 (S605). When the base station 100 detects that any terminal device belonging to the base station 100 has left the network as a result of monitoring the communication state of the network, the base station 100 prohibits MU-MIMO transmission to the basic group to which the terminal device belongs. Thereafter, the base station 100 performs MU-MIMO transmission using a group to which the terminal device does not belong, among basic groups to which the terminal device does not belong or derived groups derived from the basic group to which the terminal device belongs.

  When there is data to be transmitted to the terminal apparatuses 102 to 104 when the terminal apparatus 101 is disconnected from the network, the base station 100 stores data in the group formed by the derivation group forming process of S601 by the MU-MIMO method. Send. That is, the data is simultaneously transmitted to the group (terminal devices 102 to 104) having the group ID: G2 (S606). That is, when a disconnected terminal device is detected, control is performed in response to this to switch from the group to which the terminal device belongs to the group formed by excluding the terminal device and to transmit data using the MU-MIMO method. I do. The transmission process of S606 will be described in further detail using the flowchart shown in FIG.

  In step S701, the communication control unit 507 determines whether there is data in the transmission queue. If there is no data in the transmission queue, the process ends. If there is data in the transmission queue, in step S702, the communication control unit 507 confirms whether the destination of the data in the transmission queue is a disconnected terminal device. In the case of the disconnected terminal device, the process proceeds to S703, and the communication control unit 507 performs control to suspend transmission, and ends the process. Note that the data destined for the disconnected terminal device is discarded.

  If the destination is not the disconnected terminal device, in S704, the terminal is switched to the MU-MIMO group to which the data destination terminal device belongs and the disconnected terminal device does not belong. In this embodiment, the group (G2) to which the terminal devices 102 to 104 belong is previously formed in S601 except for the terminal device 101. In other words, when the terminal device 101 is disconnected, the calculation of the propagation path information for each user for group formation and the selection of the combination of users and the notification of the group configuration are performed immediately without any renewal, Switch to MU-MIMO group G2.

  In step S <b> 705, the communication control unit 507 searches the transmission queue, confirms whether there is destination data for the terminal devices belonging to the switched MU-MIMO group, and acquires them as much as possible. In step S <b> 706, the packet transmission unit 505 creates a MU-MIMO packet based on the data acquired by the communication control unit 507, and transmits the packet via the wireless unit 504.

  Returning to FIG. 6, when the terminal device 101 is disconnected as a result of performing the processing of FIG. 7 in S <b> 606, if the terminal device 102 to 104 has the destination data in the transmission queue, the MU-MIMO formed in advance Group G2 is selected. Then, the terminal devices 102 to 104 belonging to the group G2 transmit the destination data as MU-MIMO packets.

  Thereafter, since the terminal device 101 is disconnected, the base station 100 deletes the group ID: G1, which is the basic group formed by the basic group formation process in S600 (prohibits use) (S607). Also, the base station 100 sets, as a basic group, a group that does not include a terminal that has left the derived group generated in S601 and belongs to the largest number of terminal devices. Note that in the basic group resetting in S607, it is assumed that the calculation for determining the propagation path and selecting the user combination is performed again. Here, the group G2 is reset as a basic group.

  After that, the base station 100 generates a derived group from the basic group (G2) reset in S607. Here, the group forming unit 503 forms a G6 group to which the terminal devices 103 and 104 belong, a G7 group to which the terminal devices 102 and 104 belong, and a G8 group to which the terminal devices 102 and 103 belong. In FIG. 6, the processes of S607 and S608 are performed after the process of S606 is performed. However, the present invention is not limited to this, and the processes of S607 and S608 may be executed at an arbitrary timing of the disconnection detection of S605. Absent.

  As described above, according to the present embodiment described above, as in the first embodiment, the group can be switched in response to the communication status. In addition, the formation of the derived group is performed with a smaller calculation amount than the formation of the basic group, and the responsiveness is further improved. In other words, the basic group formation and the derived group can be formed and notified to the terminal device with a small increment of the calculation amount, and a change in the communication status of the terminal device after the group formation can be immediately responded.

