JP2017175667A - Radio communication system, base station, communication terminal, and radio communication method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a radio communication system that improves utilization efficiency of radio resources.SOLUTION: A radio communication apparatus 1 comprises: a control section 12 for extracting a radio communication apparatus 2 meeting a predetermined condition; and a communication section 11 for transmitting first information indicating a first block consisting of multiple block including a control block for transmitting a signal using a first control channel to be used for communication in an RRC layer and second information indicating a second block included in the first block to the extracted radio communication apparatus 2 using a radio resource control signal, transmitting a signal using a second control channel for activating a communication including setting of a communication cycle in the control block, and exchanging data with the second communication apparatus corresponding to the second block in the second block for each first block in each communication cycle reported by the radio resource control signal. The radio communication apparatus 2 comprises a communication section 21 for exchanging data with a first communication apparatus in the second block for each first block in each communication cycle based on the first information and the second information.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a wireless communication system, a base station, a communication terminal, and a wireless communication method.

  In recent years, a system has been introduced in which communication devices connected to a network exchange information with each other and perform control independently. Such a system may be referred to as machine-type communication (MTC). Such a system is also called machine-to-machine communication.

  As a system using MTC, a system using a cellular communication system having a wide communication area has attracted attention. For example, devices used for MTC (hereinafter referred to as “MTC device”) include an electric meter, a gas meter, and a surveillance camera.

  Also, in a cellular communication system using MTC, the MTC device often does not move, and the quality of the radio link is ensured to be constant, so that scheduling without considering mobility can be performed. Therefore, it is conceivable to use semi-permanent scheduling called Semi-Persistent Scheduling (SPS). In SPS communication, radio resources are given to the MTC device at regular intervals. Specifically, in the case of SPS communication, first, the SPS communication cycle is notified in advance by layer 3 signaling (RRC (Radio Resource Control) signaling). When performing SPS communication, each MTC device is notified of SPS Activation (SPS Activation) by Layer 1 signaling (PDCCH: Physical Downlink Shared CHannel). Then, when ending SPS communication, SPS release (Release) is notified to each MTC device by layer 1 signaling.

  As a wireless communication technique, there is a conventional technique in which a reserved slot addressed to a terminal is designated by a bitmap so that collision of signals transmitted from the terminal does not occur. Further, there is a conventional technique in which MTC devices are grouped, and data is transmitted by designating a reference destination and a data area reference destination according to a group identifier.

JP 2012-80415 A JP2013-9210A

TS36.211, “Physical Channels and Modulation,” V11.3.0, June 2013 TS36.212, “Multiplexing and channel coding,” V11.3.0, June 2013 TS36.213, “Physical layer procedures,” V11.3.0, June 2013 TS36.214, “Measurements,” V11.1.0, December 2012 TS36.300, “Overall description, V11.3.0, June 2013 TS36.321, “Media Access Control (MAC) protocol specification,” V11.3.0. June 2013 TS36.322, “Radio Link Control (RLC) protocol specification,” V11.3.0, June 2013 TS36.323, “Packet Data Convergence Protocol (PDCP) specification,” V11.3.0, June 2013 TS36.331, “Radio Resource Control (RRC) protocol specification,” V11.3.0, June 2013

  However, in a cellular communication system using MTC, for example, an enormous number (for example, 140000) of MTC devices may exist in one cell. Therefore, when activation is performed on all devices in the cell using the PDCCH, the overhead of the PDCCH that is a control signal increases. In addition, when the PDCCH is released for all devices in the cell, the overhead of the PDCCH that is a control signal increases, and further, when there is no communication data in the data channel secured by SPS, The PDSCH (Physical Downlink Control CHannel) and PUSCH (Physical Uplink Shared CHannel) of the data channel are not used and communication resources are wasted.

  As described above, when SPS is used for a cellular communication system using MTC, there is a possibility that the utilization efficiency of radio resources may deteriorate.

  In addition, when using the conventional technology for designating reserved slots addressed to terminals using a bitmap, it is difficult to specify all reserved slots when there are a large number of terminals, and it is difficult to improve the utilization efficiency of radio resources. is there. Further, in the conventional technique in which MTC devices are grouped and data is transmitted, since PDCCH is transmitted to MTC devices in the group in units of groups, it is difficult to improve the utilization efficiency of radio resources.

  The disclosed technique has been made in view of the above, and an object thereof is to provide a radio communication system, a base station, a communication terminal, and a radio communication method that improve the utilization efficiency of radio resources.

  In one aspect, a wireless communication system, a base station, a communication terminal, and a wireless communication method disclosed in the present application include a first wireless communication device and a plurality of second wireless communication devices. The first radio communication device controls transmission / reception of signals using a control unit that extracts the second radio communication device that satisfies a predetermined condition and a first control channel used for communication in a Radio Resource Control (RRC) layer. The second wireless communication apparatus in which the control unit extracts first information indicating a first section including a plurality of sections and second information indicating a second section included in the first section. For each communication period transmitted using a second control channel that activates communication including setting of a communication period in the control section and notified by the radio resource control signal. A first communication unit that transmits and receives data to and from the second wireless communication device corresponding to the second section in the second section for each of the first sections. The second radio communication device, for each of the first intervals for each communication cycle notified by the radio resource control signal, based on the first information and the second information received from the first radio communication device. A second communication unit that transmits and receives data to and from the first wireless communication device in the second section.

  According to one aspect of the wireless communication system, the base station, the communication terminal, and the wireless communication method disclosed in the present application, it is possible to improve the use efficiency of wireless resources.

FIG. 1 is a block diagram of a wireless communication system according to the first embodiment. FIG. 2 is a flowchart of communication control in the communication system according to the first embodiment. FIG. 3 is a schematic diagram of a wireless communication system according to the second embodiment. FIG. 4 is a block diagram of the wireless communication apparatus according to the second embodiment. FIG. 5 is a sequence diagram of communication control in downlink communication in the communication system according to the second embodiment. FIG. 6 is a flowchart of communication control in downlink communication in the communication system according to the second embodiment. FIG. 7 is a sequence diagram of communication control in uplink communication in the communication system according to the second embodiment. FIG. 8 is a flowchart of communication control in uplink communication in the communication system according to the second embodiment. FIG. 9 is a flowchart of communication control in downlink communication in the communication system according to the third embodiment. FIG. 10 is a flowchart of communication control in uplink communication in the communication system according to the third embodiment. FIG. 11 is a sequence diagram of communication control in downlink communication in the communication system according to the third embodiment. FIG. 12 is a sequence diagram of communication control in uplink communication in the communication system according to the third embodiment. FIG. 13 is a sequence diagram of communication control in downlink communication in the communication system according to the fourth embodiment. FIG. 14 is a sequence diagram of communication control in uplink communication in the communication system according to the fourth embodiment. FIG. 15 is a sequence diagram of communication control in downlink communication in the communication system according to the fifth embodiment. FIG. 16 is a sequence diagram of communication control in uplink communication in the communication system according to the fifth embodiment. FIG. 17 is a flowchart of communication control in downlink communication in the communication system according to the sixth embodiment. FIG. 18 is a flowchart of communication control in uplink communication in the communication system according to the sixth embodiment. FIG. 19 is a sequence diagram of communication control in downlink communication in the communication system according to the sixth embodiment. FIG. 20 is a sequence diagram of communication control in uplink communication in the communication system according to the sixth embodiment. FIG. 21 is a flowchart of communication control in downlink communication in the communication system according to the seventh embodiment. FIG. 22 is a flowchart of communication control in uplink communication in the communication system according to the seventh embodiment. FIG. 23 is a sequence diagram of communication control in downlink communication in the communication system according to the seventh embodiment. FIG. 24 is a sequence diagram of communication control in uplink communication in the communication system according to the seventh embodiment. FIG. 25 is a hardware configuration diagram of the base station. FIG. 26 is a hardware configuration diagram of the communication terminal.

  Hereinafter, embodiments of a wireless communication system, a base station, a communication terminal, and a wireless communication method disclosed in the present application will be described in detail with reference to the drawings. The wireless communication system, the base station, the communication terminal, and the wireless communication method disclosed in the present application are not limited by the following embodiments.

  FIG. 1 is a block diagram of a wireless communication system according to the first embodiment. As illustrated in FIG. 1, the wireless communication system according to the present embodiment includes a wireless communication device 1 and a wireless communication device 2. Here, although one wireless communication device 2 is illustrated in FIG. 1, there are actually a plurality of wireless communication devices 1 and two wireless communication devices 2.

  The wireless communication device 1 includes a communication unit 11 and a control unit 12. The wireless communication device 2 includes a communication unit 21 and a control unit 22.

  The control unit 12 performs overall control of the communication unit 11 and the wireless communication device 1. For example, the control unit 12 extracts a wireless communication device 2 that satisfies a predetermined condition from the plurality of wireless communication devices 2. For example, the predetermined condition is the wireless communication device 2 that performs uplink communication in a predetermined period. For example, wireless that performs random access (RA) or uplink control information transmission (UCI (Uplink Channel Information) transmission such as CQI (Channel Quality Information) report, SRS (Sounding Reference Signal) transmission, etc.)) The communication device 2 is applicable.

  And the control part 12 notifies the information of the extracted radio | wireless communication apparatus 2 to the communication part 11. FIG.

  The communication unit 11 communicates with the communication unit 21 of the wireless communication device 2 wirelessly via an antenna.

  The communication unit 11 receives the information of the wireless communication device 2 extracted by the control unit 12. And the communication part 11 is 1st information which shows the 1st area which consists of several areas including the control area which transmits / receives a 1st control signal, and 2nd information which shows the 2nd area contained in the said 1st area. Is transmitted to the extracted wireless communication apparatus 2. In the second section, data communication is possible without transmitting a control signal. Further, when data transmission / reception is not performed, the radio resources can be used for other terminals.

  Thereafter, the communication unit 11 transmits the activation that is the first control signal to the wireless communication devices 2 extracted by the control unit 12 collectively or to some of the wireless devices 2. Thereafter, in the case of downlink communication, the communication unit 11 transmits data to the wireless communication device 2 in which the second section is designated in the second section transmitted to each wireless communication device 2. In the case of uplink communication, the communication unit 11 receives data from the wireless communication device 2 in which the second section is designated in the second section transmitted to each wireless communication device 2.

