JP6357567B2 - User device and transmission control method - Google Patents

Description

  The present invention relates to a wireless communication system using carrier aggregation.

  Currently, 3GPP (3rd Generation Partnership Project) is promoting the standardization of LTE-Advanced as the next generation communication standard of LTE (Long Term Evolution). In the LTE-Advanced system, carrier aggregation (CA) technology is introduced in order to achieve a throughput higher than that of the LTE system while ensuring backward compatibility with the LTE system. In carrier aggregation, a component carrier (CC) having a maximum bandwidth of 20 MHz supported by the LTE system is used as a basic component, and by using these multiple component carriers at the same time, wider bandwidth communication is realized. It is planned to do.

  In carrier aggregation, a user apparatus (User Equipment: UE) can communicate with a base station (evolved NodeB: eNB) using a plurality of component carriers simultaneously. In carrier aggregation, a highly reliable primary cell (Primary Cell: PCell) that ensures connectivity with user equipment and a secondary cell (Secondary Cell: SCell) that is additionally set in the user equipment connected to the primary cell And are set.

  The primary cell is a cell similar to the serving cell of the LTE system, and is a cell for ensuring connectivity between the user apparatus and the network. That is, in a primary cell, a user apparatus receives PDCCH (Physical Downlink Control Channel) and PDSCH (Physical Downlink Shared Channel), PRACH (Physical Random Channel Access, PRACH (Physical Random Channel Access). Channel) and SRS (Sounding Reference Symbol) can be transmitted. Moreover, when changing a primary cell, the user apparatus needs to perform a handover. On the other hand, the secondary cell is a cell that is added to the primary cell and set in the user apparatus. The addition and the deletion of the secondary cell are executed by RRC (Radio Resource Control) configuration (Configuration).

3GPP TS 36.213 V.11.0.0 (2012-09)

  In the current carrier aggregation, among the above-described uplink radio channels of PRACH, PUCCH, PUSCH, and SRS, it is supported that PRACH, PUSCH, and SRS are transmitted in both the primary cell and the secondary cell. In this case, the user apparatus can simultaneously transmit PRACH, PUSCH, and SRS in the primary cell and the secondary cell.

  On the other hand, in the current carrier aggregation, PUCCH transmission in the primary cell is supported, but PUCCH transmission in the secondary cell is not supported. That is, PUCCH is transmitted only in the primary cell, and transmission of PUCCH via the secondary cell is not specified. For this reason, when there are many user apparatuses having a specific cell as a primary cell, the number of user apparatuses connectable to the primary cell is limited due to the PUCCH capacity limitation in the cell. In addition, in the inter-base station carrier aggregation (Inter-eNB CA) or the inter-site carrier aggregation (Inter-site CA) currently under consideration, scheduling is performed for each base station. PUCCH needs to be transmitted. For this reason, it is considered to support transmission of PUCCH not only in the primary cell but also in the secondary cell.

  However, even if the above-described simultaneous transmission of PUCCH in a plurality of cells is supported in the wireless communication system, the user apparatus cannot always simultaneously transmit PUCCH in a plurality of cells. For example, when the user equipment does not support the uplink simultaneous transmission function, the user equipment cannot simultaneously transmit PUCCH in a plurality of cells. Alternatively, when the user apparatus cannot secure sufficient transmission power to perform uplink simultaneous transmission, such as when the user apparatus is at the cell edge, simultaneous uplink transmission cannot be performed.

  When such a user apparatus cannot simultaneously transmit PUCCH in a plurality of cells, it is conceivable that priority is set for the PUCCH to be transmitted and transmission of PUCCH is controlled according to the priority.

  In view of the above problems, an object of the present invention is to provide a technique for simultaneously transmitting uplink control channels in a plurality of cells in a wireless communication system that supports transmission of uplink control channels in a secondary cell. That is.

