JP2014183508A - Base station and method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a technique to deactivate a secondary cell at timing intended by a base station.SOLUTION: One aspect of the invention relates to a base station that includes: a signal transmitting/receiving unit for communicating radio signals with a user device; a cell management unit for managing a primary cell and a secondary cell allocated to the user device to communicate the radio signal; and a timer management unit for managing a timer to control an active state of the secondary cell. The timer management unit includes a secondary cell deactivation timer activated or re-activated in response to a prescribed trigger in order to deactivate the secondary cell. When the secondary cell deactivation timer expires, the cell management unit instructs the signal transmitting/receiving unit to transmit a deactivation instruction to deactivate the secondary cell to the user device allocated to the secondary cell.

Description

  The present invention relates to wireless communication technology, and more particularly to wireless communication 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 technology, an LTE carrier (also referred to as a component carrier) 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 possible. It is intended to be realized.

  In the carrier aggregation, for example, an arrangement of component carriers as shown in FIG. 1 is assumed. In Case 1, two adjacent 20 MHz bands can be used as a 40 MHz band by carrier aggregation. Case 1 is effectively used in a case where a continuous band larger than 20 MHz can be secured, and can achieve a throughput higher than that of the LTE system while ensuring backward compatibility with the LTE system. In case 2, two 10 MHz bands separated from each other can be used as a 20 MHz band by carrier aggregation. Case 2 is effectively used when the frequency band allocation to the operator is fragmented, and can achieve a throughput higher than that of the LTE system while ensuring backward compatibility with the LTE system. .

  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. For example, in the specific example shown in FIG. 1, one of the two component carriers may be set as a primary cell and the other may be set as a secondary cell.

  The primary cell is a cell similar to 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 Control), and PUCCH (Physical Uplink Control, PUCCH (Physical Uplink Control). (Channel) 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). In the secondary cell, the user apparatus does not transmit PUCCH and PRACH. In addition, immediately after the secondary cell is set in the user apparatus, it is in an inactive state, and communication or scheduling is possible only when it is activated in the MAC (Medium Access Control) layer. For this reason, in order to make the set secondary cell in a communicable state, that is, in a schedulable state, it is necessary to change the secondary cell to the active state.

  In the LTE-Advanced system currently under consideration, in order to transition the secondary cell to the active state and the inactive state, as shown in FIG. 2, the base station sends a MAC CE (Control Element) to the user equipment in the MAC layer. By transmitting, the user apparatus is instructed to activate / deactivate the set secondary. When receiving the explicit state transition instruction, the user apparatus transitions the secondary cell to the instructed state.

  Further, when receiving the MAC CE for activating the secondary cell from the base station, the user apparatus activates the secondary cell and activates the SCell Deactivation Timer for the secondary cell. On the other hand, the base station also activates an SCell Deactivation Timer for the secondary cell when receiving an acknowledgment delivery acknowledgment (ACK) for the MAC CE from the user apparatus. That is, a base station and a user apparatus hold | maintain each SCell Deactivation Timer, and manage the state of the said activated secondary cell. After the SCell Deactivation Timer is activated, when the base station schedules a new radio resource to the user apparatus in the secondary cell, the base station and the user apparatus reset their SCell Deactivation Timer and restart. After that, when the SCell Deactivation Timer exceeds a predetermined threshold value or receives an explicit state transition instruction for deactivating the secondary cell from the base station, the user apparatus sets the secondary cell to the inactive state. Transition. When the base station also receives notification from the user apparatus that the secondary cell has been deactivated, the base station determines that the secondary cell has been deactivated and stops scheduling radio resources to the user apparatus in the secondary cell. In this way, it is possible to match the active state / inactive state of the secondary cell between the base station and the user apparatus.

3GPP TS 36.321 V11.1.0 (2012-12) 3GPP TS 36.331 V11.2.0 (2012-12)

  However, the settable value of the SCell Deactivation Timer is defined in the standard specification (3GPP TS 36.331 V11.2.0), and the secondary cell has a value longer than the defined value (such as 1.28 seconds) in the user apparatus. Cannot be deactivated autonomously. For this reason, the secondary cell cannot be deactivated at the timing intended by the network side (base station).

  In view of the above problems, an object of the present invention is to provide a technique for deactivating a secondary cell at a timing intended by a base station.

  In order to solve the above problems, an aspect of the present invention provides a signal transmission / reception unit that communicates a radio signal with a user apparatus, and a cell that manages a primary cell and a secondary cell that are allocated to the user apparatus for communicating the radio signal. A base station having a management unit and a timer management unit that manages a timer for controlling an active state of the secondary cell, wherein the timer management unit is configured to perform predetermined activation in order to deactivate the secondary cell. Having a secondary cell deactivation timer that is activated or restarted in response to an opportunity, and when the secondary cell deactivation timer expires, the cell management unit sends the user device assigned to the secondary cell to the user device The signaling to send a deactivation command to deactivate the secondary cell A base station to tell the department.