  Thereafter, when communication with the wireless communication device 2 extracted by the control unit 12 is completed, the communication unit 11 transmits a release signal to the wireless communication device 2 extracted by the control unit 12.

  The control unit 22 performs overall control of operations of the communication unit 21 and the wireless communication device 2.

  The communication unit 21 communicates with the communication unit 11 of the wireless communication device 1 via an antenna. The communication unit 21 receives the first information and the second information from the communication unit 11 of the wireless communication device 1. And the communication part 21 acquires a 1st area from the received 1st information. Furthermore, the second section indicated by the received second information is acquired as a section in which the own apparatus communicates.

  The communication unit 21 receives the activation that is the first control signal from the communication unit 11. Thereafter, the communication unit 21 repeats the cycle for each first interval from the timing at which the activation is received. In the case of downlink communication, the communication unit 21 receives data from the communication unit 11 of the wireless communication device 1 in the second interval in each first interval. In the case of uplink communication, the communication unit 21 transmits data to the communication unit 11 of the wireless communication device 1 in the second interval in each first interval.

  Next, communication control in the communication system according to the present embodiment will be described with reference to FIG. FIG. 2 is a flowchart of communication control in the communication system according to the first embodiment.

  The control unit 12 performs extraction control of the wireless communication device 2 (step S301).

  Next, the control unit 12 performs communication control to instruct the communication unit 11 to notify the communication unit 11 of information extracted to the wireless communication device 2 (step S302).

  The communication unit 11 transmits information on the first section and the second section to the wireless communication device 2 extracted by the control unit 12 (step S303).

  Thereafter, the communication unit 11 transmits the signal # 1 to the wireless communication device 2 extracted by the control unit 12 (step S304). The signal # 1 is, for example, activation.

  And the communication part 11 and the control part 12 perform communication control, such as transmission / reception of the data between the radio | wireless communication apparatuses 2, (step S305).

  Thereafter, the communication unit 11 transmits the signal # 2 to the wireless communication device 2 and ends the communication (step S306). The signal # 2 is, for example, a release signal.

  As described above, in the wireless communication system according to the present embodiment, the wireless communication device 1 satisfies the predetermined condition between the first section that represents the cycle and the second section that communicates with each wireless communication device 2. To the wireless communication device 2. Thereafter, the wireless communication device 1 transmits the first control signal collectively to the wireless communication device 2 that satisfies the predetermined condition, and then transmits and receives data in the designated second section. Thereby, the transmission of PDCCH to each of the wireless communication devices 2 can be reduced. Therefore, the overhead of PDCCH can be reduced and the utilization efficiency of radio resources can be improved.

  Next, Example 2 will be described. FIG. 3 is a schematic diagram of a wireless communication system according to the second embodiment. In the wireless communication system according to the present embodiment, a plurality of MTC devices 200 are present in the cell of the base station 100. The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  FIG. 4 is a block diagram of the wireless communication apparatus according to the second embodiment. The base station 100 in FIG. 4 corresponds to the wireless communication apparatus 1 in FIG. Also, the MTC device 200 in FIG. 4 corresponds to the wireless communication apparatus 2 in FIG.

  As illustrated in FIG. 4, the base station 100 includes a communication unit 11 and a control unit 12. The communication unit 11 includes a reception unit 111 and a transmission unit 112. Further, the control unit 12 includes a group generation unit 121 and a subframe allocation unit 122. In the following description, the downlink communication and the uplink communication are divided into cases.

(For downlink communication)
In this embodiment, the group generation unit 121 stores a predetermined period in advance, for example. The group generation unit 121 receives the identification information of the MTC device 200 that has received random access from the reception unit 111. And the group production | generation part 121 groups the MTC device 200 which received random access during the fixed period memorize | stored beforehand.

  As an example, the group generation unit 121 sequentially groups the MTC devices 200 that have received random access during a certain period for each certain period. For example, like the groups 31 to 35 in FIG. 3, the group generation unit 121 groups the MTC devices 200.

  As another example, it can be grouped by radio quality. For example, MTC devices 200 that exhibit similar radio quality as a result of receiving UCI and SRS can be grouped. The grouping may be performed not in units of MTC devices but in units of downlink / uplink of MTC devices. Therefore, even the same MTC device may belong to different groups for downlink communication and uplink communication.

  For each generated group, group generation unit 121 transmits identification information of MTC device 200 included in the group to subframe allocation unit 122.

  The subframe allocation unit 122 receives the identification information of the MTC device 200 included in the group for each group from the group generation unit 121. Hereinafter, processing of the subframe allocation unit 122 for a certain group (hereinafter referred to as “target group”) will be described. The subframe allocation unit 122 performs the same processing for other groups than the target group.

  The subframe allocation unit 122 determines a subframe to be used for communication with the MTC device 200 of the target group included in the SPS communication cycle from the number of MTC devices 200 included in the target group. For example, when there are eight MTC devices 200, the subframe allocation unit 122 determines that eight subframes are used for communication with the MTC device 200 of the target group in one cycle of the SPS communication cycle.

  Then, the subframe allocation unit 122 allocates a subframe that is included in one cycle of SPS communication and performs data communication without PDCCH to any MTC device 200 included in the target group. Then, the subframe allocation unit 122 generates, for each MTC device 200, subframe designation information indicating which subframe is allocated to each MTC device 200 in the target group in one cycle of the SPS communication. . This subframe corresponds to an example of “a plurality of sections”. In addition, a section in which subframes allocated to the MTC device 200 are collected corresponds to an example of “first section”. Information indicating a section in which subframes allocated to the MTC device 200 in the SPS communication cycle are collected corresponds to an example of “first information”. Further, the subframe assigned to each MTC device 200 corresponds to an example of “second section”.

  For example, the subframe allocation unit 122 generates subframe designation information having a bit map that represents each subframe included in one period of the SPS communication with bits and indicates the allocated subframes with bits. Specifically, when eight subframes are included in the SPS communication cycle and the second subframe from the top is allocated to a certain MTC device 200, the subframe allocation unit 122, for example, (0 , 1, 0, 0, 0, 0, 0, 0). In this case, the subframe designation information represents eight subframes included in the SPS communication cycle with eight bits, and represents a subframe assigned to the MTC device 200 with a bit having a value of “1”. This subframe designation information corresponds to an example of “second information”.

  Then, the subframe allocation unit 122 uses the generated subframe designation information in LTE such as identification information (for example, C-RNTI, S-TMSI, IMSI, etc.) of the MTC device 200 corresponding to the subframe designation information. Terminal identification information) to the transmission unit 112. In addition, the subframe allocation unit 122 notifies the transmission unit 112 of the SPS communication cycle.

  The transmission unit 112 performs paging on the MTC device 200 and transmits a command for executing random access. This is because in LTE and LTE-Advanced, a terminal that has received paging responds to paging indicating data arrival.

  In addition, the transmission unit 112 displays subframe designation information indicating a subframe in the SPS communication cycle assigned to each MTC device 200 included in the target group, together with identification information of the MTC device 200 corresponding to the subframe designation information. Received from the assigning unit 122. In addition, the transmission unit 112 receives the SPS communication cycle in the target group from the subframe allocation unit 122.

  Then, the transmission unit 112 notifies all MTC devices 200 belonging to the target group of the SPS communication cycle in the target group and the section used for communication with the MTC device 200 of the target group in the SPS communication cycle, and A cycle is set for the device 200. The transmission unit 112 performs notification of the SPS communication cycle and the section used for communication with the MTC device 200 using, for example, RRC layer signaling (control signal).

  Further, the transmission unit 112 transmits the subframe designation information received from the subframe allocation unit 122 to the MTC device 200 corresponding to the subframe.

  Then, the transmitting unit 112 first transmits a subframe in which the activation notification is stored, and transmits data to each MTC device 200 belonging to the target group using the subsequent subframe. In this case, the transmission unit 112 transmits data to each MTC device 200 to which the subframe is assigned using each subframe. A subframe in which this activation is transmitted corresponds to an example of a “section for receiving a control signal”.

  Thereafter, when the MTC device 200 fails to receive data, the transmission unit 112 receives a data retransmission request from the reception unit 111. In this case, the transmission unit 112 transmits retransmission data to the MTC device 200 with a PDCCH that is a control signal.

  The transmission unit 112 repeats the SPS communication using the subframe assigned to each MTC device 200 of the target group until the data transmission is completed. When the data transmission is completed, the transmitting unit 112 notifies the release to all the MTC devices 200 belonging to the target group using the same radio resource, and ends the SPS communication. However, the present invention is not limited to this, and the MTC device may be released individually.

  The receiving unit 111 receives random access from the MTC device 200. Then, the reception unit 111 transmits identification information of the MTC device 200 that has received the random access to the control unit 12.

  Thereafter, in downlink communication, the reception unit 111 receives ACK (ACKnowledgement) or NACK (Negative ACKnowledgement) from the MTC device 200 as a response to data transmission by the transmission unit 112. When a NACK is received, the reception unit 111 notifies the transmission unit 112 of a data retransmission request for which a NACK response has returned. The retransmission is performed by HARQ (Hybrid Automatic Repeat Request).

  The operation flow of each unit in the communication control described above will be described collectively after the operation of each unit of all devices included in the wireless communication system.

(For upstream communication)
The group generation unit 121 groups the MTC devices 200 as in the case of downlink communication. Then, for each generated group, group generation unit 121 transmits identification information of MTC device 200 included in the group to subframe allocation unit 122.

  Similarly to the case of downlink communication, the subframe allocation unit 122 determines the SPS communication cycle and further generates subframe designation information for each MTC device 200. Then, the subframe allocation unit 122 transmits the generated subframe designation information to the transmission unit 112 together with the identification information of the MTC device 200 corresponding to the subframe designation information. In addition, the subframe allocation unit 122 notifies the transmission unit 112 of the SPS communication cycle.

  The transmission unit 112 receives the subframe designation information from the subframe allocation unit 122 together with the identification information of the MTC device 200. In addition, the transmission unit 112 receives the SPS communication cycle in the target group from the subframe allocation unit 122.

  Then, the transmission unit 112 notifies the SPS communication cycle in the target group to all the MTC devices 200 belonging to the target group, and further, the subframe designation information received from the subframe allocation unit 122 corresponds to the subframe. Transmit to the MTC device 200.