[Example 3]
In the first embodiment, the power saving mode state of the terminal device is monitored. In the second embodiment, the connection state of the terminal device is monitored and the group is switched. However, the state of the transmission queue may be monitored and the group may be switched. it can. The configuration of the base station 100 in this embodiment is assumed to correspond to FIG. 5, and the transmission processing of this embodiment will be described using the flowchart shown in FIG.

  In step S801, the communication control unit 507 determines whether there is data in the transmission queue. If there is no data in the transmission queue, the process ends. If there is data in the transmission queue, in step S802, the communication control unit 507 checks the destination of the data in the transmission queue and confirms whether there is a terminal device that belongs only to the basic group. If a terminal device belonging only to the basic group is the destination of data in the transmission queue, the process proceeds to S803, and the communication control unit 507 performs control to switch to the basic group for transmission, and then proceeds to S805.

  If the terminal device belonging only to the basic group is not the destination of the data in the transmission queue, the terminal device serving as the destination of the data in the transmission queue belongs to the largest number in S804, and the terminal devices belonging only to the basic group are excluded. Switch to the MU-MIMO group. In the present embodiment, as in the first and second embodiments, a group (G1) of the terminal device 101, the terminal device 102, the terminal device 103, and the terminal device 104 is formed as a basic group. Further, it is assumed that a group (G2) to which the terminal devices 102 to 104 belong is formed in advance excluding the terminal device 101 as a derived group. That is, when the terminal device 101 is not at the destination of the data in the transmission queue, the calculation for determining the propagation path for each user and the selection of the combination of users for group formation and the notification of the group configuration are not performed again. Then, the group is switched to the group G2 used for transmission.

  In step S805, the communication control unit 507 searches the transmission queue, confirms whether there is destination data for the terminal devices belonging to the switched MU-MIMO group, and acquires them as much as possible. In step S <b> 806, the packet transmission unit 505 creates a MU-MIMO packet based on the data acquired by the communication control unit 507, and transmits the packet via the wireless unit 504.

  As described above, according to the present embodiment described above, as in the first embodiment, it is possible to switch the group so as to improve the transmission efficiency of the entire system while reducing the amount of calculation required for group formation in response to the communication situation. It becomes. As in this embodiment, when a derived group is formed in order to switch the group in response to the state of the transmission queue, further processing is performed for selecting a basic group that is a combination of a propagation path and a user for each user to be diverted. When added, it works more favorably. For example, the communication quality may be maintained and improved by adding a basic group having a channel characteristic and channel quality of a predetermined value or more to form a derived group from the selected basic group. .

  Note that the communication resources (streams) allocated to the terminal devices excluded from the basic group when generating the derived group may be further allocated to other terminal devices belonging to the derived group. For example, in the case of G2, more data streams are assigned to at least one of the terminal devices 102 to 104 assigned to G1 in the above-described embodiment. With this configuration, the throughput of the entire system when data transmission is performed by switching to a derived group is further improved. Further, in the first to third embodiments, the base station 100 switches to the power saving mode of the terminal device, the connection of the terminal device is disconnected, and the state of the transmission queue is used as an example of the communication state used as a criterion for switching the group. . However, the present invention is not limited to these. For example, a terminal group that monitors the communication state of a terminal device such as a long data length of received data, a low communication speed, or a large number of communication errors, and removes the terminal device from the basic group. Form. Then, data is transmitted to a terminal device in the communication state as described above by SISO (Single User Input MIMO) or SISO (Single-Input Single-Output) which transmits data using a single antenna. To. For example, when data transmission is performed within a MU-MIMO group to which a terminal device having a long data length of received data belongs, it is necessary to embed padding data in the data for other terminal devices in order to match the longest data length. That is, the throughput of the entire system is reduced by the amount of padding data that has no meaning. Therefore, a terminal device having a long data length of received data can reduce the amount of padding data by switching groups so that data transmission is not performed by the MU-MIMO method, and the throughput of the entire system is improved. In addition, when transmitting to a MU-MIMO group included in a terminal device such as a slow communication speed or a large number of communication errors, other terminal devices are forced to have a transmission rate and retransmission processing tailored to the terminal device. Throughput will decline. Therefore, the terminal apparatus having a low communication speed or a large number of communication errors can improve the throughput of the entire system by switching the group so as not to perform data transmission by the MU-MIMO method.