  Another aspect of the present invention includes a signal transmission / reception unit that communicates radio signals with a user apparatus, a cell management unit that manages primary cells and secondary cells assigned to the user apparatus for communicating the radio signals, and the secondary And a timer management unit that manages a timer for controlling the active state of the cell, wherein the timer management unit is repeatedly restarted at a predetermined cycle in order to repeatedly activate the secondary cell. A cycle timer, and a cycle timer control means for stopping the cycle timer, each time the cycle timer expires before being stopped by the cycle timer control means, the cell management unit An activation command for activating the secondary cell is sent to the user equipment assigned to A base station which instructs the signal receiving unit to.

  According to the present invention, a secondary cell can be deactivated at a timing intended by the base station.

FIG. 1 is a diagram schematically illustrating carrier aggregation. FIG. 2 is a diagram schematically illustrating an operation example of the SCell Deactivation Timer. FIG. 3 is a diagram schematically illustrating a wireless communication system according to an embodiment of the present invention. FIG. 4 is a diagram schematically showing a first embodiment of the present invention. FIG. 5 is a block diagram illustrating a configuration of a base station according to the first embodiment of the present invention. FIG. 6 is a flowchart showing cell management processing in the base station according to the first embodiment of the present invention. FIG. 7 schematically shows a second embodiment of the present invention. FIG. 8 is a block diagram illustrating a configuration of a base station according to the second embodiment of the present invention. FIG. 9 is a flowchart showing an exemplary cell management process in the base station according to the second embodiment of the present invention. FIG. 10 is a diagram schematically showing a modification of the second embodiment of the present invention. FIG. 11 is a flowchart showing another example of cell management processing in the base station according to the second embodiment of the present invention.

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

  An outline of an embodiment of the present invention to be described later is that a base station that communicates with a user apparatus by carrier aggregation extends the deactivation timing of the secondary cell defined in the standard specifications, and therefore the timing intended by the base station. To deactivate the active secondary cell.

  In one embodiment, the user equipment is controlled not to autonomously deactivate the secondary cell (ie, the standardized inactivity timer is set to an infinite value), and explicit inactivity from the base station The secondary cell is deactivated according to the activation instruction. In this embodiment, the base station provides a secondary cell deactivation timer (SCell Deactivation Timer_eNB) for deactivating the secondary cell separately from the SCell Deactivation Timer defined in the standard specification for each secondary cell. Have. In response to a predetermined activation trigger, the base station starts or restarts the secondary cell deactivation timer, and when the secondary cell deactivation timer expires, the base station sends the secondary cell to the user apparatus assigned to the secondary cell. Send a deactivation command to deactivate. As a result, the base station deactivates the secondary cell at the timing intended by the base station by disabling the autonomous deactivation function of the user device and sending an explicit deactivation command to the user device. It becomes possible to become.

  In another embodiment, for each secondary cell, the base station repeatedly activates the secondary cell, so that the periodic timer is repeatedly restarted at a predetermined period, and the period timer is stopped. Periodic timer control means (Inactive Timer, Inactive Counter). Until the period timer is stopped by the period timer control means, the base station transmits an activation command for activating the secondary cell to the user apparatus assigned to the secondary cell every time the period timer expires . In this embodiment, the user apparatus has an SCell Deactivation Timer set for a period (1.28 seconds) defined by the standard specification. Upon receiving the periodic activation command from the base station, the user equipment restarts the timer, so that the secondary cell is autonomously deactivated while receiving the periodic activation command from the base station. Do not activate. As a result, the base station controls the autonomous deactivation function of the user apparatus, and periodically transmits an activation command to the user apparatus, thereby deactivating the secondary cell at the timing intended by the base station. It becomes possible to activate.

  First, a radio communication system according to an embodiment of the present invention will be described with reference to FIG. FIG. 3 is a diagram schematically illustrating a wireless communication system according to an embodiment of the present invention.

  As illustrated in FIG. 3, the wireless communication system 10 is a wireless communication system that realizes wireless communication using carrier aggregation, such as an LTE-Advanced system. The radio communication system 10 includes a base station (eNB) 100 and one or more user apparatuses (UE) 200. The user apparatus 200 may typically be any appropriate user apparatus having a wireless communication function such as a mobile phone, a smartphone, a tablet, and a mobile router as illustrated.

  The base station 100 wirelessly connects to the user apparatus 200, thereby transmitting downlink (DL) data received from a communication-connected upper station or server (not shown) to the user apparatus 200 and from the user apparatus 200. The received uplink (UL) data is transmitted to an upper station (not shown).

  As illustrated, the base station 100 is capable of communicating with the user apparatus 200 via a primary cell (PCell) and a secondary cell (SCell) by applying carrier aggregation and simultaneously using a plurality of component carriers. . The primary cell is a highly reliable primary cell that ensures connectivity with the user apparatus 200, and the secondary cell is additionally set in the user apparatus 200 that is connected to the primary cell. In the primary cell, the user apparatus 200 can receive PDCCH and PDSCH and transmit PUCCH, PUSCH, and PRACH. Moreover, when changing a primary cell, the user apparatus 200 needs to perform a hand-over. In addition, addition and deletion of secondary cells are executed by RRC configuration. Immediately after the secondary cell is set in the user apparatus 200, it is in an inactive state, and communication in the secondary cell becomes possible only after being activated in the MAC layer. For this reason, in order to make the set secondary cell in a communicable state, that is, in a schedulable state, it is necessary to change the secondary cell to the active state. In order to transition the secondary cell to the active state and the inactive state, the base station 100 activates the set secondary by transmitting the MAC CE of the activation command / deactivation command to the user apparatus 200 in the MAC layer. Instruct user device 200 to deactivate. Upon receiving these explicit state transition instructions, the user apparatus 200 transitions the secondary cell to the instructed state.

