JP2014049931A - Base station in mobile communication system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To allow the number of secondary component carriers (SCCs or SCells) to be changed at the appropriate timing for the change in a communication system capable of carrier aggregation (CA).SOLUTION: A base station comprises: a communication unit for communicating with a user device; a management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device; and a generation unit for generating a control message at least including an addition/deletion message that indicates adding or deleting an SCC. When the management unit determines that an SCC should be added or deleted according to the result of comparison of a measured value with a threshold for a predetermined measuring target, the communication unit communicates the control message to the user device.

Description

  The disclosed invention relates to a base station or the like in a mobile communication system.

  In an LTE-Advanced communication system following the Long Term Evolution (LTE) system, communication can be performed using one or a plurality of carriers. Communication using a plurality of carriers is called carrier aggregation (CA). When CA is performed, a relatively reliable cell is set as a primary cell (P cell), and a carrier used in the P cell is called a primary component carrier (PCC). When performing CA, one or more other cells used for communication with the P cell are set as secondary cells (S cells), and the carrier used in the S cell is called a secondary component carrier (SCC). Conventional CA is described in Non-Patent Document 1.

3GPP TS36.300 V10.7.0 (2012-03)

  However, in Non-Patent Document 1, it is not stipulated as to when CA should be performed or when CA should not be performed, so changing the number of SCCs at an appropriate timing to change the number of SCCs as it is Is not easy.

  An object of the disclosed invention is to enable the number of SCCs to be changed at an appropriate timing for changing the number of secondary component carriers (SCCs) in a communication system capable of performing carrier aggregation (CA).

A base station according to the disclosed invention is
A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
And a generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is added or deleted, and the management unit adds an SCC according to a comparison result between a measurement value and a threshold value for a predetermined measurement target. When it is determined to delete, the communication unit is a base station that notifies the user apparatus of the control message.

  According to the disclosed invention, it is possible to change the number of SCCs at an appropriate timing for changing the number of SCCs in a communication system capable of performing CA.

The figure which shows the communication system used by embodiment. The figure which shows the example in which CA is performed. The figure which shows another example in which CA is performed. The flowchart of the operation example which a base station performs. The figure which shows the time change of the quality of a cell. The figure which shows the time change of the processing load of a base station. The figure which shows the time change of the data retention amount of a user apparatus. FIG. 8 is a flowchart showing an operation example in which the S cell addition / deletion method described with reference to FIG. 5-7 is used in parallel; The figure which shows the procedure at the time of a user apparatus performing initial access. The figure which shows the procedure at the time of a user apparatus reconnecting. The figure which shows the procedure at the time of a user apparatus performing a hand-over. The figure which shows the procedure at the time of a user apparatus changing from a DRX state to a non-DRX state. The figure which shows a mode that the addition and deletion of S cell are performed based on a periodic timing. The figure which shows the operation example at the time of adding or deleting S cell according to the request | requirement from a user apparatus. The figure which shows the example which adds S cell based on bearer classification. The functional block diagram of a base station.

  Embodiments will be described from the following viewpoints with reference to the accompanying drawings. In the figures, similar elements are given the same reference numbers or reference signs.

1． Communications system
2． Example of operation
2.1 Changing the number of S cells based on S cell quality
2.2 Changing the number of S cells based on eNB processing load
2.3 Changing the number of S cells based on data retention
2.4 Changing the number of S cells with other messages
2.5 Changing the number of S cells with DRX state transition
2.6 Periodic change of the number of S cells
2.7 Changing the number of S cells based on the request from the UE
2.8 Changing the number of S cells based on bearer type
3． Base station The classification of these items is not essential to the present invention, and the items described in two or more items may be used in combination as necessary, or the items described in one item may be used in another item. It may apply to the matters described in (as long as there is no conflict).

<1. Communication system>
FIG. 1 shows an LTE advanced communication system used in the embodiment. FIG. 1 shows a macro base station (eNB) 11, a macro cell 12 controlled by the macro base station (eNB) 11, a pico base station 13 located in the macro cell 12, and a pico cell 14 controlled by the pico base station 13. Further, another pico base station 15 located in the macro cell 12 and pico cells 16 and 17 controlled by the pico base station 15 are shown. The numbers and magnitude relationships of the macro base station (eNB), the pico base station, the macro cell, and the pico cell are merely examples, and can be any appropriate number and magnitude relationship. The macro base station (eNB) 11 and the pico base stations 13 and 15 can transmit and receive signals to and from each other through a communication link (for example, an x2 interface).