  In order to solve the above problems, according to one aspect of the present invention, a transmission / reception unit that transmits and receives a radio channel to and from a base station via a plurality of cells set by carrier aggregation, and an uplink control channel is simultaneously transmitted from the plurality of cells. In response to the occurrence of an event, the simultaneous transmission availability determination unit that determines whether uplink control channels can be simultaneously transmitted in the plurality of cells, and when the uplink control channels can be simultaneously transmitted in the plurality of cells, The transmission / reception unit is instructed to simultaneously transmit the uplink control channel in the cell, and when the uplink control channel cannot be simultaneously transmitted in the plurality of cells, the transmission for controlling the transmission of the uplink control channel according to the transmission priority The present invention relates to a user apparatus having a control unit.

  According to the above aspect, in a radio communication system that supports transmission of an uplink control channel in a secondary cell, it is possible to simultaneously transmit the uplink control channel in a plurality of cells.

FIG. 1 is a diagram schematically illustrating a wireless communication system according to an embodiment of the present invention. FIG. 2 is a diagram illustrating a configuration of a user apparatus according to an embodiment of the present invention. FIG. 3 is a flowchart illustrating a PUCCH transmission process according to an embodiment of the present invention.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

  In an embodiment to be described later, when an event occurs in which a uplink control channel is simultaneously transmitted in a plurality of cells in a wireless communication system using carrier aggregation, the user apparatus sets a plurality of uplink control channels to be transmitted. Determine whether simultaneous transmission is possible in the cell. When it is possible to simultaneously transmit the uplink control channel to be transmitted in a plurality of cells, the user apparatus transmits the uplink control channel to be transmitted to the base station via the plurality of cells. On the other hand, when it is not possible to simultaneously transmit the uplink control channel to be transmitted in a plurality of cells, the user equipment allocates a relatively large transmission power to the uplink control channel having a high transmission priority, for example, and performs transmission priority. The transmission of the uplink control channel is controlled according to the transmission priority by allocating a relatively small transmission power to the lower uplink control channel or by canceling the transmission.

  The transmission priority may be in accordance with the type of uplink control channel to be transmitted. The transmission priority may also be set according to the type of applied carrier aggregation, that is, according to whether intra-base station carrier aggregation or inter-base station carrier aggregation is used.

  In this way, even when it is not possible to simultaneously transmit the uplink control channel to be transmitted in a plurality of cells, the uplink control channel can be simultaneously transmitted, and the uplink control channel having a high transmission priority. Can be received at the base station more reliably than the uplink control channel having a low transmission priority.

  First, a wireless communication system according to an embodiment of the present invention will be described with reference to FIG. FIG. 1 is a diagram schematically illustrating a wireless communication system according to an embodiment of the present invention.

  As illustrated in FIG. 1, the radio communication system 10 includes one or more base stations (eNBs) 50 and one or more user apparatuses (UEs) 100. In the present embodiment, the radio communication system 10 is an LTE-Advanced system, but is not limited to this, and may be any appropriate radio communication system that supports carrier aggregation.

  In the radio communication system 10 according to the present embodiment, a single base station 50 provides a plurality of cells for communication with the user apparatus 100, and from these cells, a primary cell and a secondary cell are allocated to the user apparatus 100, and these To the user apparatus 100 via the cell (carrier aggregation within base station (Intra-eNB CA)).

  Also, a plurality of base stations 50 provide a plurality of cells for communication with the user apparatus 100, and a primary cell and a secondary cell are assigned to the user apparatus 100 by different base stations 50, and the user apparatus 100 is transmitted via these cells. (Inter-base station carrier aggregation (Inter-eNB CA)).

  The base station 50 wirelessly connects to the user apparatus 100, thereby transmitting downlink data received from a higher-level station and a server (not shown) connected to the user apparatus 100 to the user apparatus 100 and receiving the up-data received from the user apparatus 100. Link data is transmitted to an upper station (not shown). In this embodiment, the base station 50 is an eNB conforming to LTE-Advanced, but is not limited to this, and is any suitable base station that supports intra-base station carrier aggregation and inter-base station carrier aggregation. May be.