  Each of the base station 100 and the user apparatus 200 has its own SCell Deactivation Timer for each activated secondary cell according to the standard specification. The SCell Deactivation Timer is used for deactivating the secondary cell when the active secondary cell is unused for a predetermined period of time and avoiding the waste of radio resources of the secondary cell and the battery of the user apparatus 200. . Specifically, when the activation command for activating the secondary cell is received from the base station 100, the user apparatus 200 activates the secondary cell and activates its own SCell Deactivation Timer. On the other hand, the base station 200 also activates its own SCell Deactivation Timer when receiving acknowledgment acknowledgment (ACK) for the activation command from the user apparatus 200. That is, the base station 100 and the user apparatus 200 hold their own SCell Deactivation Timer and manage the state of the activated secondary cell.

  Further, when the base station 100 schedules a new radio resource in the secondary cell after the SCell Deactivation Timer is activated, the base station 100 and the user apparatus 200 reset their SCell Deactivation Timer and restart. Thereafter, when the user's own SCell Deactivation Timer exceeds a predetermined threshold value (1.28 seconds in the standard) or receives a deactivation command from the base station 100 to deactivate the secondary cell, The apparatus 200 changes the secondary cell to the inactive state. When the base station 100 also receives a notification from the user apparatus 200 that the secondary cell has been deactivated, the base station 100 determines that the secondary cell has been deactivated, and performs scheduling of radio resources to the user apparatus 200 in the secondary cell. quit. In this way, the active state / inactive state of the secondary cell can be matched between the base station 100 and the user apparatus 200.

  In a typical hardware configuration, the base station 100 has 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 comprises an interface device for exchanging various data and / or instructions with a device, a host station, an external server, an operator and the like. For example, each function and process of the base station 100 to be described later is performed by loading data and programs stored in the auxiliary storage device into the memory device via the communication device and / or interface device, and the CPU performing data according to the loaded program. It is realized by processing.

  Next, a base station according to the first embodiment of the present invention will be described with reference to FIGS. In the first example, the user apparatus 200 is controlled not to autonomously deactivate the secondary cell, and deactivates the secondary cell according to an explicit deactivation command from the base station 100. As defined in the standard specification, each of the base station 100 and the user apparatus 200 is activated each time a secondary cell is activated, and a timer (SCell Deactivation Timer) that autonomously deactivates the secondary cell upon expiration. ). In this embodiment, as shown in FIG. 4, a secondary cell deactivation timer (SCell Deactivation Timer_eNB) for deactivating the secondary cell for each secondary cell is provided separately from the SCell Deactivation Timer. The SCell Deactivation Timer_eNB is set to a predetermined period intended by the network side to deactivate the secondary cell. Further, the SCell Deactivation Timer between the base station 100 and the user apparatus 200 is set infinitely (SCell Deactivation Timer = infinity). That is, the user apparatus 200 does not deactivate the secondary cell autonomously, but deactivates the secondary cell according to the deactivation command transmitted from the base station 100 at the timing determined by the SCell Deactivation Timer_eNB.

  Specifically, when the SCell Deactivation Timer_eNB managed by the base station 100 expires, the base station 100 transmits a deactivation command (Deactivation command) for deactivating the secondary cell to the user apparatus 200. When receiving the deactivation command, the user apparatus 200 deactivates the secondary cell. Thereby, the base station 100 disables the autonomous deactivation function of the user apparatus 200, and transmits an explicit deactivation command to the user apparatus 200, whereby the base station 100 performs the secondary cell at the timing intended by the base station 100. Can be deactivated.

  As shown in the figure, the SCell Deactivation Timer_eNB is activated and restarted in response to a predetermined activation opportunity. The predetermined activation trigger includes, for example, a timing at which the secondary cell is activated and a timing at which a control channel (PDCCH) indicating new transmission for the secondary cell is transmitted to the user apparatus 200.

  FIG. 5 is a block diagram illustrating a configuration of a base station according to the first embodiment of the present invention. As illustrated in FIG. 5, the base station 100 includes a signal transmission / reception unit 110, a cell management unit 120, and a timer management unit 130. The timer management unit 130 includes a secondary cell deactivation timer (SCell Deactivation Timer_eNB) 131. Have.