  Then, the transmitting unit 112 transmits the subframe storing the activation notification to all the MTC devices 200 belonging to the target group using the same radio resource.

  Thereafter, when the reception unit 111 successfully receives data from the MTC device 200, the transmission unit 112 transmits an ACK to the MTC device 200 that is the data transmission source. On the other hand, when the reception unit 111 fails to receive data from the MTC device 200, the transmission unit 112 transmits a NACK to the MTC device 200 that has failed to receive data. After that, the transmitting unit 112 transmits a PDCCH to the MTC device 200 that is the transmission destination of the NACK and notifies the radio resources used for data retransmission. This PDCCH is an example of a “second control signal”.

  When the data reception is completed, the transmission unit 112 notifies the release to all the MTC devices 200 belonging to the target group using the same radio resource, and ends the SPS communication.

  The receiving unit 111 receives a random access from the MTC device 200 in which transmission data is generated. Then, the reception unit 111 transmits identification information of the MTC device 200 that has received the random access to the control unit 12.

  Then, the reception unit 111 receives data from each MTC device 200 by using the subframe assigned to each MTC device 200 in the SPS communication cycle started after activation.

  In addition, the reception unit 111 notifies the transmission unit 112 of success or failure of data reception. If the data reception fails, then the reception unit 111 receives data retransmission from the MTC device 200 using the radio resource specified by the transmission unit 112 using the PDCCH. Then, the reception unit 111 generates reception data by combining the data that has failed to be received and the data that has been received through retransmission. Here, retransmission is performed by HARQ (Hybrid Automatic Repeat Request).

  The operation flow of each unit in the communication control described above will be described collectively after the operation of each unit of all devices included in the wireless communication system.

  As illustrated in FIG. 4, the MTC device 200 includes a communication unit 21 and a control unit 22. The communication unit 21 includes a reception unit 211 and a transmission unit 212. In the following description, the downlink communication and the uplink communication are divided into cases.

(For downlink communication)
The reception unit 211 receives paging from the transmission unit 112 of the base station 100. Then, the reception unit 211 notifies the transmission unit 212 that the paging has been received.

  Thereafter, the reception unit 211 receives the SPS communication cycle and subframe designation information from the transmission unit 112 of the base station 100. The reception unit 211 notifies the transmission unit 212 and the control unit 22 of the received SPS communication cycle. In addition, the reception unit 211 transmits the received subframe designation information to the control unit 22. Then, the reception unit 211 receives from the control unit 22 a notification of a subframe used for reception of data by the own device in the SPS communication cycle and the SPS communication cycle.

  Thereafter, the reception unit 211 receives the activation from the transmission unit 112 of the base station 100. For example, the MTC devices 200 belonging to the same group receive activation using the same radio resource. Then, the reception unit 211 notifies the control unit 22 of activation.

  Thereafter, the reception unit 211 receives data from the transmission unit 112 of the base station 100 using a subframe assigned to the own apparatus in the SPS communication cycle started from the timing at which the activation is received. Here, the reception unit 211 notifies the transmission unit 212 of the success or failure of data reception. Needless to say, activation may be performed using different radio resources.

  When the data reception fails, the reception unit 211 receives the PDCCH from the transmission unit 112 of the base station 100. Then, the reception unit 211 receives retransmission data from the transmission unit 112 of the base station 100 using the radio resource specified by the received PDCCH. Then, the reception unit 211 performs HARQ combining (data combining) using the data that has failed to be received and the data that has been received through retransmission, and generates received data. Retransmission is performed by HARQ.

  Further, the reception unit 211 receives the release from the transmission unit 112 of the base station 100. Then, the reception unit 211 notifies the control unit 22 of the release.

  The transmission unit 212 receives a notification that the paging has been received from the reception unit 211. Next, the transmission unit 212 transmits random access to the base station 100.

  Then, after the activation, the transmission unit 212 receives the success or failure of data reception from the reception unit 211. When the data reception is successful, the transmission unit 212 transmits ACK to the reception unit 111 of the base station 100. On the other hand, when data reception fails, the transmission unit 212 transmits NACK to the reception unit 111 of the base station 100.

  The control unit 22 receives the SPS communication cycle and subframe designation information from the reception unit 211. Next, the control unit 22 identifies the subframe assigned to the own device in the SPS communication cycle. Then, the control unit 22 notifies the reception unit 211 of information on subframes in the SPS communication cycle and the identified SPS communication cycle.

  In addition, the control unit 22 receives an activation notification from the reception unit 211. And the control part 22 makes the communication part 21 the state which can communicate.

  Thereafter, the control unit 22 receives a release notification from the reception unit 211. And the control part 22 makes the communication part 21 a standby state.

  The operation flow of each unit in the communication control described above will be described collectively after the operation of each unit of all devices included in the wireless communication system.

(For upstream communication)
The reception unit 211 receives the SPS communication cycle and subframe designation information from the transmission unit 112 of the base station 100. Then, the reception unit 211 notifies the transmission unit 212 and the control unit 22 of the received SPS communication cycle. In addition, the reception unit 211 transmits the received subframe designation information to the control unit 22.

  Thereafter, the reception unit 211 receives the activation from the transmission unit 112 of the base station 100. For example, the MTC devices 200 belonging to the same group receive activation using the same radio resource. Then, the reception unit 211 notifies the control unit 22 of activation. Needless to say, activation may be performed using different radio resources.

  Thereafter, the reception unit 211 receives ACK or NACK from the transmission unit 112 of the base station 100. When receiving the NACK, the reception unit 211 transmits a retransmission request to the transmission unit 212.

  Further, the reception unit 211 receives the release from the transmission unit 112 of the base station 100. Then, the reception unit 211 notifies the control unit 22 of the release.

  The transmission unit 212 transmits random access to the base station 100 when transmission data is generated.

  Thereafter, the transmission unit 212 receives from the control unit 22 a notification of a subframe used by the own device for receiving data in the SPS communication cycle and the SPS communication cycle. Then, the transmission unit 212 transmits data to the reception unit 111 of the base station 100 using the subframe assigned to the own device.

  In addition, the transmission unit 212 receives a retransmission request from the reception unit 211. Thereafter, the transmission unit 212 receives the PDCCH from the transmission unit 112 of the base station 100. And the transmission part 212 resends data using the radio | wireless resource designated by PDCCH.

  The control unit 22 receives the SPS communication cycle and subframe designation information from the reception unit 211. Next, the control unit 22 identifies the subframe assigned to the own device in the SPS communication cycle. Then, the control unit 22 notifies the transmission unit 212 of subframe information in the SPS communication cycle and the identified SPS communication cycle.

  In addition, the control unit 22 receives an activation notification from the reception unit 211. And the control part 22 makes the communication part 21 the state which can communicate.

  Thereafter, the control unit 22 receives a release notification from the reception unit 211. And the control part 22 makes the communication part 21 a standby state.

  The operation flow of each unit in the communication control described above will be described collectively after the operation of each unit of all devices included in the wireless communication system.

  Next, communication control in downlink communication will be described collectively with reference to FIG. FIG. 5 is a sequence diagram of communication control in downlink communication in the communication system according to the second embodiment. FIG. 5 shows that time elapses as it goes to the right. Here, the case where n MTC devices 200 are grouped will be described, and in FIG. 5, three of them are shown as MTC devices 201 to 203. In the following, all n MTC devices 200 are represented as MTC devices 201-203.

  Base station 100 transmits paging to each of MTC devices 201-203. Each MTC device 201-203 transmits random access (RA) to the base station 100. The base station 100 receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S101).

  The base station 100 transmits the SPS communication period and subframe designation information to each MTC device 201-203. Here, base station 100 transmits an SPS communication cycle including 8 subframes. In addition, the base station 100 transmits a bitmap specifying the first subframe to the MTC device 201. For example, the base station 100 transmits a bitmap (1, 0, 0, 0, 0, 0, 0, 0) to the MTC device 201. In addition, the base station 100 transmits a bitmap specifying the second subframe to the MTC device 202. For example, the base station 100 transmits a bitmap (0, 1, 0, 0, 0, 0, 0, 0) to the MTC device 202. Also, the base station 100 transmits a bitmap specifying the last subframe to the MTC device 203. For example, the base station 100 transmits a bitmap (0, 0, 0, 0, 0, 0, 0, 1) to the MTC device 203. Then, the MTC devices 201 to 203 set the SPS communication cycle (step S102).

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S103).

  Furthermore, the base station 100 transmits data to the MTC device 201 using the first subframe of the SPS communication cycle started after activation (step S104). Further, the base station 100 transmits data to the MTC device 202 using the second subframe of the SPS communication cycle (step S105).

  The base station 100 receives ACK or NACK from the MTC devices 201 and 202 as a response to data transmission. Here, it is assumed that the MTC device 201 has successfully received data. The MTC device 201 transmits ACK to the base station 100. The base station 100 receives ACK from the MTC device 201 (step S106). It is assumed that the MTC device 202 has failed to receive data. The MTC device 202 transmits a NACK to the base station 100. The base station 100 receives NACK from the MTC device 202 (step S107).

  As described above, the base station 100 sequentially performs communication with each of the MTC devices 201 to 203. Then, base station 100 transmits data to MTC device 203 using the last subframe of the SPS communication cycle (step S108). Although not shown in FIG. 5, the MTC device 203 transmits ACK or NACK to the base station 100.

  Furthermore, base station 100 transmits PDCCH that is control information of retransmission data to MTC device 202 that is the transmission source of NACK (step S109). Then, the base station 100 retransmits data to the MTC device 202 using the radio resource specified by the PDCCH (step S110). Here, in FIG. 5, the retransmission data is described side by side with the data transmitted using the already determined SPS communication cycle, but the radio resource used for the retransmission data is the same as that of the already determined SPS communication cycle. Radio resources other than radio resources can be selected.

  Here, in FIG. 5, only communication in one SPS communication cycle is described, but the base station 100 and the MTC devices 201 to 203 repeat SPS communication until data transmission is completed.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S111). The MTC devices 201-203 receive the release and transition to the standby state. The standby state includes an RRC connected mode and an RRC idle mode. In the RRC connected mode, there are a state where PDCCH monitoring is essential (ACTIVE_TIME in DRX mode) and a state where PDCCH monitoring is not essential (non-ACTVEI_TIME in DRX mode). Further, in the RRC idle mode, the MTC device 200 is in a state after receiving an RRC release (RRC Connection Release) from the base station 100.