In the illustrated communication system, a user apparatus (UE) (not shown) can perform communication using one or a plurality of carriers. Each carrier is called a component carrier (CC). In the illustrated example, the frequency of the CC of the macrocell 12 is f _1, the frequency of the CC of the picocell 14 is f _3, the frequency of the CC of the picocell 16 is f _2, the frequency of the CC of the picocell 17 is f ₃ It is. Communication using a plurality of carriers is called carrier aggregation (CA). When CA is performed, a cell of a component carrier (CC) having relatively high reliability is set as a primary cell (P cell), and the CC used in the P cell is called a primary component carrier (PCC). One or more other cells used together with the P cell when performing CA are set as a secondary cell (S cell), and a CC used in the S cell is called a secondary component carrier (SCC). In order to perform CA, a plurality of CC cells need to be able to execute CA communication processing in addition to a plurality of CC cells overlapping in a region. In other words, combinations of CCs or cells that can execute CA are defined in advance. In the case of the illustrated example, CA can be performed by the macro cell 12 and the pico cell 14. Further, CA can be performed by the picocell 16 and the picocell 17. In the case of the illustrated example, CA cannot be performed with a combination of other cells.

  FIG. 2 illustrates carrier aggregation (CA) using a component carrier CC1 of the first system having a system bandwidth of 20 MHz and a component carrier CC2 of the second system having a system bandwidth of 20 MHz adjacent to CC1. Shows how to do it. In this case, CC1 and CC2 can communicate using a continuous bandwidth of 40 MHz as a whole.

  FIG. 3 shows carrier aggregation (CA) using a component carrier CC1 of the first system having a system bandwidth of 10 MHz and a component carrier CC2 of the second system having a system bandwidth of 10 MHz separated from CC1. Shows how to do it. In this case, it is possible to perform communication using a bandwidth of 20 MHz as a whole by CC1 and CC2 that are not continuous.

<2. Example of operation>
FIG. 4 shows a flowchart of an operation example executed by the base stations 11, 13, 15 (typically, the macro base station (eNB) 11) of the communication system of FIG. The flow begins at step 41 and proceeds to step 42.

  In step 41, the base station (eNB) determines whether or not it is necessary to notify the addition or deletion of the S cell for the user apparatus (UE) capable of performing CA. The case of notifying the addition or deletion of the S cell will be described later (2.1-2.8). If notification of addition or deletion of S cells is unnecessary, the flow proceeds to step 45 and ends. If notification of S cell addition or deletion is required, the flow proceeds to step 43.

  In step 43, the base station (eNB) generates a control message including at least an addition / deletion message indicating the addition or deletion of the S cell. The control message is, for example, an RRC message.

  In step 44, the base station (eNB) notifies the user apparatus (UE) of a control message including at least an addition / deletion message. Thereby, a user apparatus (UE) sets a parameter, for example according to the instruction | indication to add or delete S cell, and communicates, without performing CA.

  Hereinafter, the trigger for notifying the user apparatus (UE) of the addition / deletion message in 2.1-2.8 will be described. The eight triggers described in 2.1-2.8 are listed by way of example and not limitation, and other triggers may be used. Also, the eight triggers 2.1-2.8 may be used alone, or a combination of two or more triggers out of the eight triggers may be used.

<< 2.1 Change in the number of S cells based on S cell quality >>
The first trigger for adding or deleting an S cell is based on the quality of the S cell. In addition to reporting the quality of the P cell to the base station (eNB), the user equipment (UE) also has the quality of the one or more S cells when one or more S cells are configured. Report to (eNB). Reporting may be done regularly and / or irregularly. The quality report may be performed in the P cell or the S cell. Downlink quality is expressed, for example, by radio resource management measurement report (Radio Resource Measurement Measurement Report) quality (for example, desired signal power vs. interference signal power (SIR)), channel quality indicator (CQI), etc. May be. The uplink quality may be expressed by the reception quality of the reference signal transmitted by the user apparatus (UE). Quality may be referred to as a reception level. Quality may be measured in any suitable amount known in the art. For example, quality or reception level is expressed by received strength (RSSI), desired signal power to interference power ratio (SIR), desired signal power to interference plus noise power ratio (SINR), Eb / No, CQI, CNR, CIR, etc. However, it is not limited to these.