  The signal transmission / reception unit 110 communicates radio signals with the user apparatus 200. In the carrier aggregation, the signal transmission / reception unit 110 exchanges a radio signal including a data signal and / or a control signal with the user apparatus 200 via the primary cell and / or the secondary cell. For example, the signal transmission / reception unit 110 converts data provided from the server in response to a request from the user device 200 into a radio signal, and transmits the wireless signal to the requesting user device 200. In addition, the signal transmission / reception unit 110 converts control information such as scheduling information and various signaling necessary for wireless communication with the user apparatus 200 into a wireless signal, and transmits the wireless signal to the user apparatus 200. In addition, when the user apparatus 200 transmits a data signal using radio resources of the assigned primary cell and / or secondary cell, the signal transmission / reception unit 110 transfers the received data signal to a transmission destination server. Further, when the user apparatus 200 transmits a control signal using the radio resources of the assigned primary cell and / or secondary cell, the signal transmission / reception unit 110 uses the received control signal for subsequent communication, and / or Or, transfer to upper station.

  The cell management unit 120 manages a primary cell and a secondary cell that are allocated to the user apparatus 200 in order to communicate radio signals. The primary cell (PCell) is a highly reliable cell that ensures connectivity with the user apparatus 200, and the user apparatus 200 needs to execute a handover when changing the primary cell. The secondary cell (SCell) is a cell that is added to the primary cell and set in the user apparatus 200. Addition and deletion of secondary cells are performed by RRC configuration.

  The secondary cell is in an inactive state immediately after being set in the user apparatus 200 by the RRC configuration. For this reason, in order to make the set secondary cell in a communicable state, that is, in a schedulable state, it is necessary to change the secondary cell to the active state. In the LTE-A system, in order to transition the secondary cell to the active state and the inactive state, the base station 100 transmits the MAC CE of the activation command and the deactivation command to the user apparatus 200 in the MAC layer, respectively. The user apparatus 200 is transitioned to an active state / inactive state.

  When receiving the activation command from the base station 100, the user apparatus 200 activates the secondary cell and activates the SCell Deactivation Timer. Further, the secondary cell is deactivated when the SCell Deactivation Timer managed for the secondary cell expires. However, in the present embodiment, the SCell Deactivation Timer of the user apparatus 200 is set to infinity so that the user apparatus 200 does not deactivate the secondary cell autonomously (SCell Deactivation Timer = infinity). For example, the cell management unit 120 may instruct the user apparatus 200 to set the SCell Deactivation Timer of the user apparatus 200 to infinity. Similarly, the SCell Deactivation Timer of the base station 100 may also be set infinitely, and the active state of the secondary cell is controlled based on the SCell Deactivation Timer_eNB 131.

  The timer management unit 130 includes an SCell Deactivation Timer_eNB 131 for deactivating the secondary cell, in addition to the SCell Deactivation Timer defined in the standard specification. The SCell Deactivation Timer_eNB 131 is activated and restarted in response to a predetermined activation trigger and a restart trigger. When the SCell Deactivation Timer_eNB 131 expires, the cell management unit 120 instructs the signal transmission / reception unit 110 to transmit a deactivation command for deactivating the secondary cell to the user apparatus 200 allocated to the secondary cell. .

  The predetermined activation trigger and restart trigger may include, for example, a timing for activating a secondary cell and a timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200. Good. Here, the timing at which the secondary cell is activated may be the timing at which the signal transmission / reception unit 110 transmits an activation command for activating the secondary cell to the user apparatus 200. Alternatively, the signal transmission / reception unit 110 may It may be the timing at which an acknowledgment response acknowledgment (ACK) for the activation command is received from the user apparatus 200. The timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200 may be the timing at which the signal transmitting / receiving unit 110 transmits the PDCCH to the user apparatus 200, or the PDCCH Is an instruction for downlink transmission, it is the timing at which an ACK for the PDCCH is received from the user apparatus 200, and when the PDCCH is an uplink transmission instruction, the corresponding PUSCH is received from the user apparatus 200 It may be timing.

  Note that the PDCCH that becomes the start trigger and the restart trigger includes MAC CE, SRB (Signaling Radio Bearer) data, PDCP / RLC (Packet Data Convergence Protocol / Radio Link Control) control data, SIP (Session Initiation Proto) The PDCCH for transmission of control signals such as control signals may be excluded.

  In addition, when the cell management unit 120 deactivates the secondary cell due to another factor (for example, when a deactivation instruction is given to the secondary cell due to deterioration of the quality of the secondary cell), that is, the SCell Deactivation Timer_eNB When the secondary cell is deactivated without responding to the expiration of 131, the timer management unit 130 resets the SCell Deactivation Timer_eNB 131 and stops it.

  FIG. 6 is a flowchart showing cell management processing in the base station according to the first embodiment of the present invention. The cell management process is started, for example, when the base station 100 activates the secondary cell set in the user apparatus 200.

  As illustrated in FIG. 6, in step S101, the base station 100 activates the SCell Deactivation Timer_eNB 131. That is, since the secondary cell set in the user apparatus 200 is activated and a predetermined activation trigger occurs, the base station 100 activates the SCell Deactivation Timer_eNB 131.