  Here, a flow of communication control in downlink communication in the communication system according to the second embodiment will be described with reference to FIG. FIG. 6 is a flowchart of communication control in downlink communication in the communication system according to the second embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S1).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S2).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S3). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Further, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S4). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S5). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  And the communication part 11 of the base station 100 communicates with each MTC device 200 using the sub-frame designated by sub-frame designation | designated information (step S6).

  The receiving unit 111 of the base station 100 determines whether a retransmission request has been received from each MTC device 200, that is, whether a NACK has been received (step S7). When the retransmission request has not been received (step S7: No), the base station 100 proceeds to step S9.

  On the other hand, when the retransmission request is received (step S7: Yes), the transmission unit 112 of the base station 100 transmits the data to the MTC device 200 that is the transmission source of the retransmission request with the PDCCH attached (step S7). S8).

  The transmission unit 112 of the base station 100 determines whether data transmission is completed (step S9). When the data transmission has not been completed (No at Step S9), the base station 100 returns to Step S6.

  On the other hand, when data transmission is completed (step S9: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S10). The receiving unit 211 of the MTC device 200 receives the release and transitions to a standby state.

  Next, communication control in uplink communication will be described collectively with reference to FIG. FIG. 7 is a sequence diagram of communication control in uplink communication in the communication system according to the second embodiment.

  Each MTC device 201-203 in which transmission data has been generated transmits random access (RA) to the base station 100. The base station 100 receives the random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S121).

  The base station 100 transmits the SPS communication period and subframe designation information to each MTC device 201-203. Here, base station 100 transmits an SPS communication cycle including 8 subframes. In addition, the base station 100 transmits a bitmap specifying the first subframe to the MTC device 201. In addition, the base station 100 transmits a bitmap specifying the second subframe to the MTC device 202. Also, the base station 100 transmits a bitmap specifying the last subframe to the MTC device 203. Then, the MTC devices 201 to 203 set the SPS communication cycle (step S122).

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S123).

  The MTC device 201 transmits data to the base station 100 using the first subframe of the SPS communication cycle started after activation (step S124). In addition, the MTC device 202 transmits data to the base station 100 using the second subframe of the SPS communication cycle (step S125).

  The base station 100 transmits ACK or NACK to the MTC devices 201 and 202 as a response to data transmission. Here, it is assumed that the base station 100 has successfully received data from the MTC device 201. The base station 100 transmits ACK to the MTC device 201. The MTC device 201 receives ACK from the base station 100 (step S126). Further, it is assumed that the base station 100 fails to receive data from the MTC device 202. Base station 100 transmits NACK to MTC device 202. The MTC device 202 receives NACK from the base station 100 (step S127).

  As described above, each MTC device 201 to 203 sequentially performs communication with the base station 100 using the assigned subframe. Then, the MTC device 203 transmits data to the base station 100 using the last subframe of the SPS communication cycle (step S128). Although not shown in FIG. 7, the MTC device 203 receives ACK or NACK from the base station 100.

  Furthermore, the base station 100 transmits PDCCH that is control information of retransmission data to the MTC device 202 that has transmitted NACK (step S129). Then, the MTC device 202 retransmits data to the base station 100 using the radio resource specified by the PDCCH (step S130).

  Here, in FIG. 7, only communication in one SPS communication cycle is described, but the base station 100 and the MTC devices 201 to 203 repeat SPS communication until data transmission is completed.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S131). The MTC devices 201-203 receive the release and transition to the standby state. The standby state includes an RRC connected mode and an RRC idle mode. In the RRC connected mode, there are a state where PDCCH monitoring is essential (ACTIVE_TIME in DRX mode) and a state where PDCCH monitoring is not essential (non-ACTVEI_TIME in DRX mode). Further, in the RRC idle mode, the MTC device 200 is in a state after receiving an RRC release (RRC Connection Release) from the base station 100.

  Here, with reference to FIG. 8, the flow of communication control in uplink communication in the communication system according to the second embodiment will be described together. FIG. 8 is a flowchart of communication control in uplink communication in the communication system according to the second embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S11).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S12).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S13). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Further, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S14). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S15). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Then, the communication unit 21 of each MTC device 200 sequentially communicates with the base station 100 using the subframe specified by the subframe specifying information (step S16).

  The receiving unit 211 of each MTC device 200 determines whether a retransmission request has been received from the base station 100, that is, whether a NACK has been received (step S17). If the retransmission request has not been received (No at Step S17), the MTC device 200 proceeds to Step S20.

  On the other hand, when the reception unit 211 of the MTC device 200 has received the retransmission request (step S17: Yes), the reception unit 211 of the MTC device 200 waits for reception of the PDCCH. The transmission unit 112 of the base station 100 transmits the PDCCH to the MACK device 200 that is the NACK transmission destination (step S18).

  When the reception unit 211 of the MTC device 200 receives the PDCCH, the transmission unit 212 retransmits data to the base station 100 using the radio resource specified by the PDCCH (step S19).

  The transmission unit 212 of each MTC device 200 determines whether data transmission is completed (step S20). If the data transmission has not been completed (No at Step S20), the MCT device 200 returns to Step S16.

  On the other hand, when data transmission is completed (step S20: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S21). The receiving unit 211 of the MTC device 200 receives the release, and the communication unit 12 transitions to a standby state.

  Here, a conventional radio communication system that transmits a PDCCH that is a control signal for each SPS communication cycle is compared with the radio communication system according to the present embodiment. Here, the case where X packet transmission / reception is performed will be described. Further, a case where the data retransmission probability is 10% will be described.

  A conventional wireless communication system transmits a PDCCH, which is a control signal, X times by initial transmission of data. Furthermore, the conventional wireless communication system transmits a PDCCH that is a control signal 0.1 × X times by data retransmission. That is, the conventional wireless communication system performs PDCCH transmission 1.1X times in this case.

  In contrast, the wireless communication system according to the present embodiment does not transmit the PDCCH that is the control signal in the initial transmission of data. Also, the radio communication system according to the present embodiment transmits the PDCCH that is a control signal 0.1 × X times by data retransmission. That is, in this case, the radio communication system according to the present embodiment performs PDCCH transmission 0.1X times.

  From the above, in the radio communication system according to the present embodiment, for example, the number of PDCCH transmissions associated with data transmission can be suppressed to about 9% of the conventional radio communication system.

  As described above, the base station according to the present embodiment groups the MTC devices, notifies each different MTC device in the SPS communication period to each MTC device belonging to the group, and uses each notified subframe to Communicate with the MTC device. Thereby, the base station can communicate with the MTC device without transmitting the PDCCH, and can reduce the overhead of the PDCCH. For this reason, the radio | wireless communications system which concerns on a present Example can improve the utilization efficiency of a radio | wireless resource.

  Next, Example 3 will be described. The wireless communication system according to the present embodiment is different from the second embodiment in that, when there is no transmission data in SPS communication, the set wireless resource is diverted to another device. The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  The wireless communication system according to the present embodiment is also represented by the block diagram of FIG. In the following, the description of the function of each part similar to the second embodiment will be omitted. Hereinafter, the case of downlink communication and the case of uplink communication will be described separately.

(For downlink communication)
The transmission unit 112 of the base station 100 determines whether there is data to be transmitted for each MTC device 200 in each SPS communication cycle. When there is data to be transmitted, the transmission unit 112 transmits the data to the MTC device 200.

  On the other hand, when there is no transmission data, the transmission part 112 uses the radio | wireless resource allocated to the MTC device 200 with no data to transmit for another communication. At this time, the transmission unit 112 receives a NACK from the MTC device 200 that uses the allocated radio resource for other communication. This is because the MTC device 200 expects to receive downlink data addressed to itself, and therefore attempts to demodulate the data on the set resource, but in reality, the resource is used by another terminal. This is because data cannot be demodulated and a CRC error occurs and NACK is returned.

  In addition, when data to be transmitted to the MTC device 200 that uses the radio resource in the SPS communication cycle for other communication occurs, the transmission unit 112 receives the NACK from the MTC device 200, so Transmit to the MTC device 200. Then, the transmission unit 112 transmits data to the MTC device 200 using the radio resource specified by the PDCCH. Thereafter, the transmission unit 112 transmits data to the MTC device 200 by using again the radio resource of the SPS communication period allocated to the MTC device 200.

  When the radio resource allocated to the MTC device 200 is used for other communication, the reception unit 111 of the base station 100 receives a NACK from the MTC device 200 to which the radio resource is allocated. Then, the reception unit 111 transmits a retransmission request to the transmission unit 112.

  When there is no data transmitted from the base station 100 in the subframe assigned to the own apparatus in the SPS communication cycle, the reception unit 211 of the MTC device 200 accumulates the data received in the subframe in the buffer.

  And the receiving part 211 will receive data using the radio | wireless resource designated by the PDCCH, if PDCCH which the transmission part 112 of the base station 100 transmitted is received. The receiving unit 211 then combines the received data with the data stored in the buffer, and receives the data. If the PDCCH is not received, the reception unit 211 determines that the buffered data is data addressed to another terminal in the next SPS communication cycle, clears the buffer, and receives new data.

  Next, a flow of communication control in downlink communication in the communication system according to the third embodiment will be described with reference to FIG. FIG. 9 is a flowchart of communication control in downlink communication in the communication system according to the third embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S401).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S402).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S403). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Further, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S404). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S405). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Next, the transmission unit 112 of the base station 100 determines whether there is an MTC device 200 that has no transmission data to send (step S406). When there is an MTC device 200 with no data to be sent (step S406: Yes), the transmission unit 112 diverts the subframe to communication with another device (step S407). On the other hand, when there is an MTC device 200 with no data to be transmitted (No at Step S406), the transmission unit 112 proceeds to Step S408.

  Then, the communication unit 11 of the base station 100 communicates with each MTC device 200 using the subframe specified by the subframe specifying information (step S408).