  The user apparatus 100 is typically a mobile phone, a smartphone, a tablet, a mobile router, or the like, but is not limited thereto, and may be any appropriate user apparatus having a wireless communication function. In a typical hardware configuration, the user device 100 includes a CPU (Central Processing Unit) such as a processor, a memory device such as a RAM (Random Access Memory), an auxiliary storage device such as a hard disk device, and a communication for communicating radio signals. It consists of a device, an interface device for interacting with the user, and the like. Each function of the user device 100 described later is such that data or a program stored in the auxiliary storage device is loaded into the memory device via the communication device and / or the interface device, and the CPU processes the data according to the loaded program. It is realized by.

  Next, the configuration of the user apparatus according to an embodiment of the present invention will be described with reference to FIG. FIG. 2 is a diagram illustrating a configuration of a user apparatus according to an embodiment of the present invention.

  As illustrated in FIG. 2, the user apparatus 100 includes a transmission / reception unit 110, a simultaneous transmission availability determination unit 120, and a transmission control unit 130.

  The transmission / reception unit 110 transmits / receives various radio channels such as an uplink / downlink control channel and an uplink / downlink data channel to / from the base station 50. In the radio communication system 10 compliant with LTE-Advanced, the user apparatus 100 receives a PDCCH (Physical Downlink Control Channel) and a PDSCH (Physical Downlink Shared Channel) from the base station 50, and the base station 50 receives a PRACH (cand shar chan) ), PUCCH (Physical Uplink Control Channel), PUSCH (Physical Uplink Shared Channel), and SRS (Sounding Reference Symbol).

  In this embodiment, the radio communication system 10 supports carrier aggregation, and the base station 50 can communicate via the user apparatus 100, the primary cell, and the secondary cell. For example, in the intra-base station carrier aggregation, a single base station 50 allocates a primary cell and a secondary cell to a user apparatus 100 from a plurality of cells provided by itself, and communicates with the user apparatus 100 via these cells. In this case, the transmission / reception unit 110 exchanges various radio channels with the base station 50 that provides these cells. Moreover, in the carrier aggregation between base stations, the some base station 50 allocates a primary cell or a secondary cell from the cell which each one provides to the user apparatus 100, and communicates with the user apparatus 100 via these cells. In this case, the transmission / reception unit 110 exchanges various radio channels with different base stations 50 that provide assigned cells. In general, in the inter-base station CA, different base stations 50 use their own schedulers to allocate cells provided by themselves to the user equipment 100. For this reason, each base station 50 performs communication processing with the user apparatus 100 such as scheduling, delivery confirmation, and radio quality measurement in parallel, such as PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI. It is assumed that all uplink control information (UCI) combinations are transmitted simultaneously. Here, PUCCH-SR is an uplink control channel for user apparatus 100 to request a scheduling request from base station 50, and PUCCH-ACK / NACK is a reception of a data channel from base station 50 by user apparatus 100. It is an uplink control channel for reporting success / failure, and PUCCH-CQI is an uplink control channel for reporting radio quality such as CQI (Channel Quality Indicator) measured by the user apparatus 100 to the base station 50.

  The simultaneous transmission availability determination unit 120 determines whether the uplink control channel can be simultaneously transmitted in a plurality of cells in response to the occurrence of an event in which the uplink control channel is simultaneously transmitted in a plurality of cells. The simultaneous transmission event may be, for example, when the user apparatus 100 requests a scheduling request from the base station 50. Alternatively, the event may be when the user apparatus 100 receives a data channel from the base station 50 and transmits a delivery confirmation as to whether or not the data channel has been successfully received. Alternatively, the simultaneous transmission event is a time when the user apparatus 100 is requested to measure the radio quality such as CQI from the base station 50 and report the measured radio quality, or a periodic transmission timing of the radio quality. Also good.

  In one embodiment, the simultaneous transmission availability determination unit 120 determines whether the user apparatus 100 has a function of simultaneously transmitting an uplink control channel via a plurality of cells or whether the function is set. It may be determined whether transmission is possible. In another embodiment, the simultaneous transmission availability determination unit 120 may determine whether simultaneous transmission is possible by determining whether the user apparatus 100 can sufficiently secure transmission power for simultaneous transmission. The simultaneous transmission permission determination unit 120 notifies the transmission control unit 130 of the determination result.