  FIG. 5 shows the time change of the quality of the S cell for explaining the operation of adding or deleting the S cell according to the quality of the S cell. The quality of the S cell increases from time 0 to t1, and exceeds the S cell addition threshold at time t1. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added to the user apparatus (UE). This is because the quality of the S cell is high during this period, so that high-speed communication can be performed (by CA) in the P cell and the S cell.

  In the case of the illustrated example, the quality of the S cell is equal to or higher than the S cell addition threshold from time t1 to t2. After the time t2, the quality of the S cell is lowered, and is lowered to less than the S cell deletion threshold at the time t3. At time t3, the base station (eNB) notifies the user apparatus (UE) that the S cell is deleted for the user apparatus (UE). This is because, during this period, the quality of the S cell is low, so there is little possibility that high-speed communication can be performed in the P cell and the S cell.

  The quality of the S cell rises again after time t3, and exceeds the S cell addition threshold at time t4. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added for the user apparatus (UE). This is because the quality of the S cell is high during this period, so that high-speed communication can be performed (by CA) in the P cell and the S cell. Although not shown in the drawings, the S cell is similarly added if the quality of the S cell exceeds the S cell addition threshold, and the S cell is deleted if it falls below the S cell deletion threshold.

  Thus, carrier aggregation (CA) using not only the P cell but also the S cell is performed only in a state where high-speed communication can be performed in the S cell. When high-speed communication cannot be expected with an S cell, the S cell can be prevented from being used.

  In the example shown in the figure, the S cell addition threshold for determining whether or not to add an S cell and the S cell deletion threshold for determining whether or not to delete an S cell are set to different values. ing. The S cell addition threshold is set higher than the S cell deletion threshold. If the S cell addition threshold and the S cell deletion threshold are the same value, S cells are frequently added and deleted (fluctuation occurs), and the number of control signals for adding and deleting S cells becomes excessive. There is a concern that By setting the S cell addition threshold and the S cell deletion threshold to different values, it becomes necessary to delete the S cell immediately after adding the S cell (or conversely, immediately after deleting the S cell, the S cell Can be prevented).

  From the viewpoint of preventing flapping of addition and deletion of S cells, it is desirable to average the quality of S cells. For example, instead of the instantaneous value of the quality of the S cell, the magnitude relationship between the quality obtained by averaging the quality of the S cell over a certain period and the S cell addition threshold (or the S cell deletion threshold) may be determined. In averaging, a plurality of quality values at discrete points in time may be averaged rather than over a certain period of time.

  In addition, from the viewpoint of preventing flapping of addition and deletion of S cells, measure the period during which S cell deletion is prohibited so that deletion of S cells is prohibited for a certain period after S cells are added The S cell deletion prohibition timer may be started together with the addition of the S cell. While the S cell deletion prohibition timer is active, deletion of S cells is prohibited regardless of the quality of the S cell, and deletion of S cells is not permitted unless the S cell deletion prohibition timer expires. In the figure, “T.O.” indicates that the timer has expired. Conversely, the S cell addition prohibition timer that measures the period during which S cell addition is prohibited is started together with the S cell deletion so that the addition of the S cell is prohibited for a certain period after the S cell is deleted. May be. While the S cell addition prohibition timer is activated, addition of S cells is prohibited regardless of the quality of the S cell, and addition of S cells is not permitted unless the S cell addition prohibition timer expires. The period counted by the S cell deletion prohibition timer and the S cell addition prohibition timer may be set to any appropriate value. However, from the viewpoint of quickly deleting unnecessary S cells, the S cell deletion prohibition timer It should be shorter than the add prohibition timer.

<< 2.2 Change in the number of S cells based on eNB processing load >>
The second opportunity for adding or deleting S cells is based on the processing load of the base station (eNB). The processing load of the base station (eNB) may be expressed from any appropriate viewpoint.

  The processing load of the base station (eNB) may be expressed by, for example, the number of user apparatuses (UEs) located in the P cell and / or S cell. As the number of user apparatuses (UE) increases, the processing load on the base station (eNB) increases.