  In addition, the transmission unit 112 of the base station 100 determines whether or not transmission data has been generated for the MTC device 200 in which the allocated subframe has already been diverted (step S409). When transmission data is generated (step S409: Yes), the transmission unit 112 transmits data to the MTC device 200 with the PDCCH attached (step S410).

  Further, the reception unit 111 of the base station 100 determines whether a retransmission request has been received from each MTC device 200, that is, whether a NACK has been received (step S411). When the retransmission request has not been received (No at Step S411), the base station 100 proceeds to Step S413.

  On the other hand, when the retransmission request is received (step S411: Yes), the transmission unit 112 of the base station 100 transmits the data to the MTC device 200 that is the transmission source of the retransmission request with the PDCCH attached (step S411). S412).

  The transmission unit 112 of the base station 100 determines whether data transmission is completed (step S413). When the data transmission is not completed (Step S413: No), the base station 100 returns to Step S406.

  On the other hand, when the data transmission is completed (step S413: Yes), the transmission unit 112 of the base station 100 transmits the release to the MTC device 200 (step S414). The receiving unit 211 of the MTC device 200 receives the release and transitions to a standby state.

(For upstream communication)
When there is no data to be transmitted, the transmission unit 212 of the MTC device 200 transmits to the reception unit 111 of the base station 100 that the data retention amount is 0 by BSR (Buffer Status Report) to the reception unit 111 of the base station 100. . Thereafter, the transmission unit 212 receives a notification of ACK reception from the reception unit 111.

  Then, when transmission data is generated, the transmission unit 212 transmits an SR (Scheduling Request) to the reception unit 111 of the base station 100 to notify that data transmission is performed using the allocated subframe. Thereafter, the transmission unit 212 transmits data using the subframe assigned in the next SPS communication cycle.

  The reception unit 211 of the MTC device 200 receives the NACK from the base station 100 after the transmission unit 212 transmits the BSR. Then, the reception unit 211 notifies the transmission unit 212 of reception of NACK.

  The reception unit 111 of the base station 100 receives the BSR from the transmission unit 212 of the MTC device 200 when there is no uplink transmission data. As a result of receiving the BSR, when it is found that there is no data retention amount of the MTC device 200, it is found that the MTC device 200 does not hold the transmission data, so that the resource can be diverted to other users. The reception unit 111 notifies the transmission unit 112 of reception of the BSR. Then, from the next SPS communication cycle, the reception unit 111 uses the radio resource allocated to the MTC device 200 that is the transmission source of the BSR for other communication.

  Thereafter, when transmission data is generated in the MTC device 200 in which the assigned subframe is used for other communication, the reception unit 111 receives the SR from the transmission unit 212 of the MTC device 200. Then, in the next SPS communication cycle, the reception unit 111 resumes reception using the subframe to which data from the MTC device 200 that is the SR transmission source is assigned.

  When receiving the BSR reception notification from the reception unit 111, the transmission unit 112 of the base station 100 transmits a NACK to the MTC device 200 that is the transmission source of the BSR.

  Next, with reference to FIG. 10, the flow of communication control in uplink communication in the communication system according to the third embodiment will be described together. FIG. 10 is a flowchart of communication control in uplink communication in the communication system according to the third embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S421).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S422).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S423). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Also, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S424). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S425). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Then, the communication unit 21 of each MTC device 200 sequentially communicates with the base station 100 using the subframe specified by the subframe specifying information (step S426).

  At this time, the receiving unit 111 of the base station 100 determines whether or not a BSR is received from the MTC device 200 (step S427). When the BSR is received (step S427: affirmative), the transmission unit 112 diverts the allocated subframe to communication with another device (step S428). On the other hand, when the BSR has not been received (No at Step S427), the base station apparatus 100 proceeds to Step S429.

  In addition, the reception unit 111 of the base station 100 determines whether or not an SR has been received from the MTC device 200 (step S429). When the SR is received (step S429: Yes), the transmission unit 112 returns the subframe to the communication with the MTC device 200 in which the allocated subframe has already been diverted (step S430). On the other hand, when the SR is not received (No at Step S429), the base station device 100 proceeds to Step S431.

  The receiving unit 211 of each MTC device 200 determines whether a retransmission request has been received from the base station 100, that is, whether a NACK has been received (step S431). When the retransmission request has not been received (No at Step S431), the MTC device 200 proceeds to Step S434.

  On the other hand, when the reception unit 211 of the MTC device 200 has received a retransmission request (step S431: Yes), the reception unit 211 of the MTC device 200 waits for reception of the PDCCH. The transmission unit 112 of the base station 100 transmits the PDCCH to the MTC device 200 that is the NACK transmission destination (step S432).

  When the reception unit 211 of the MTC device 200 receives the PDCCH, the transmission unit 212 retransmits data to the base station 100 using the radio resource specified by the PDCCH (step S433).

  The transmission unit 212 of each MTC device 200 determines whether or not data transmission is completed (step S434). When the data transmission has not been completed (No at Step S434), the MCT device 200 returns to Step S426.

  On the other hand, when data transmission is completed (step S434: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S435). The receiving unit 211 of the MTC device 200 receives the release, and the communication unit 12 transitions to a standby state.

  Next, communication control in the case of downlink communication will be described collectively with reference to FIG. FIG. 11 is a sequence diagram of communication control in downlink communication in the communication system according to the third embodiment. Here, a case where there is no transmission data to the MTC device 202 will be described.

  The base station 100 transmits paging, and then receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S141).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information to the MTC devices 201 to 203 (step S142). Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S143).

  Furthermore, the base station 100 transmits data to the MTC device 201 using the first subframe of the SPS communication cycle started after activation (step S144).

  On the other hand, the base station 100 diverts the second subframe of the SPS communication cycle to other communication. In this case, as represented by “null” in FIG. 11, the MTC device 202 does not receive the transmission data from the base station 100, but receives other data (step S145). Specifically, although the MTC device 202 considers that there is data addressed to itself and tries to demodulate the data, the base station 100 actually transmits data addressed to other terminals. Demodulation fails and a CRC error occurs. That is, the receiving unit receives noise. As a matter of course, since a CRC error has occurred, NACK is returned.

  The base station 100 receives ACK from the MTC device 201 (step S146). Further, the base station 100 receives NACK from the MTC device 202 (step S147).

  Further, the base station 100 transmits data to the MTC device 203 using the last subframe of the SPS communication cycle (step S148).

  Furthermore, when transmission data is generated, the base station 100 transmits the data with the PDCCH attached (step S149). When receiving the PDCCH, the MTC device 202 performs composition and receives data. On the other hand, when no transmission data is generated, base station 100 does not transmit data accompanied by PDCCH. In this case, since the MTC device 202 does not receive the PDCCH, the MTC device 202 clears the buffer in the next SPS communication cycle and newly receives data (step S150). In FIG. 11, dotted lines are used to represent both cases where transmission data is generated and cases where transmission data is not generated.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S151). The MTC devices 201-203 receive the release and transition to the standby state.

  Next, communication control in the case of uplink communication will be described collectively with reference to FIG. FIG. 12 is a sequence diagram of communication control in uplink communication in the communication system according to the third embodiment. Here, a case where there is no transmission data to the MTC device 202 will be described.

  The base station 100 receives the random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S161).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information to the MTC devices 201 to 203 (step S162). Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S163).

  The MTC device 201 transmits data to the base station 100 using the first subframe of the SPS communication cycle started after activation (step S164).

  On the other hand, the MTC device 202 transmits the BSR to the base station 100 using the second subframe of the SPS communication cycle (step S165). The base station 100 receives the BSR from the MTC device 202 and diverts the second subframe of the SPS communication period to other communication.

  The base station 100 transmits ACK to the MTC device 201 (step S166). Further, the base station 100 transmits ACK to the MTC device 202 (step S167).

  In addition, the MTC device 203 transmits data to the base station 100 using the last subframe of the SPS communication cycle (step S168).

  Thereafter, when transmission data is generated, the MTC device 202 transmits an SR (step S169). Thereafter, the MTC device 202 transmits data using the subframe allocated in the next SPS communication cycle (step S170).

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S171). The MTC devices 201-203 receive the release and transition to the standby state.

  As described above, the radio communication system according to the present embodiment diverts the set radio resource to another device when there is no transmission data to the MTC device to which the radio resource is allocated in the SPS communication. Thereby, the radio | wireless communications system which concerns on a present Example can reduce the radio | wireless resource which is not used, and can improve the utilization efficiency of a radio | wireless resource.

  Next, Example 4 will be described. The wireless communication system according to the present embodiment is different from the second embodiment in that communication is performed using multi-user MIMO (Multi Input Multi Output). The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  The wireless communication system according to the present embodiment is also represented by the block diagram of FIG. In the following, the description of the function of each part similar to the second embodiment will be omitted. Hereinafter, the case of downlink communication and the case of uplink communication will be described separately.

(For downlink communication)
The transmission unit 112 of the base station 100 orthogonalizes the transmission data of each MTC device 200 by making the cyclic shift amount different from the orthogonal code (sequence) such as the Zadoff-Chu Sequence base. Thereby, the base station 100 can multiplex data transmission to the plurality of MTC devices 200 and can simultaneously transmit data to the plurality of MTC devices 200. Therefore, for example, when data transmission to the two MTC devices 200 is multiplexed, twice the data can be transmitted using the same SPS communication cycle as in the second embodiment.

  Then, when the reception unit 111 receives a notification of reception of NACK from any of the MTC devices 200 in which data transmission is multiplexed, the transmission unit 112 transmits the PDCCH only to the MTC device 200 that is the transmission source of NACK.

  Thereafter, the transmission unit 112 retransmits data to the MTC device 200 that is the transmission source of the NACK, using the radio resource specified by the PDCCH.

  The receiving unit 111 of the base station 100 receives ACK or NACK information in a multiplexed state from all of the MTC devices 200 that multiplexed the data transmission. Then, the reception unit 111 notifies the transmission unit 112 of success or failure of data reception of each MTC device 200.

  The reception unit 211 of the MTC device 200 receives the data multiplexed and transmitted from the base station 100 in the subframe assigned to the own device in the SPS communication cycle.

  Then, the transmission unit 212 of the MTC device 200 multiplexes ACK or NACK and transmits the multiplexed ACK or NACK to the reception unit 111 of the base station 100.