  In step S <b> 102, the base station 100 determines whether a predetermined restart opportunity has occurred for the active SCell Deactivation Timer_eNB 131. The predetermined restart trigger may be, for example, a timing at which the signal transmission / reception unit 110 transmits to the user apparatus 200 a control channel (PDCCH) indicating new transmission for an active secondary cell. In addition, the predetermined restart trigger may be the same as the restart trigger of the SCell Deactivation Timer defined in the standard. When a predetermined restart opportunity has occurred (S102: Y), the base station 100 returns to step S101 and restarts the SCell Deactivation Timer_eNB 131. On the other hand, when the predetermined restart opportunity has not occurred (S102: N), the base station 100 proceeds to Step S103.

  In step S103, the base station 100 determines whether the SCell Deactivation Timer_eNB 131 has expired. When the SCell Deactivation Timer_eNB 131 has not expired (S103: N), the base station 100 returns to Step S102 and continues to determine whether or not a predetermined restart opportunity has occurred until the SCell Deactivation Timer_eNB 131 expires. On the other hand, when the SCell Deactivation Timer_eNB 131 expires (S103: Y), the base station 100 transmits an inactivity command for deactivating the secondary cell to the user apparatus 200 in Step S104, and the cell management process Ends.

  Next, a base station according to a second embodiment of the present invention will be described with reference to FIGS. In the second embodiment, the base station 100 repeatedly activates the secondary cell for each secondary cell, so that the period timer (Periodic Timer) that is repeatedly restarted at a predetermined period and the period timer are stopped. Periodic timer control means (Inactive Timer, Inactive Counter). Each time the periodic timer expires before being stopped by the periodic timer control means, the base station 100 transmits an activation command for activating the secondary cell to the user apparatus 200 assigned to the secondary cell. In this embodiment, unlike the first embodiment, it is assumed that the deactivation timer for standardization is set to a finite value.

  As defined in the standard specification, each of the base station 100 and the user apparatus 200 is activated each time a secondary cell is activated, and a timer (SCell Deactivation Timer) that autonomously deactivates the secondary cell upon expiration. ). Upon receiving a periodic activation command from the base station 100, the user apparatus 200 restarts the timer. For this reason, while receiving a periodic activation command from the base station 100, the user apparatus 200 does not autonomously deactivate the secondary cell. When the periodic timer is stopped by the periodic timer control means, the base station 100 stops transmitting the activation command to the user apparatus 200. Thereafter, when the Scell Deactivation Timer expires, the user apparatus 200 deactivates the secondary cell. As described above, the base station 100 transmits the activation command periodically to the user apparatus 200 in order to control the autonomous deactivation function of the user apparatus 200, so that the base station 100 performs the secondary operation at the timing that the base station 100 intends. It becomes possible to deactivate a cell.

  FIG. 7 schematically shows a second embodiment of the present invention. In the embodiment shown in FIG. 7, the periodic timer control means is a stop timer (Inactive Timer) that times a predetermined period. As illustrated in FIG. 7, the base station 100 transmits an activation command to the user apparatus 200 every time a periodic timer expires during the time measurement of the inactive timer. When the inactive timer expires, the base station 100 stops the periodic timer and stops transmitting the activation command to the user apparatus 200. Thereafter, when the SCell Deactivation Timer of the user apparatus 200 expires, the user apparatus 200 autonomously deactivates the secondary cell.

  FIG. 8 is a block diagram illustrating a configuration of a base station according to the second embodiment of the present invention. As illustrated in FIG. 8, the base station 100 includes a signal transmission / reception unit 110, a cell management unit 120, and a timer management unit 130. In addition, the timer management unit 130 includes a periodic timer 132 and a periodic timer control unit 133.

  The signal transmission / reception unit 110 communicates radio signals with the user apparatus 200. In the carrier aggregation, the signal transmission / reception unit 110 exchanges a radio signal including a data signal and / or a control signal with the user apparatus 200 via the primary cell and / or the secondary cell. For example, the signal transmission / reception unit 110 converts data provided from the server in response to a request from the user device 200 into a radio signal, and transmits the wireless signal to the requesting user device 200. In addition, the signal transmission / reception unit 110 converts control information such as scheduling information and various signaling necessary for wireless communication with the user apparatus 200 into a wireless signal, and transmits the wireless signal to the user apparatus 200. In addition, when the user apparatus 200 transmits a data signal using radio resources of the assigned primary cell and / or secondary cell, the signal transmission / reception unit 110 transfers the received data signal to a transmission destination server. Further, when the user apparatus 200 transmits a control signal using the radio resources of the assigned primary cell and / or secondary cell, the signal transmission / reception unit 110 uses the received control signal for subsequent communication, and / or Or, transfer to upper station.

  The cell management unit 120 manages a primary cell and a secondary cell that are allocated to the user apparatus 200 in order to communicate radio signals. The primary cell (PCell) is a highly reliable cell that ensures connectivity with the user apparatus 200, and the user apparatus 200 needs to execute a handover when changing the primary cell. The secondary cell (SCell) is a cell that is added to the primary cell and set in the user apparatus 200. Addition and deletion of secondary cells are performed by RRC configuration.