  The transmission control unit 130 controls transmission of the uplink control channel by the transmission / reception unit 110 according to the received simultaneous transmission permission / inhibition result. That is, when the uplink control channel can be simultaneously transmitted in a plurality of cells, the transmission control unit 130 instructs the transmission / reception unit 110 to simultaneously transmit the uplink control channel in the plurality of cells. On the other hand, when the uplink control channel cannot be transmitted simultaneously in a plurality of cells, transmission of the uplink control channel is controlled according to the set transmission priority.

  Here, “transmission according to transmission priority” means that a relatively large transmission power is allocated to an uplink control channel having a high transmission priority, and a relatively small transmission power is allocated to an uplink control channel having a low transmission priority. It may be to allocate transmission power or to cancel transmission. However, the present invention is not limited to this, and any appropriate transmission control is performed such that the uplink control channel with a high transmission priority is received by the base station 50 more reliably than the uplink control channel with a low transmission priority. means.

  In one embodiment, the transmission priority may be predefined according to the type of uplink control channel. In the radio communication system 10 compliant with LTE-Advanced, for example, three types of PUCCH, PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI, are transmitted from the user apparatus 100 to the base station 50.

  For example, a transmission priority may be set between PUCCH-SR and PUCCH-ACK / NACK so that PUCCH-SR is transmitted with priority over PUCCH-ACK / NACK (PUCCH-SR> PUCCH-ACK). / NACK). Also, the transmission priority may be set in the order of PUCCH-SR, PUCCH-ACK, and PUCCH-NACK (PUCCH-SR> PUCCH-ACK> PUCCH-NACK).

  Also, a transmission priority may be set between PUCCH-ACK / NACK and PUCCH-CQI so that PUCCH-ACK / NACK is transmitted with priority over PUCCH-CQI (PUCCH-ACK / NACK> PUCCH). -CQI). Further, the transmission priority may be set in the order of PUCCH-ACK, PUCCH-CQI, and PUCCH-NACK (PUCCH-ACK> PUCCH-CQI> PUCCH-NACK).

  Moreover, between PUCCH-SR and PUCCH-CQI, a transmission priority may be set so that PUCCH-SR is transmitted with priority over PUCCH-CQI (PUCCH-SR> PUCCH-CQI).

  The uplink control channel of the present invention is not limited to the above-described PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI, and any other type of uplink control channel may be used. . As understood from the specific examples described above, basically, the transmission priority is given priority to the uplink control channel that is more important in realizing wireless communication between the base station 50 and the user apparatus 100. It is preferable that it is prescribed | regulated to transmit.

  In other embodiments, the transmission priority of the uplink control channel may be changed dynamically. For example, the transmission priority may be dynamically changed according to the communication status between the base station 50 and the user apparatus 100. In typical wireless communication between the base station 50 and the user apparatus 100, when some communication demand occurs in the user apparatus 100, the user apparatus 100 transmits a scheduling request to the base station 50. After execution of scheduling, communication is started between the user apparatus 100 and the base station 50. For this reason, you may set so that the transmission priority of PUCCH-SR may become high at the timing before communication start. On the other hand, after the start of communication, the user apparatus 100 typically receives a data channel from the base station 50 or transmits a data channel to the base station 50. For this reason, after communication start, you may set so that the transmission priority of PUCCH-ACK / NACK may become high. In addition, when the CQI reported from the user apparatus 100 is equal to or lower than a predetermined threshold, since the possibility of retransmission increases, the PUCCH-ACK / NACK transmission priority may be set higher. Moreover, when the magnitude | size of the fluctuation | variation of the measured CQI is more than a predetermined threshold value, you may set so that the transmission priority of PUCCH-CQI may become high so that a radio | wireless quality fluctuation | variation can be tracked rapidly.