  The operation flow of each unit in downlink communication between the base station 100 and the MTC device 200 in the radio communication system according to the present embodiment described above is the same as that in FIG. 6 except that communication is performed using MIMO. .

(For upstream communication)
The transmission unit 112 of the base station 100 assigns an orthogonal code to each MTC device 200. Then, the transmission unit 112 of the base station 100 transmits the code information assigned so that data can be multiplexed and transmitted to each MTC device 200 belonging to the group.

  Thereafter, when receiving a data reception failure notification from the reception unit 111, the transmission unit 112 transmits a NACK to the MTC device 200 that is the transmission source of the data that has failed to be received. Then, the transmission part 112 transmits PDCCH to the MTC device 200 of the transmission destination of NACK. Then, the transmission unit 112 retransmits the data to the MTC device 200 that is the transmission destination of the NACK using the radio resource specified by the PDCCH.

  The reception unit 111 of the base station 100 receives the multiplexed data transmitted from the transmission units 212 of the plurality of MTC devices 200. At this time, the reception unit 111 notifies the transmission unit 112 of success or failure of data reception for each MTC device 200.

  When the data reception fails, the reception unit 111 receives the retransmitted data from the MACK device 200 that is the transmission destination of the NACK, using the radio resource specified by the transmission unit 112 on the PDCCH.

  The transmission unit 212 of the MTC device 200 multiplexes data using the assigned subframe, and transmits the data to the reception unit 111 of the base station 100.

  The receiving unit 211 of the MTC device 200 receives information of subframes allocated so that data can be multiplexed and transmitted from the transmitting unit 112 of the base station 100. Then, the reception unit 211 transmits the subframe information to the control unit 22.

  The control unit 22 identifies a subframe assigned so that data can be multiplexed and transmitted. Then, the control unit 22 notifies the transmission unit 212 of information on the identified subframe.

  The operation flow of each unit in uplink communication between the base station 100 and the MTC device 200 in the radio communication system according to the present embodiment described above is the same as that in FIG. 8 except that communication is performed using MIMO. .

  Next, communication control in the case of downlink communication will be described collectively with reference to FIG. FIG. 13 is a sequence diagram of communication control in downlink communication in the communication system according to the fourth embodiment.

  The base station 100 transmits paging, and then receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S181).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information for multiplexing and transmitting data to the MTC devices 201 to 203 (step S182). Here, the base station 100 transmits subframe designation information that designates the first and second subframes as subframes used for multiplex transmission of data to the MTC devices 201 and 202. For example, the base station 100 transmits a bitmap of (1, 1, 0, 0, 0, 0, 0, 0) to the MTC devices 201 and 202. Thereby, the base station 100 transmits double data in the same SPS communication cycle as that in the case of not multiplexing.

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S183).

  Furthermore, the base station 100 multiplex-transmits data to the MTC devices 201 and 202 using the first subframe of the SPS communication cycle started after activation (step S184). Also, the base station 100 multiplex-transmits data to the MTC devices 201 and 202 using the second subframe (step S185).

  The base station 100 receives the multiplexed ACK from the MTC devices 201 and 202 (step S186). Further, the base station 100 receives the multiplexed ACK from the MTC device 201 and NACK from the MTC device 202 (step S187).

  Further, the base station 100 transmits data to the MTC device 203 using the last subframe of the SPS communication cycle (step S188).

  Furthermore, base station 100 transmits PDCCH that is control information of retransmission data to MTC device 202 that is the transmission source of NACK (step S189). Then, the base station 100 retransmits data to the MTC device 202 using the radio resource specified by the PDCCH (step S190).

  When the data transmission is completed, the base station 100 transmits a release to the MTC devices 201 to 203 (step S191). The MTC devices 201-203 receive the release and transition to the standby state.

  Next, communication control in the case of uplink communication will be described collectively with reference to FIG. FIG. 14 is a sequence diagram of communication control in uplink communication in the communication system according to the fourth embodiment.

  The base station 100 receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S201).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information for multiplexing and transmitting data to the MTC devices 201 to 203 (step S202). Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S203).

  The MTC devices 201 and 202 multiplex and transmit data to the base station 100 using the first subframe of the SPS communication cycle started after activation (step S204).

  Also, the MTC devices 201 and 202 multiplex and transmit data to the base station 100 using the second subframe of the SPS communication cycle (step S205).

  The base station 100 multiplexes the ACK and transmits it to the MTC devices 201 and 202 (step S206). In addition, the base station 100 multiplexes the ACK to the MTC device 201 and the NACK to the MTC device 202 and transmits them to the MTC devices 201 and 202 (step S207).

  In addition, the MTC device 203 transmits data to the base station 100 using the last subframe of the SPS communication cycle (step S208).

  Furthermore, the base station 100 transmits PDCCH, which is retransmission data control information, to the MTC device 202, which is the NACK transmission source (step S209). Then, the MTC device 202 retransmits data to the base station 100 using the radio resource specified by the PDCCH (step S210).

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S211). The MTC devices 201-203 receive the release and transition to the standby state.

  As described above, the radio communication system according to the present embodiment transmits data using multiuser MIMO in SPS communication. Thereby, the radio | wireless communications system which concerns on a present Example can transmit more data compared with Example 2. FIG.

  Next, Example 5 will be described. The wireless communication system according to the present embodiment is different from the second embodiment in that L1 (Layer 1) retransmission using HARQ is not performed. The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  The wireless communication system according to the present embodiment is also represented by the block diagram of FIG. In the following, the description of the function of each part similar to the second embodiment will be omitted. Hereinafter, the case of downlink communication and the case of uplink communication will be described separately.

(For downlink communication)
The transmission unit 112 of the base station 100 allocates a subframe to each MTC device 200 so as to repeatedly perform transmission. Here, since the retransmission of L1 is not performed in the present embodiment, the transmission error rate becomes high, and therefore the transmission unit 112 repeatedly performs transmission to ensure data transmission.

  The receiving unit 211 of the MTC device 200 receives data repeatedly transmitted using the assigned subframe from the transmitting unit 112 of the base station 100.

  The operation flow of each part in the downlink communication between the base station 100 and the MTC device 200 in the wireless communication system according to the present embodiment described above is that the retransmission of L1 using HARQ is not performed (for example, step S7). And S8) is the same as FIG.

(For upstream communication)
The transmission unit 112 of the base station 100 allocates a subframe to each MTC device 200 so as to repeatedly perform transmission.

  The transmission unit 212 of the MTC device 200 performs repeated transmission of data to the reception unit 111 of the base station 100 using the assigned subframe.

  The receiving unit 111 of the base station 100 receives data repeatedly transmitted using the assigned subframe from the transmitting unit 212 of the MTC device 200.

  The operation flow of each part in the downlink communication between the base station 100 and the MTC device 200 in the wireless communication system according to the present embodiment described above does not implement L1 retransmission using HARQ (for example, step S17). -S19 is the same as FIG.

  Next, communication control in the case of downlink communication will be described collectively with reference to FIG. FIG. 15 is a sequence diagram of communication control in downlink communication in the communication system according to the fifth embodiment.

  The base station 100 transmits paging, and then receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S221).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information for repeatedly transmitting data to the MTC devices 201 to 203 (step S222). Here, the base station 100 transmits subframe designation information for assigning the first and second subframes to the MTC device 201. For example, the base station 100 transmits a bitmap of (1, 1, 0, 0, 0, 0, 0, 0) to the MTC device 201. In addition, the base station 100 transmits subframe designation information for allocating the sixth to eighth subframes to the MTC device 202. For example, the base station 100 transmits a bitmap (0, 0, 0, 0, 0, 1, 1, 1) to the MTC device 202. In addition, the base station 100 transmits subframe designation information for assigning the third to fifth subframes to the MTC device 203. For example, the base station 100 transmits a bitmap (0, 0, 1, 1, 1, 0, 0, 0) to the MTC device 203.

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S223).

  Furthermore, the base station 100 repeatedly transmits data to the MTC device 201 using the first and second subframes of the SPS communication cycle started after activation (step S224). In addition, the base station 100 repeatedly transmits data to the MTC device 202 using the sixth to eighth subframes (step S225). Also, the base station 100 repeatedly transmits data to the MTC device 203 using the third to fifth subframes (step S226).

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S227). The MTC devices 201-203 receive the release and transition to the standby state.

  Next, communication control in the case of uplink communication will be described collectively with reference to FIG. FIG. 16 is a sequence diagram of communication control in uplink communication in the communication system according to the fifth embodiment.

  The base station 100 receives the random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S231).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information for multiplexing and transmitting data to the MTC devices 201 to 203 (step S232). Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S233).

  The MTC device 201 repeatedly transmits data to the base station 100 using the first and second subframes of the SPS communication cycle started after activation (step S234).

  Further, the MTC device 202 repeatedly transmits data to the base station 100 using the sixth to eighth subframes (step S235).

  Further, the MTC device 203 repeatedly transmits data to the base station 100 using the third to fifth subframes (step S236).

  When the data transmission is completed, the base station 100 transmits a release to the MTC devices 201 to 203 (step S237). The MTC devices 201-203 receive the release and transition to the standby state.

  As described above, the radio communication system according to the present embodiment performs communication without using HARQ in SPS communication. Thus, even when HARQ is not performed, the utilization efficiency of radio resources can be improved.

  In this embodiment, the case where L1 retransmission is not performed has been described. However, for example, L1 retransmission is performed by notifying the communication destination device whether or not L1 retransmission is performed using 1-bit information. And negative execution may be switched.

  Next, Example 6 will be described. The wireless communication system according to the present embodiment does not retransmit L1 using HARQ, and retransmits the same data at the next timing in the case of an error. The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  The wireless communication system according to the present embodiment is also represented by the block diagram of FIG. In the following, the description of the function of each part similar to the second embodiment will be omitted. Hereinafter, the case of downlink communication and the case of uplink communication will be described separately.

(For downlink communication)
The receiving unit 111 of the base station 100 detects the occurrence of a data transmission error.

  When the generation of an error is detected in the reception unit 111, the transmission unit 112 of the base station 100 uses the same data in the subframe assigned to the own apparatus in the next SPS communication cycle as the MTC device in which the data transmission error has occurred. 200.