  The processing load of the base station (eNB) may be expressed by, for example, the number of user devices (UE) for which connections are set among user devices (UE) located in the P cell and / or S cell. Good. As the number of user apparatuses (UE) increases, the processing load on the base station (eNB) increases.

  The processing load of the base station (eNB) is, for example, the number of active user equipment (UE) in the P cell and / or S cell, the number of inactive user equipment (UE), or the intermittent reception state (DRX) You may express by the ratio (ratio with respect to all UEs of a connection state) of user apparatus (UE). In addition, although the processing load of the base station (eNB) is heavier as the number of connected user apparatuses (UE) is larger, the processing load of the base station (eNB) is higher as the value of the ratio of the user apparatus (UE) of DRX is larger Is light.

  The processing load of the base station (eNB) may be expressed by, for example, the number of bearers (number of logical channels) set in the P cell and / or S cell. The processing load of the base station (eNB) may be expressed by the number of bearers (number of logical channels) set in the P cell and / or S cell. The greater the number of bearers, the heavier the processing load on the base station (eNB).

  The processing load of the base station (eNB) may be expressed, for example, by a hardware resource usage rate (for example, a CPU usage rate or a buffer usage rate) in the base station (eNB). The higher the usage rate, the heavier the processing load on the base station (eNB).

  The processing load of the base station (eNB) may be expressed by, for example, the number of user apparatuses (UE) for which individual resources are set in the cell. The larger the number of user devices, the heavier the processing load on the base station (eNB).

  The processing load of the base station (eNB) may be expressed by, for example, the number of user apparatuses (UE) that are performing carrier aggregation (CA). The user equipment (UE) performing CA may be the number of user equipment (UE) to which the S cell is added, or the number of user equipment (UE) to which the added S cell is active. Good. In any case, the processing load on the base station (eNB) increases as the number of user devices increases.

  The processing load of the base station (eNB) may be expressed by, for example, an average transmission / reception rate (average throughput) in the cell. The higher the average transmission / reception rate, the heavier the processing load on the base station (eNB).

  The processing load of the base station (eNB) may be determined for each cell, or may be measured for each processing function unit such as a baseband (BB) resource.

  These processing loads are merely examples, and the processing load of the base station (eNB) may be expressed from another viewpoint.

  FIG. 6 shows a time change of the processing load for explaining the operation of adding or deleting the S cell according to the processing load of the base station (eNB). Although generally the same as FIG. 5, it should be noted that the magnitude relationship between the S cell addition threshold and the S cell deletion threshold is reversed. The quality of the S cell decreases after time 0 and falls below the S cell addition threshold at time t1. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added for the user apparatus (UE). This is because, during this period, the processing load on the base station (eNB) is light, and thus the user apparatus (UE) should perform high-speed communication using the P cell and the S cell.

  In the illustrated example, the quality of the S cell is less than the S cell deletion threshold from time t1 to t3. After time t1, the processing load on the base station (eNB) is light and reaches the S cell deletion threshold at time t3. At time t4, the base station (eNB) notifies the user apparatus (UE) that this S cell will be deleted for the user apparatus (UE). This is because, during this period, the processing load on the base station (eNB) is high, so high-speed communication using S cells should be avoided.

  The processing load of the base station (eNB) decreases again after time t3, and falls below the S cell addition threshold at time t4. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added for the user apparatus (UE). This is because the processing load on the base station (eNB) is light during this period, and the user equipment (UE) should be encouraged to perform high-speed communication using the P cell and S cell. Although not shown in the figure, the S cell is deleted if the processing load of the base station (eNB) exceeds the S cell deletion threshold, and the S cell is added if the processing load falls below the S cell addition threshold.

  Thereby, carrier aggregation (CA) is promoted only when the processing load of the base station (eNB) is light, and when the processing load of the base station (eNB) is heavy, CA is suppressed, for example, the base station ( eNB) congestion can be avoided.

  Similar to the example shown in FIG. 5, in the example shown in FIG. 6, an S cell addition threshold for determining whether or not to add an S cell and an S for determining whether or not to delete an S cell are used. The cell deletion threshold is set to a different value, and flapping can be prevented. However, it differs from the example shown in FIG. 5 in that the S cell addition threshold is set lower than the S cell deletion threshold.