  Further, the above-described priority control for PUCCH-ACK / NACK and PUCCH-CQI of PUCCH-SR may be performed based on, for example, the priority of data generated when the transmission of PUCCH-SR is triggered. . For example, PUCCH-ACK / NACK and PUCCH-CQI may be prioritized over PUCCH-SR if the generated data has low priority or low delay requirements.

  In another embodiment, the transmission priority of the uplink control channel may be notified from the base station 50. In the radio communication system 10 compliant with LTE-Advanced, for example, the base station 50 sets the transmission priority among PUCCH-SR, PUCCH-ACK / NACK and PUCCH-CQI to be transmitted, and notifies the user apparatus 100 of them. May be. Further, the base station 50 may dynamically set the priority according to the communication status with the user apparatus 100 and notify the user apparatus 100 of the priority. For example, when a large number of user apparatuses 100 are connected to the base station 50, it may not be preferable for the base station 50 to receive a specific type of uplink control channel (such as PUCCH-SR) centrally. Absent. In fact, when receiving PUCCH-SRs simultaneously from a large number of user apparatuses 100, the base station 50 temporarily bears a large processing burden related to scheduling. In order to avoid such a situation, for example, the base station 50 may divide the connected user apparatus 100 into a plurality of groups and dynamically set different transmission priorities for each group.

  In other embodiments, the transmission priority may be set according to a component carrier or cell. For example, transmission of the uplink control channel in the primary cell may be prioritized over transmission of the uplink control channel in the secondary cell. For example, when transmitting PUCCH-CQI in a plurality of cells, the transmission priority may be set such that the PUCCH-CQI of the primary cell is transmitted with priority over the PUCCH-CQI of the secondary cell (PCell CQI> SCell CQI). ).

  When two or more secondary cells are set, the transmission priority between the secondary cells may be set according to the communication quality order of each secondary cell, the secondary cell index (SCellIndex) order, and the like. Here, the SCellIndex is given every time a secondary cell is assigned to the user apparatus 100. For example, SCellIndex = 1 may be assigned to the first assigned secondary cell, SCellIndex = 2 may be assigned to the second assigned secondary cell, and SCellIndex may be assigned similarly thereafter.

  Further, the transmission priority may be set according to the component carrier or cell communication scheme set in the user apparatus 100. For example, depending on whether the cell is a TDD (Time Division Duplex) method or an FDD (Frequency Division Duplex) method, a relatively high transmission priority is set for the TDD cell, and the FDD cell is assigned to the cell. A relatively low transmission priority may be set.

  In one embodiment, the transmission control unit 130 may include a CA type determination unit 131 that determines whether the user apparatus 100 uses intra-base station carrier aggregation or inter-base station carrier aggregation. In this case, the transmission control unit 130 determines whether the user apparatus 100 uses intra-base station carrier aggregation or inter-base station carrier aggregation, PUCCH-SR, PUCCH-ACK / NACK, and PUCCH- CQI transmission priority is determined. The CA type determination may be performed, for example, by specifying the base station 50 that provides each component carrier or cell assigned to the user apparatus 100.

  The transmission control unit 130 controls transmission priorities of various uplink control channels of PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI according to the CA type used by the user apparatus 100. When the user apparatus 100 uses the CA in the base station, the transmission control unit 130 controls transmission of various uplink control channels according to the transmission priority described above. That is, as described above, the transmission control unit 130 performs uplink according to one or more of the transmission priority based on the type of the uplink control channel, the transmission priority notified from the base station 50, and the transmission priority of a plurality of cells. The transmission priority of the control channel is determined, and control is performed so that the uplink control channel is transmitted to the base station 50 via the corresponding cell according to the determined transmission priority.

  On the other hand, when the user apparatus 100 uses the inter-base station CA, the transmission control unit 130 may further use various transmission priorities as described later. In general, different base stations 50 and schedulers are used in the inter-base station CA. For this reason, each base station 50 performs communication processing with the user apparatus 100 such as scheduling, delivery confirmation, and radio quality measurement in parallel, such as PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI. It is assumed that all uplink control information (UCI) combinations are transmitted simultaneously.