  The secondary cell is in an inactive state immediately after being set in the user apparatus 200 by the RRC configuration. For this reason, in order to make the set secondary cell in a communicable state, that is, in a schedulable state, it is necessary to change the secondary cell to the active state. In the LTE-A system, in order to transition the secondary cell to the active state and the inactive state, the base station 100 transmits the MAC CE of the activation command and the deactivation command to the user apparatus 200 in the MAC layer, respectively. The user apparatus 200 is transitioned to an active state / inactive state.

  When receiving the activation command from the base station 100, the user apparatus 200 activates the secondary cell and activates the SCell Deactivation Timer. The SCell Deactivation Timer is set to an arbitrary finite value, and is set to a maximum of 1.28 seconds according to the standard specification. The base station 100 also activates the SCell Deactivation Timer when receiving an acknowledgment delivery acknowledgment (ACK) for the activation command from the user apparatus 200. That is, the base station 100 and the user apparatus 200 hold their own SCell Deactivation Timer and manage the state of the activated secondary cell. After the SCell Deactivation Timer is activated, when the cell management unit 120 schedules a new radio resource in the user cell 200 in the secondary cell, the cell management unit 120 and the user device 200 reset their SCell Deactivation Timer and restart. . Thereafter, when the SCell Deactivation Timer exceeds a predetermined period or a deactivation command for the secondary cell is transmitted to the user apparatus 200, the user apparatus 200 causes the secondary cell to transition to the inactive state, The management unit 120 also recognizes that the secondary cell has been deactivated by receiving an ACK for the deactivation command, and stops scheduling to the user apparatus 200 in the secondary cell.

  In addition to the SCell Deactivation Timer, the timer management unit 130 includes a periodic timer 132 (Periodic Timer) for repeatedly activating the secondary cell, and a periodic timer control means 133 for stopping the periodic timer 132. In this embodiment, the cycle timer control means 133 is a stop timer (Inactive Timer) 133.

  The period timer 132 is activated and restarted in response to a predetermined activation trigger and a restart trigger, and is repeatedly restarted at a predetermined period. When the period timer 132 expires, the cell management unit 120 transmits an activation command for activating the secondary cell to the user apparatus 200. When receiving the activation command, the user apparatus 200 activates the secondary cell, resets its own SCell Deactivation Timer, and restarts. In order to prevent the user apparatus 200 from autonomously deactivating the secondary cell, the restart period of the period timer 132 may be set shorter than the period of the SCell Deactivation Timer.

  The predetermined activation trigger and restart trigger of the periodic timer 132 include, for example, timing for activating the secondary cell and timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200. May be. Here, the timing at which the secondary cell is activated may be the timing at which the signal transmission / reception unit 110 transmits an activation command for activating the secondary cell to the user apparatus 200. Alternatively, the signal transmission / reception unit 110 may It may be the timing at which an acknowledgment response acknowledgment (ACK) for the activation command is received from the user apparatus 200. The timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200 may be the timing at which the signal transmitting / receiving unit 110 transmits the PDCCH to the user apparatus 200, or the PDCCH Is an instruction for downlink transmission, it is the timing at which an ACK for the PDCCH is received from the user apparatus 200, and when the PDCCH is an uplink transmission instruction, the corresponding PUSCH is received from the user apparatus 200 It may be timing.

  The stop timer 133 counts a predetermined period, and when the measured period exceeds a predetermined period, the timer management unit 130 stops the periodic timer 132. The predetermined period of the stop timer 133 is set longer than the restart period of the period timer 132. In order to extend the period of the SCell Deactivation Timer, the predetermined period of the stop timer 133 is set longer than the period of the SCell Deactivation Timer.

  The stop timer 133 is started and restarted in response to predetermined start triggers and restart triggers. The predetermined activation trigger and restart trigger include, for example, the timing when the secondary cell in the inactive state is activated and the timing when the control channel (PDCCH) indicating new transmission for the secondary cell is transmitted to the user apparatus 200. There may be. Here, the timing of activating the secondary cell, which is the trigger for starting the periodic timer 132, may be either the active state or the inactive state of the secondary cell immediately before the activation, It should be noted that at the timing when the secondary cell in the inactive state, which is the trigger for starting the stop timer 133, is activated, the state of the secondary cell immediately before the activation is the inactive state. The timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200 may be the timing at which the signal transmitting / receiving unit 110 transmits the PDCCH to the user apparatus 200, or the PDCCH Is an instruction for downlink transmission, it is the timing at which an ACK for the PDCCH is received from the user apparatus 200, and when the PDCCH is an uplink transmission instruction, the corresponding PUSCH is received from the user apparatus 200 It may be timing. However, the PDCCH that triggers the start and restart of the stop timer 133 includes uplink MAC CE, downlink MAC CE, SRB (Signaling Radio Bearer) data, PDCP / RLC (Packet Data Convergence Protocol / Radio Link Control) control data. The PDCCH for transmission of control signals such as upper control signals such as SIP (Session Initiation Protocol) signals may be excluded.

  When the periodic timer 132 expires while the stop timer 133 is activated, the cell management unit 120 transmits a signal transmission / reception unit to transmit an activation command for activating the secondary cell to the user apparatus 200 assigned to the secondary cell. In addition to instructing 110, the timer management unit 130 resets and restarts the periodic timer 132. When the stop timer 133 expires, the timer management unit 130 stops the periodic timer 132.