  Needless to say, apparatuses that combine or have all the functions of the base stations according to the first to third embodiments are also within the scope of the present invention.

  As mentioned above, although Example 1-3 was demonstrated, this invention is implement | achieved also by performing the following processes. That is, software (program) that realizes the functions of the above-described embodiments is supplied to a system or apparatus via a network or various storage media, and a computer (or CPU, MPU, or the like) of the system or apparatus reads the program. It is a process to be executed.

100 Base station 101-104 Terminal device 200, 500 CPU
201, 501 Memory 202 Power saving mode monitoring unit 203, 503 Group forming unit 204, 504 Wireless unit 205, 505 Packet transmitting unit 206, 506 Packet receiving unit 207, 507 Communication control unit 502 Connection state monitoring unit

Claims (11)

A base station that transmits data to a group to which a plurality of communication devices belong,
Transmitting means for spatially multiplexing data corresponding to each of the plurality of communication devices belonging to the group using a plurality of antennas and wirelessly transmitting to the group;
A first forming unit that forms a first group to which a plurality of communication devices that are targets of data transmission by the transmitting unit and that have correlations equal to or less than a predetermined value;
A second forming means for forming a second group based on the first group, excluding at least one communication device belonging to the first group;
The base station according to claim 1, wherein the transmission unit performs transmission to the first group or the second group according to a communication state in a network controlled by the base station.   When the communication device shifts to the power saving mode, the transmission means transmits to the second group excluding the communication device from the first group to which the communication device shifted to the power saving mode belongs. The base station according to claim 1.   3. The transmission unit according to claim 1, wherein when the communication unit detects that the power saving mode is released, the transmission unit performs transmission in a first group including the communication device that has released the power saving mode. Base station described in.   2. The transmission unit according to claim 1, wherein, when the communication device leaves the network, the transmission unit performs transmission to the second group excluding the communication device from the first group to which the detached communication device belongs. 4. The base station according to any one of 3 to 3.   The base station according to any one of claims 1 to 4, wherein when the communication device leaves the network, the first group including the communication device that has left the network is deleted.   When the destination of the data in the transmission queue includes a communication device that belongs only to the first group, the transmission means transmits in the first group, and does not include a communication device that belongs only to the first group. The base station according to claim 1, wherein transmission is performed in a second group to which a communication device belonging only to the first group does not belong.   The first forming means generates propagation path information for propagating data to communication devices belonging to the first group, and the second forming means propagates to communication devices belonging to the second group. The base station according to any one of claims 1 to 6, wherein propagation path information obtained by forming the first group is used as path information. The second forming unit forms the second group excluding the communication device belonging to the first group having a long data length of received data, a low communication speed, or a large number of communication errors,
When transmitting the data to the communication device, the transmission means does not use the first group to which the communication device belongs, and spatially multiplexes data corresponding to the communication device using a plurality of antennas, Sending data corresponding to the communication device to the communication device using a single antenna or transmitting to the communication device,
8. When transmitting data to another communication apparatus belonging to the first group, the data is transmitted to the second group excluding the communication apparatus. 8. Base station.   In the first group, the second forming unit further assigns the assigned data stream to another communication device in the first group when the communication device removed when forming the second group is assigned to the second group. The base station according to claim 1, wherein the base station is formed. A control method of a base station that transmits data to a group to which a plurality of communication devices belong,
Using a plurality of antennas, spatially multiplexing data corresponding to each of the plurality of communication devices belonging to the group, and wirelessly transmitting to the group; and
A first forming step of forming a first group to which a plurality of communication devices that are data transmission targets in the transmission step and whose correlation is equal to or less than a predetermined value belong to each other;
A second forming step of forming a second group based on the first group, excluding at least one communication device belonging to the first group;
In the transmission step, transmission is performed to the first group or the second group according to a communication state in a network controlled by the base station.   The program for operating a computer as a base station in any one of Claims 1 thru | or 9.

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