  In one embodiment, the base station 50 that provides any cell to which the user apparatus 100 is connected may be set as an anchor base station (eNB), and transmission of the uplink control channel to the anchor base station 50 may be prioritized. . That is, the uplink control channel transmitted to the component carrier or cell provided by the anchor base station 50 has priority over the uplink control channel transmitted to the component carrier or cell provided by the non-anchor base station 50 ′. It may be transmitted. For example, the uplink control channel transmitted to the component carrier or cell provided by the anchor base station 50 is higher than the uplink control channel transmitted to the component carrier or cell provided by the non-anchor base station 50 ′. Transmission of the uplink control channel to the component carrier or cell provided by the non-anchor base station 50 ′ may be stopped.

  The anchor base station 50 may be selected according to any criterion. In one embodiment, the anchor base station 50 may be a base station in which a primary cell is set. In another example, the anchor base station 50 may be a base station that collectively provides a specific protocol layer. For example, in the LTE-Advanced system, RRC (Radio Resource Control), PDCP (Packet Data Convergence Protocol), RLC (Radio Link Control), MAC (Medium Access Control) and PHY layers are used. A base station that collectively provides any specific protocol layer may be set as the anchor base station 50.

  In another embodiment, the anchor base station 50 may be a base station in which an SRB (Signaling Radio Bearer) is set. Alternatively, the anchor base station 50 may be a base station that manages an interface with the core node. Alternatively, the anchor base station 50 may be a base station for which security is set. In this case, the anchor base station 50 collectively executes security processing for communication between the user apparatus 100 and the own station and other non-anchor base stations 50 ′.

  In another embodiment, the anchor base station 50 may be a macro base station. That is, in the LTE-Advanced system, a heterogeneous network (HetNet) in which a plurality of types of base stations having different cell radii is used is being studied. For example, a macro base station is used as a high-power base station that covers a relatively large cell radius, and a pico base station is used as a low-power base station that covers a relatively small cell radius. Alternatively, an indoor femto base station is used. The anchor base station 50 may be any of these different types of base stations.

  In another embodiment, the anchor base station 50 may be a stand-alone base station that can provide communication service to the user apparatus 100 independently.

  In another embodiment, for example, when inter-base station CA is executed among three or more base stations 50, the priority may be set in descending or ascending order of the identifiers (indexes) of the base stations 50.

  In another embodiment, transmission priorities may be set in the order of good or bad radio quality between the user apparatus 100 and each base station 50. For example, the transmission priority may be set in the order of good or poor downlink or uplink radio quality.

  In another embodiment, a priority may be set for each base station 50 in the wireless communication system 10, and transmission of an uplink control channel to each base station 50 may be controlled according to the priority.

  In other embodiments, transmission of the uplink control channel to each base station 50 may be controlled according to the priority of the bearer associated with communication in each component carrier or cell. For example, the priority of SRB data is set highest, the priority of high QoS (Quality of Service) data such as voice is set next highest, and finally the priority of low QoS data such as BE data is set lowest. You may be made to do.

  In other embodiments, transmission of the uplink control channel to each base station 50 may be controlled according to the average data rate that each base station 50 can provide. The average data rate can be measured by the user apparatus 100.

  In other embodiments, the transmission priority may be preset according to the type of the uplink control channel. In the inter-base station CA in which scheduling is performed using different schedulers, the situation in which PUCCH-SRs are simultaneously transmitted in a plurality of cells is different from the intra-base station CA in which scheduling is performed using a single scheduler. Is assumed. In this situation, when PUCCH-SR cannot be transmitted simultaneously in a plurality of cells and priority control is applied, some transmission priority needs to be set. For example, a PUCCH-SR with a smaller number of transmissions, that is, a PUCCH-SR with a smaller number of retransmissions may be preferentially transmitted. This is because a newer scheduling request is considered to reflect the latest communication demand of the user apparatus 100.