  FIG. 9 is a flowchart showing an exemplary cell management process in the base station according to the second embodiment of the present invention. The cell management process is started, for example, in response to the activation of the inactive secondary cell. That is, the base station 100 starts the period timer 132 and the stop timer 133.

  As shown in FIG. 9, in step S201, the base station 100 determines whether the stop timer 133 has expired. When the stop timer 133 has expired (S201: Y), the base station 100 determines that it is no longer necessary to restart the SCell Deactivation Timer of the user apparatus 200, stops the periodic timer 132 in step S205, and Stop the cell management process. On the other hand, when the stop timer 133 has not expired (S201: N), the base station 100 proceeds to step S202.

  In step S202, the base station 100 determines whether the period timer 132 has expired. When the period timer 132 has not expired (S202: N), the base station 100 returns to step S201 and counts the period timer 132 and the stop timer 133 until either the period timer 132 or the stop timer 133 expires. Continue. On the other hand, when the period timer 132 has expired (S202: Y), the base station 100 transmits an activation command for activating the secondary cell to the user apparatus 200 in step S203. Upon receiving the activation command, the user apparatus 200 activates the secondary cell and resets the SCell Deactivation Timer of the user apparatus 200 to restart. Thereby, the base station 100 can prevent the user apparatus 200 from autonomously deactivating the secondary cell until at least the restarted SCell Deactivation Timer expires.

  In step S204, the base station 100 resets and restarts the period timer 132. The restart may be, for example, the timing at which the base station 100 transmits an activation command to the user apparatus 200, or the base station 100 confirms delivery of acknowledgment (ACK) to the activation command from the user apparatus 200. It may be the timing of receiving. When the period timer 132 is restarted, the base station 100 returns to step S201 and repeats the above-described steps until the stop timer 133 expires and the period timer 132 is stopped.

  FIG. 10 schematically shows a modification of the second embodiment of the invention. In this embodiment, the base station 100 uses a stop counter (Inactive Counter) 133 as the cycle timer control means 133 that stops the cycle timer 132.

  The stop counter 133 counts the number of times that the periodic timer 132 is activated and restarted, and when the counted number exceeds a predetermined number, the timer management unit 130 stops the periodic timer 132. To extend the period of the SCell Deactivation Timer, the predetermined number of times of the stop counter 133 is set so that the product of the restart period of the period timer 132 and the predetermined number of times of the stop counter 133 is longer than the period of the SCell Deactivation Timer. The The stop counter 133 is activated in response to a predetermined activation trigger (Inactive Counter = 0). When the period timer 132 expires, the counter management unit 130 increments the stop counter 133. After that, when the stop counter 133 expires (inactive counter = 2 in the illustrated example), the periodic timer 132 is stopped, and the secondary cell is autonomously deactivated due to the expiration of the SCell Deactivation Timer of the user apparatus 200. The

  The predetermined activation trigger of the stop counter 133 includes, for example, a timing when the secondary cell in the inactive state is activated and a timing when a control channel (PDCCH) indicating new transmission to the secondary cell is transmitted to the user apparatus 200. May be. Here, the timing of activating the secondary cell, which is the trigger for starting the periodic timer 132, may be either the active state or the inactive state of the secondary cell immediately before the activation, It should be noted that when the secondary cell in the inactive state, which is the trigger for starting the stop counter 133, is activated, the state of the secondary cell immediately before the activation is the inactive state. The timing for transmitting a control channel (PDCCH) indicating new transmission to the secondary cell to the user apparatus 200 may be the timing at which the signal transmitting / receiving unit 110 transmits the PDCCH to the user apparatus 200, or the PDCCH Is an instruction for downlink transmission, it is the timing at which an ACK for the PDCCH is received from the user apparatus 200, and when the PDCCH is an uplink transmission instruction, the corresponding PUSCH is received from the user apparatus 200 It may be timing. However, the PDCCH that triggers the start of the stop counter 133 includes uplink MAC CE, downlink MAC CE, SRB (Signaling Radio Bearer) data, PDCP / RLC (Packet Data Convergence Protocol / Radio Link Control) control data, SIP (Ses The PDCCH for transmission of a control signal such as a higher-order control signal such as an initiation protocol signal may be excluded.

  FIG. 11 is a flowchart showing another example of cell management processing in the base station according to the second embodiment of the present invention. The cell management process is started, for example, in response to the activation of the inactive secondary cell. That is, the base station 100 starts the period timer 132 and the stop counter 133.

  As shown in FIG. 11, in step S301, the base station 100 determines whether the stop counter 133 has reached a predetermined number of times and has expired. If the stop counter 133 has expired (S301: Y), the base station 100 determines that it is no longer necessary to restart the SCell Deactivation Timer of the user apparatus 200, stops the periodic timer 132 in step S305, and Stop the cell management process. On the other hand, when the stop counter 133 has not expired (S301: N), the base station 100 proceeds to step S302.