  Here, with reference to FIG. 17, the flow of communication control in downlink communication in the communication system according to the sixth embodiment will be described together. FIG. 17 is a flowchart of communication control in downlink communication in the communication system according to the sixth embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S441).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S442).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S443). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Further, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S444). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S445). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Then, the communication unit 11 of the base station 100 communicates with each MTC device 200 using the subframe specified by the subframe specifying information (step S446).

  The receiving unit 111 of the base station 100 determines whether or not the occurrence of a data transmission error has been detected (step S447). If no error has been detected (No at Step S447), the base station 100 proceeds to Step S449.

  On the other hand, when an error is detected (step S447: Yes), the transmission unit 112 of the base station 100 sets data retransmission in the next subframe (step S448).

  The transmission unit 112 of the base station 100 determines whether data transmission is completed (step S449). When the data transmission has not been completed (step S449: No), the base station 100 returns to step S446.

  On the other hand, when data transmission is completed (step S449: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S450). The receiving unit 211 of the MTC device 200 receives the release and transitions to a standby state.

(For upstream communication)
The receiving unit 211 of the MTC device 200 detects the occurrence of an error in data transmission.

  When the reception unit 211 detects the occurrence of an error, the transmission unit 212 of the MCT device 200 transmits the same data to the base station 100 in the subframe assigned to the own device in the next SPS communication cycle.

  Here, with reference to FIG. 18, the flow of communication control in uplink communication in the communication system according to the sixth embodiment will be described together. FIG. 18 is a flowchart of communication control in uplink communication in the communication system according to the sixth embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S451).

  Next, the subframe allocation unit 122 of the base station 100 obtains the number of subframes used for communication with the MTC device 200 included in the group included in the SPS communication cycle from the information of the MTC device 200 included in the group. Further, subframe designation information is created (step S452).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S453). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Further, the transmission unit 112 of the base station 100 transmits the subframe designation information to the MTC device 200 (step S454). The control unit 22 of the MTC device 200 identifies the subframe assigned to the own device in the SPS communication cycle from the subframe designation information.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S455). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Then, the communication unit 21 of each MTC device 200 sequentially communicates with the base station 100 using the subframe specified by the subframe specifying information (step S456).

  The receiving unit 211 of each MTC device 200 determines whether or not the occurrence of a data transmission error has been detected (step S457). When no error is detected (No at Step S457), the MTC device 200 proceeds to Step S459.

  On the other hand, when the receiving unit 211 of the MTC device 200 detects an error (step S457: affirmative), retransmission of the same data in the subframe allocated to the own apparatus in the next SPS communication cycle is set. (Step S458).

  The transmission unit 212 of each MTC device 200 determines whether data transmission is completed (step S459). When the data transmission is not completed (No at Step S459), the MCT device 200 returns to Step S456.

  On the other hand, when data transmission is completed (step S459: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S460). The receiving unit 211 of the MTC device 200 receives the release, and the communication unit 12 transitions to a standby state.

  Next, communication control in the case of downlink communication will be described collectively with reference to FIG. FIG. 19 is a sequence diagram of communication control in downlink communication in the communication system according to the sixth embodiment.

  The base station 100 transmits paging, and then receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S241).

  The base station 100 sets the SPS communication cycle to the MTC devices 201 to 203, and transmits subframe designation information to the MTC devices 201 to 203 (step S242).

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S243).

  Furthermore, the base station 100 transmits data to the MTC device 201 using the first subframe of the SPS communication cycle started after activation (step S244). Further, the base station 100 transmits data to the MTC device 202 using the second subframe (step S245). Further, the base station 100 transmits data to the MTC device 203 using the last subframe of the SPS communication cycle (step S246).

  Next, the base station 100 transmits data to the MTC device 201 using the first subframe (step S247). At this time, if an error occurs in data transmission in step S244, the base station 100 transmits the same data as in step S244. In addition, the base station 100 transmits data to the MTC device 202 using the second subframe (step S248). At this time, if an error occurs in data transmission in step S245, the base station 100 transmits the same data as in step S245.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S249). The MTC devices 201-203 receive the release and transition to the standby state.

  Next, communication control in the case of uplink communication will be described collectively with reference to FIG. FIG. 20 is a sequence diagram of communication control in uplink communication in the communication system according to the sixth embodiment.

  The base station 100 receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S251).

  The base station 100 transmits the subframe designation information to each MTC device 201-203 (step S252).

  Thereafter, the base station 100 sets the SPS communication cycle to the MTC devices 201 to 203 and transmits the activation to the MTC devices 201 to 203 (step S253).

  Thereafter, the MTC device 201 transmits data to the base station 100 using the first subframe of the SPS communication cycle started after activation (step S254). Further, the MTC device 202 transmits data to the base station 100 using the second subframe (step S255). Further, the MTC device 203 transmits data to the base station 100 using the last subframe of the SPS communication cycle (step S256).

  Next, the MTC device 201 transmits data to the base station 100 using the first subframe (step S257). At this time, if an error occurs in data transmission in step S254, the MTC device 201 transmits the same data as in step S254. In addition, the MTC device 202 transmits data to the base station 100 using the second subframe (step S258). At this time, if an error occurs in data transmission in step S255, the base station 100 transmits the same data as in step S255.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S259). The MTC devices 201-203 receive the release and transition to the standby state.

  As described above, the radio communication system according to the present embodiment does not use HARQ in SPS communication, and transmits the same data in the next SPS communication cycle when an error occurs in data transmission. In this way, when HARQ is not used in SPS communication and an error occurs in data transmission, even when the same data is transmitted in the next SPS communication cycle, the utilization efficiency of radio resources can be improved.

  Next, Example 7 will be described. The radio communication system according to the present embodiment transmits PDSCH (Physical Downlink Shared CHannel) or PUSCH (Physical Uplink Shared CHannel) without specifying a subframe. The following embodiments including the present embodiment may be regarded as embodiments in which embodiment 1 is embodied. Furthermore, it is needless to say that the same reference numerals in the drawings can operate as described in each embodiment regardless of the embodiment. It goes without saying that not only this embodiment but also each embodiment can be implemented in combination.

  The wireless communication system according to the present embodiment is also represented by the block diagram of FIG. In the following, the description of the function of each part similar to the second embodiment will be omitted. Hereinafter, the case of downlink communication and the case of uplink communication will be described separately.

(For downlink communication)
The transmission unit 112 of the base station 100 notifies the MTC device 200 that the SPS communication period and HARQ are not implemented. Further, the transmission unit 112 transmits the subframe designation information not indicating the subframe to the MTC device 200 with the content of the subframe designation information being “null” or the like, for example.

  The transmission unit 112 masks the CRC (Cyclic Redundancy Check) portion of each PDSCH with the address of the destination MTC device 200. Then, in each subframe of the SPS communication cycle, the transmission unit 112 transmits the PDSCH masked with the CRC unit to all the MTC devices 200 belonging to the group.

  Then, when occurrence of an error in data transmission is detected by the reception unit 111, the transmission unit 112 uses ARQ in an RLC (Radio Link Control) layer to transmit data to the MTC device 200 in which an error has occurred in data transmission. Is retransmitted (ARQ).

  The receiving unit 111 of the base station 100 detects the occurrence of an error in data transmission.

  The reception unit 211 of the MTC device 200 acquires the PDSCH transmitted from the transmission unit 112 of the base station 100 in each subframe, and checks the CRC unit. When the CRC part can be descrambled with the address of the own apparatus and no CRC error has occurred, the MTC device 200 receives the PDSCH. On the other hand, if the CRC unit can be descrambled with the address of the own device and a CRC error has occurred, the receiving unit 211 discards the PDSCH. At this time, the ACK or NACK reply is considered to be a part of the HARQ function and is preferably returned, but it is not always necessary to reply. In other words, since the ARQ in the RLC layer has a data reception check function based on Poll / Status, if the data is not received correctly, the RLC layer can check. Therefore, ACK and NACK replies are not essential.

  Here, with reference to FIG. 21, the flow of communication control in downlink communication in the communication system according to the seventh embodiment will be described together. FIG. 21 is a flowchart of communication control in downlink communication in the communication system according to the seventh embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S471).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S472). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S473). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  Then, the communication unit 11 of the base station 100 masks the CRC part of the PDSCH with the address of the destination MTC device 200 and transmits it to all the MTC devices 200 (step S474).

  The receiving unit 111 of the base station 100 determines whether or not an error has been detected (step S475). When the occurrence of an error has not been detected (No at Step S475), the base station 100 proceeds to Step S477.

  On the other hand, when the occurrence of an error is detected (step S475: Yes), the transmission unit 112 of the base station 100 retransmits data to the MTC device 200 using ARQ (step S476).

  The transmission unit 112 of the base station 100 determines whether data transmission is completed (step S477). When the data transmission is not completed (No at Step S477), the base station 100 returns to Step S474.

  On the other hand, when the data transmission is completed (step S477: Yes), the transmission unit 112 of the base station 100 transmits the release to the MTC device 200 (step S478). The receiving unit 211 of the MTC device 200 receives the release and transitions to a standby state.

(For upstream communication)
The transmission unit 112 of the base station 100 notifies the MTC device 200 that the SPS communication period and HARQ are not implemented. In addition, the transmission unit 112 transmits subframe designation information not indicating a subframe to the MTC device 200.

  When an error is detected in the CRC check by the reception unit 111, the transmission unit 112 transmits a NACK to the MTC device 200 that is the transmission source of the PUSCH in which the error is detected in the CRC check.

  The reception unit 111 of the base station 100 acquires the PUSCH transmitted from the transmission unit 212 of the MTC device 200 in each subframe and checks the CRC unit. When no error is detected in the CRC check, the reception unit 111 receives the PUSCH. On the other hand, when an error is detected by the CRC check, the reception unit 111 notifies the transmission unit 112 of error detection.

  The transmission unit 212 of the MTC device 200 masks the CRC unit of each PUSCH with an address (for example, C-RNTI or the like) assigned to the own device of the base station 100. And the transmission part 212 transmits PUSCH which masked the CRC part to the base station 100 in each subframe of the SPS communication cycle. In the present embodiment, the transmission unit 212 transmits data using the Contention-base PUSCH, and transmits control information and data to the base station 100. (See 3GPP (3rd Generation Partnership Project), “Contention based uplink transmissions”, 3GPP TSG-RAN WG2 # 66bis R2-093812, 2009-06.)