  As described above, different base stations 50 and schedulers are used in the inter-base station CA. For this reason, each base station 50 performs communication processing with the user apparatus 100 such as scheduling, delivery confirmation, and radio quality measurement in parallel, such as PUCCH-SR, PUCCH-ACK / NACK, and PUCCH-CQI. It is assumed that all uplink control information (UCI) combinations are transmitted simultaneously. Thus, in the inter-base station CA in which scheduling is performed using different schedulers, a situation in which PUCCH-ACK / NACK is simultaneously transmitted in a plurality of cells is assumed. In this situation, when PUCCH-ACK / NACK cannot be transmitted simultaneously in a plurality of cells and priority control is applied, some transmission priority needs to be set. For example, PUCCH-ACK may be transmitted with priority over PUCCH-NACK. Even if the base station 50 does not receive the PUCCH-NACK, if the PUCCH-ACK is not received within a predetermined period, the base station 50 determines that the user apparatus 100 has failed to receive. This is because retransmission is executed. Alternatively, when PUCCH-NACK is transmitted, priority control may be performed in consideration of how many times the PUCCH-NACK is PUCCH-NACK for HARQ (Hybrid Automatic Repeat Request). In one embodiment, transmission of PUCCH-NACK for earlier HARQ may be prioritized. In this case, for example, in the case of PUCCH-NACK for the third HARQ and PUCCH-NACK for the fifth HARQ, PUCCH-NACK for the third HARQ may be prioritized.

  Note that the various settings of the transmission priority described above may be used alone or in combination. For example, when the embodiment in which the transmission to the anchor base station is prioritized and the embodiment in which the SCellIndex is used are combined, first, the transmission of the uplink control channel to the anchor base station is prioritized, and the non-anchor base The transmission priority between stations may be set using SCellIndex.

  Next, with reference to FIG. 3, the simultaneous transmission process of the uplink control channel in the user apparatus according to an embodiment of the present invention will be described. FIG. 3 is a flowchart illustrating a PUCCH transmission process according to an embodiment of the present invention.

  As shown in FIG. 3, in step S101, the user apparatus 100 detects any event in which PUCCH is simultaneously transmitted in a plurality of cells. The event may be, for example, when the user apparatus 100 requests a scheduling request from the base station 50. Whether the user apparatus 100 has received a data channel from the base station 50 and has successfully received the data channel. Even when the user apparatus 100 is requested to measure the radio quality such as CQI and report the measured radio quality from the base station 50. Good.

  In step S102, in response to the event, the simultaneous transmission availability determination unit 120 determines whether PUCCH can be transmitted simultaneously in a plurality of cells. In one embodiment, the simultaneous transmission permission determination unit 120 may determine whether simultaneous transmission is possible by determining whether the user apparatus 100 has a function of simultaneously transmitting PUCCH via a plurality of cells. In another embodiment, the simultaneous transmission availability determination unit 120 may determine whether simultaneous transmission is possible by determining whether the user apparatus 100 can sufficiently secure transmission power for simultaneous transmission.

  When it is determined that the PUCCH can be transmitted simultaneously in a plurality of cells (S102: Y), the flow proceeds to step S103, and the transmission control unit 130 transmits the PUCCH to the transmission / reception unit 110 simultaneously in the plurality of cells. Instruct.

  On the other hand, when it is determined that the PUCCH cannot be simultaneously transmitted in a plurality of cells (S102: N), the flow moves to step S104, and the transmission control unit 130 prioritizes the transmission target PUCCH according to the transmission priority. Then, the transceiver unit 110 is instructed to transmit the PUCCH to the base station 50 according to the priority order.

  In one embodiment, the transmission control unit 130 determines whether the applied CA is an intra-base station CA or an inter-base station CA, and prioritizes transmission target PUCCHs according to the intra-base station CA or the inter-base station CA. May be.

  When the intra-base station CA is applied, the transmission control unit 130 determines the priority based on the preset or dynamically set PUCCH type, the priority notified from the base station 50, and the cell priority. The transmission priority of a transmission target PUCCH may be determined according to one or more priorities, and the transmission target PUCCH may be transmitted to a single base station 50 via a corresponding cell according to the determined transmission priority.