  In step S302, the base station 100 determines whether the period timer 132 has expired. When the period timer 132 has not expired (S302: N), the base station 100 returns to step S301 and waits until the period timer 132 expires or the stop counter 133 reaches a predetermined number of times. Counting of time and stop counter 133 is continued. On the other hand, when the period timer 132 has expired (S302: Y), the base station 100 transmits an activation command for activating the secondary cell to the user apparatus 200 in step S303. Upon receiving the activation command, the user apparatus 200 activates the secondary cell and resets the SCell Deactivation Timer of the user apparatus 200 to restart. Thereby, the base station 100 can prevent the user apparatus 200 from autonomously deactivating the secondary cell until at least the restarted SCell Deactivation Timer expires.

  In step S304, the base station 100 resets the period timer 132 and restarts. The restart may be, for example, the timing at which the base station 100 transmits an activation command to the user apparatus 200, or the base station 100 confirms delivery of acknowledgment (ACK) to the activation command from the user apparatus 200. It may be the timing of receiving. When the cycle timer 132 is restarted and the stop counter 133 is incremented, the base station 100 returns to step S301 and repeats the above steps until the stop counter 133 reaches a predetermined number of times and stops the cycle timer 132.

  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.

DESCRIPTION OF SYMBOLS 10 Radio communication system 100 Base station 110 Signal transmission / reception part 120 Cell management part 130 Timer management part 131 Secondary cell deactivation timer (SCell Deactivation Timer_eNB)
132 period timer 133 period timer control means (stop counter)
200 User equipment

Claims (10)

A signal transmission / reception unit for communicating a radio signal with the user apparatus;
A cell management unit for managing a primary cell and a secondary cell allocated to the user apparatus for communicating the radio signal;
A timer management unit for managing a timer for controlling the active state of the secondary cell;
A base station having
The timer management unit has a secondary cell deactivation timer that is activated or restarted in response to a predetermined activation trigger in order to deactivate the secondary cell,
When the secondary cell deactivation timer expires, the cell management unit transmits and receives the signal to transmit a deactivation command for deactivating the secondary cell to the user apparatus assigned to the secondary cell. A base station that directs the department.   The base station according to claim 1, wherein the cell management unit controls the user apparatus so as not to autonomously deactivate the assigned secondary cell.   The base station according to claim 1 or 2, wherein the predetermined activation trigger includes a timing for activating the secondary cell and a timing for transmitting a control channel indicating new transmission to the secondary cell to the user apparatus.   The timer management unit stops the secondary cell deactivation timer when the cell management unit deactivates the secondary cell without responding to the expiration of the secondary cell deactivation timer. Base station. A method in a base station that communicates with a user equipment by carrier aggregation,
In response to a predetermined activation opportunity, starting or restarting a secondary cell deactivation timer for deactivating the secondary cell;
Transmitting a deactivation command for deactivating the secondary cell to the user equipment assigned to the secondary cell when the secondary cell deactivation timer expires. A signal transmission / reception unit for communicating a radio signal with the user apparatus;
A cell management unit for managing a primary cell and a secondary cell allocated to the user apparatus for communicating the radio signal;
A timer management unit for managing a timer for controlling the active state of the secondary cell;
A base station having
The timer management unit includes a periodic timer that is repeatedly restarted at a predetermined period in order to repeatedly activate the secondary cell, and a periodic timer control unit that stops the periodic timer,
Each time the period timer expires until it is stopped by the period timer control means, the cell management unit activates the secondary cell to the user apparatus assigned to the secondary cell. A base station that instructs the signal transmission / reception unit to transmit. The periodic timer control means is a stop timer that times a predetermined period,
Each time the periodic timer expires while the stop timer is counting, the cell management unit transmits an activation command for activating the secondary cell to the user apparatus assigned to the secondary cell. Instructing the signal transmitting and receiving unit;
The base station according to claim 6, wherein when the stop timer expires, the timer management unit stops the periodic timer. The periodic timer control means is a stop counter that counts the number of times the periodic timer is started and restarted,
When the periodic timer expires during the counting of the stop counter, the cell management unit transmits the activation command for activating the secondary cell to the user apparatus assigned to the secondary cell. Instruct the transmitter / receiver,
The base station according to claim 6, wherein the timer management unit stops the periodic timer when the counted number is equal to or greater than a predetermined number. A method in a base station that communicates with a user equipment by carrier aggregation,
Activating a periodic timer and a stop timer in response to activating the inactive secondary cell;
Determining whether the stop timer has expired;
When the stop timer expires, the periodic timer is stopped, and when the stop timer has not expired, the secondary cell is activated in the user equipment every time the periodic timer expires. Sending an activation command of the method to reset and restart the periodic timer. A method in a base station that communicates with a user equipment by carrier aggregation,
Activating a periodic timer and a stop counter in response to activating the inactive secondary cell;
Determining whether the stop counter is greater than or equal to a predetermined number of times;
When the stop counter is greater than or equal to a predetermined number of times, the periodic timer is stopped, and when the stop counter is less than the predetermined number of times, the secondary stop is sent to the user device every time the periodic timer expires. Sending an activation command to activate the cell, resetting and restarting the periodic timer, and incrementing the stop counter.

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