  Then, when receiving a retransmission request from the reception unit 211, the transmission unit 212 retransmits the data after waiting for a randomly determined time. In other words, the transmission unit 212 performs backoff.

  When receiving unit 111 of base station 100 receives NACK from transmitting unit 112 of base station 100, receiving unit 111 transmits a retransmission request to transmitting unit 212.

  Here, with reference to FIG. 22, the flow of communication control in uplink communication in the communication system according to the seventh embodiment will be described together. FIG. 22 is a flowchart of communication control in uplink communication in the communication system according to the seventh embodiment.

  The group generation unit 121 of the base station 100 extracts and groups the MTC devices 200 that satisfy a predetermined condition (step S481).

  The transmission unit 112 of the base station 100 notifies the MTC device 200 of the SPS communication cycle (step S482). The control unit 22 of the MTC device 200 sets the SPS communication cycle in its own device.

  Thereafter, the transmission unit 112 of the base station 100 transmits the activation to the MTC device 200 (step S483). The communication unit 21 of the MTC device 200 transitions to a communicable state.

  And the communication part 21 of each MTC device 200 masks the CRC part of PUSCH with the address of an own apparatus, and transmits to all the base stations 100 (step S484).

  The receiving unit 111 of the base station 100 determines whether an error has been detected (step S485). If no error is detected (step S485: negative), the process proceeds to step S487. On the other hand, when an error is detected (step S485: Yes), the transmission unit 112 of the base station apparatus transmits a NACK (step S486).

  The receiving unit 211 of the MTC device 200 determines whether or not a NACK has been received (step 487). When NACK is not received (step S487: No), the MTC device 200 proceeds to step S489.

  On the other hand, when the reception unit 211 of the MTC device 200 has received NACK (step S487: Yes), the reception unit 211 of the MTC device 200 performs backoff (step S488).

  Then, the transmission unit 212 of each MTC device 200 determines whether or not the data transmission is completed (step S489). If the data transmission has not been completed (No at Step S489), the MCT device 200 returns to Step S484.

  On the other hand, when data transmission is completed (step S489: Yes), the transmission unit 112 of the base station 100 transmits a release to the MTC device 200 (step S490). The receiving unit 211 of the MTC device 200 receives the release, and the communication unit 12 transitions to a standby state.

  Next, communication control in the case of downlink communication will be described collectively with reference to FIG. FIG. 23 is a sequence diagram of communication control in downlink communication in the communication system according to the seventh embodiment. In FIG. 23, PDSCH is simply represented as data.

  The base station 100 transmits paging, and then receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S261).

  The base station 100 sets the SPS communication period to each MTC device 201-203 (step S262).

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S263).

  Furthermore, base station 100 transmits PDSCH with the CRC portion masked with the destination address in each subframe. For example, the MTC device 201 checks the CRC part of the acquired PDSCH, and if the CRC part can be descrambled with the address of the own apparatus and no CRC error has occurred, acquires the PDSCH (step S264). Further, for example, the MTC device 202 checks the CRC part of the acquired PDSCH, and if the CRC part can be descrambled with the address of the own apparatus and no CRC error occurs, acquires the PDSCH (step S265). . Thus, each MTC device 201-203 receives the PDSCH while performing a CRC check.

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S266). The MTC devices 201-203 receive the release and transition to the standby state.

  Next, communication control in the case of uplink communication will be described collectively with reference to FIG. FIG. 24 is a sequence diagram of communication control in uplink communication in the communication system according to the seventh embodiment. In FIG. 24, PUSCH is simply represented as data.

  The base station 100 receives random access transmitted by the MTC devices 201 to 203 within a predetermined period, and sets the MTC devices 201 to 203 as one group (step S271).

  The base station 100 sets the SPS communication period to each MTC device 201-203 (step S272).

  Thereafter, the base station 100 transmits the activation to the MTC devices 201 to 203 (step S273).

  Thereafter, the MTC devices 201 to 203 transmit data to the base station 100 using the Contention-base PUSCH (Step S274).

  Then, the base station 100 checks the CRC part of the received PUSCH, and if no error is detected, receives the PUSCH. On the other hand, for example, when an error is detected in the CRC check of the PUSCH received from the MTC device 202, the base station 100 transmits a NACK to the MTC device 202 (step S275).

  The MTC device 202 receives NACK from the base station 100 and performs backoff (step S276). The base station 100 receives the retransmitted data from the MTC device 202 (step S277).

  When the data transmission is completed, the base station 100 transmits the release to the MTC devices 201 to 203 (step S278). The MTC devices 201-203 receive the release and transition to the standby state.

  As described above, the radio communication system according to the present embodiment transmits data without assigning subframes to each MTC device. In this way, it is possible to improve the utilization efficiency of radio resources for transmitting data without assigning subframes to each MTC device.

(Hardware configuration)
FIG. 25 is a hardware configuration diagram of the base station. The base station is, for example, the wireless communication device 1 in FIG. 1 or the base station 100 shown in FIG.

  The base station includes an antenna 901, a control unit 902, an RF circuit 903, a memory 904, a CPU 905, and a network interface 906.

  The control unit 902 realizes the function of the control unit 12 illustrated in FIGS. 1 and 4, for example.

  The network interface 906 is an interface for connecting to a network by wire.

  The CPU 905, the memory 904, and the RF circuit 903 realize the function of the communication unit 11 shown in FIGS.

  For example, the memory 904 stores various programs such as a program for realizing the function of the communication unit 11.

  The CPU 905 reads the program stored in the memory 904 and realizes the function of the communication unit 11 by cooperating with the RF circuit 903 and the like.

  FIG. 26 is a hardware configuration diagram of the communication terminal. The communication terminal is, for example, the wireless communication device 2 in FIG. 1, the MTC device 200 shown in FIG.

  The communication terminal includes an antenna 911, a control unit 912, an RF circuit 913, a memory 914, and a CPU 915.

  The control unit 912 implements the function of the control unit 22 illustrated in FIGS. 1 and 4, for example.

  The CPU 915, the memory 914, and the RF circuit 913 realize the function of the communication unit 21 shown in FIGS.

  For example, the memory 914 stores various programs such as a program for realizing the function of the communication unit 21.

  The CPU 915 implements the function of the communication unit 21 by reading the program stored in the memory 914 and cooperating with the RF circuit 913 and the like.

DESCRIPTION OF SYMBOLS 1, 2 Wireless communication apparatus 11, 21 Communication part 12,22 Control part 100 Base station 200 MTC device 111,211 Reception part 112,212 Transmission part 121 Group generation part 122 Sub-frame allocation part

Claims (7)

A wireless communication system having a first wireless communication device and a plurality of second wireless communication devices,
The first wireless communication device is:
A control unit that extracts the second wireless communication device that satisfies a predetermined condition;
1st information which shows the 1st section which consists of a plurality of sections including the control section which transmits and receives a signal using the 1st control channel used for communication in a Radio Resource Control (RRC) layer, and is included in the 1st section Second information indicating the second section to be transmitted is transmitted to the second wireless communication apparatus extracted by the control unit using a radio resource control signal, and communication including communication period setting is activated in the control section. A signal is transmitted using the second control channel, and the second section for each of the first sections for each of the communication periods notified by the radio resource control signal is the second section corresponding to the second section. A first communication unit that transmits and receives data to and from two wireless communication devices;
The second wireless communication device is
Based on the first information and the second information received from the first wireless communication device, the second interval of the first interval of the communication interval notified by the wireless resource control signal A wireless communication system, comprising: a second communication unit that transmits and receives data to and from the first wireless communication device. A control unit that extracts communication terminals that satisfy a predetermined condition;
1st information which shows the 1st section which consists of a plurality of sections including the control section which transmits and receives a signal using the 1st control channel used for communication in a RRC layer, and the 2nd section contained in the 1st section Using a second control channel that activates communication including setting of a communication period in the control period, and transmits second information indicating the communication information to the communication terminal extracted by the control unit using a radio resource control signal. Transmitting and receiving data to and from the communication terminal corresponding to the second section in the second section for each of the first sections for each communication period transmitted by the radio resource control signal And a communication unit.   When the transmission of data to the communication terminal fails, the communication unit receives a retransmission request from the communication terminal, transmits a control signal specifying a radio resource to be used for the communication terminal, and transmits the specified radio resource. The base station according to claim 2, wherein the base station retransmits data that failed to be transmitted.   The said control part allocates the said 2nd area without data to another communication, when there is no data in communication between the said communication terminals in the said 2nd area. base station.   The base station according to claim 2, wherein the communication unit repeatedly transmits the same data a plurality of times.   1st information which shows the 1st section which consists of a plurality of sections including the control section which transmits and receives a signal using the 1st control channel used for communication in a RRC layer, and the 2nd section contained in the 1st section Is transmitted to a communication terminal satisfying a predetermined condition using a radio resource control signal, and a signal is transmitted using a second control channel that activates communication including setting of a communication period in the control interval. First communication for transmitting / receiving data to / from the communication terminal corresponding to the second section in the second section for each of the first sections for each of the communication periods notified by the radio resource control signal Based on the first information and the second information received from the base station comprising a unit, the second section for each first section for each communication period notified by the radio resource control signal Data with the base station Communication terminal, characterized in that it comprises a second communication unit for receiving. A wireless communication method in a wireless communication system having a first wireless communication device and a plurality of second wireless communication devices,
The first wireless communication device extracts the second wireless communication device satisfying a predetermined condition;
The first wireless communication device includes first information indicating a first section including a plurality of sections including a control section that transmits and receives a signal using a first control channel used for communication in an RRC layer, and the first information Transmitting second information indicating a second section included in the section to the extracted second wireless communication device using a radio resource control signal;
The first wireless communication device transmits a signal to the second wireless communication device using a second control channel that activates communication including communication period setting in the control section,
The first radio communication device includes the second radio communication device corresponding to the second interval in the second interval for each of the first intervals for each communication cycle notified by the radio resource control signal. Send and receive data between
The second radio communication device, for each of the first intervals for each communication cycle notified by the radio resource control signal, based on the first information and the second information received from the first radio communication device. A wireless communication method comprising transmitting and receiving data to and from the first wireless communication device during the second section of the method.

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