  On the other hand, when the inter-base station CA is applied, the transmission control unit 130 determines the priority based on the preset or dynamically set type of PUCCH used in the case of the intra-base station CA, the base station 50 In addition to or in place of one or more of the priorities notified from the cell and the priority of the cell, the priority of the anchor base station 50, the priority according to the order of the identifiers of the base stations 50, Priority based on quality of radio quality between the base station 50 and the user apparatus 100, priority set in each base station 50, priority of bearers associated with each base station 50, and each base station can provide Different base stations that are connected to the transmission target PUCCH according to the determined transmission priority according to one or more priorities of different average data rates It may be transmitted to the 0.

  As mentioned above, although the Example of this invention was explained in full detail, this invention is not limited to the specific embodiment mentioned above, In the range of the summary of this invention described in the claim, various deformation | transformation・ Change is possible.

10 radio communication system 50 base station 100 user apparatus 110 transmission / reception unit 120 simultaneous transmission availability determination unit 130 transmission control unit 131 carrier aggregation type determination unit

Claims (6)

A transmission / reception unit that transmits and receives a radio channel to and from a base station via a plurality of cells set by carrier aggregation;
In response to the occurrence of an event for simultaneously transmitting uplink control channels in the plurality of cells, a simultaneous transmission availability determination unit that determines whether uplink control channels can be simultaneously transmitted in the plurality of cells;
When uplink control channels can be transmitted simultaneously in the plurality of cells, the transceiver unit is instructed to transmit uplink control channels simultaneously in the plurality of cells, and uplink control channels are transmitted simultaneously in the plurality of cells. If not possible, a transmission control unit for controlling transmission of the uplink control channel according to transmission priority;
A user device comprising:
The transmission control unit includes a carrier aggregation type determination unit that determines whether the applied carrier aggregation is intra-base station carrier aggregation or inter-base station carrier aggregation,
The transmission control unit is a user device that sets the transmission priority according to the determination result.   When the intra-base station carrier aggregation is applied, the transmission control unit determines a transmission priority of the uplink control channel according to a priority based on a type of the uplink control channel, and according to the determined transmission priority The user apparatus according to claim 1, wherein the user equipment is controlled to transmit the uplink control channel to the base station via a corresponding cell. The type of the uplink control channel includes an uplink control channel that transmits a scheduling request, a delivery confirmation and a radio quality report,
The transmission priority is according to an order of an uplink control channel that transmits the scheduling request, an uplink control channel that transmits the acknowledgment, and an uplink control channel that transmits the radio quality report. User device.   When the inter-base station carrier aggregation is applied, the transmission control unit determines a transmission priority of the uplink control channel according to a priority that gives priority to the anchor base station, and increases the uplink according to the determined transmission priority. The user apparatus as described in any one of Claims 1 thru | or 3 controlled to transmit a link control channel to the said base station via a corresponding cell.   The transmission control unit allocates a relatively large transmission power to the uplink control channel having a high transmission priority, and allocates a relatively small transmission power to the uplink control channel having a low transmission priority, or performs transmission. The user apparatus according to claim 1, wherein the user apparatus is canceled. A transmission control method in a user apparatus that transmits / receives a radio channel to / from a base station via a plurality of cells set by carrier aggregation,
Detecting the occurrence of an event of simultaneously transmitting uplink control channels in the plurality of cells;
Determining whether uplink control channels can be transmitted simultaneously in the plurality of cells;
When the uplink control channel can be transmitted simultaneously in the plurality of cells, the uplink control channel is transmitted simultaneously in the plurality of cells, and when the uplink control channel is not simultaneously transmitted in the plurality of cells, the transmission priority Controlling the transmission of the uplink control channel according to:
Have
Determining whether the applied carrier aggregation is intra-base station carrier aggregation or inter-base station carrier aggregation; and
Setting the transmission priority according to the result of the determination;
A transmission control method further comprising:

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