  Similar to the example shown in FIG. 5, in the example shown in FIG. 6, it is desirable to average the processing load of the base station (eNB) from the viewpoint of preventing flapping of addition and deletion of S cells. For example, not the instantaneous value of the processing load of the base station (eNB), but the magnitude relationship between the processing load obtained by averaging the processing load of the base station (eNB) over a certain period and the S cell addition threshold (or S cell deletion threshold) May be determined. During the averaging, a plurality of processing load values at discrete time points may be averaged instead of over a certain period.

  In addition, from the viewpoint of preventing flapping of addition and deletion of S cells, measure the period during which S cell deletion is prohibited so that deletion of S cells is prohibited for a certain period after S cells are added The S cell deletion prohibition timer may be started together with the addition of the S cell. While the S cell deletion prohibition timer is running, deletion of S cells is prohibited regardless of the processing load of the base station (eNB). Not allowed. In the figure, “T.O.” indicates the expiration of the timer. Conversely, the S cell addition prohibition timer that measures the period during which S cell addition is prohibited is started together with the S cell deletion so that the addition of the S cell is prohibited for a certain period after the S cell is deleted. May be. While the S cell addition prohibition timer is running, addition of S cells is prohibited regardless of the processing load of the base station (eNB). Not allowed. The period counted by the S cell deletion prohibition timer and the S cell addition prohibition timer may be set to any appropriate value. However, from the viewpoint of quickly deleting unnecessary S cells, the S cell deletion prohibition timer It should be shorter than the add prohibition timer.

<< 2.3 Change in the number of S cells based on the data retention amount >>
The third opportunity for adding or deleting S cells is based on the data retention amount of the user equipment (UE). The data retention amount of the user apparatus (UE) may be expressed by the amount of data waiting for transmission / reception with the user apparatus (UE).

  The data retention amount of the user apparatus (UE) may be measured for each layer that processes data on the uplink and downlink. Data retention amount of user equipment (UE) is, for example, retention amount of service data unit (SDU) in downlink PDCP layer, retention amount of SDU in downlink RLC layer, protocol data unit in downlink RLC layer ( PDU), and a retention amount of HARQ transmission data in the MAC layer. Further, this data retention amount may be normalized by the average throughput for each user and each bearer.

  Data retention amount of user equipment (UE) is, for example, SDU retention amount in uplink PDCP layer, SDU retention amount in uplink RLC layer, protocol data unit (PDU) retention amount in uplink RLC layer It may be expressed by.

  By the way, bearers for control signals (SRB) and user data bearers (DRB) exist in bearers, and when these bearers have a high transmission / reception rate (throughput), it is estimated that there is a large amount of data retention. The Therefore, the data retention amount of the user apparatus (UE) may be expressed by a transmission / reception rate (throughput) for each bearer, for example. Or the data retention amount of user apparatus (UE) may be expressed by the transmission / reception rate (throughput) of the bearer of DRB, for example. Alternatively, the data retention amount of the user apparatus (UE) may be expressed by the number of bearers (the number of logical channels) exceeding (or falling below) a predetermined transmission / reception rate.

  These data retention measurement method processing loads are merely examples, and the processing load of the base station (eNB) may be expressed from another viewpoint.

  FIG. 7 shows a time change of the data retention amount of the user apparatus (UE) for explaining an operation of adding or deleting an S cell according to the data retention amount of the user apparatus (UE). The data retention amount increases from time 0 to t1, and exceeds the S cell addition threshold at time t1. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added for the user apparatus (UE). This is because, during this period, since the data retention amount of the user device is large, high-speed communication should be performed using the P cell and S cell to reduce the data retention amount.

  In the illustrated example, the data retention amount is equal to or greater than the S cell addition threshold from time t1 to t2. After time t2, the data retention amount decreases and decreases to less than the S cell deletion threshold at time t3. At time t3, the base station (eNB) notifies the user apparatus (UE) that this S cell is deleted for the user apparatus (UE). This is because, during this period, the data retention amount of the user apparatus is small, so that high-speed communication using the P cell and S cell is unnecessary.

  The data retention amount of the user device rises again after time t3 and exceeds the S cell addition threshold at time t4. In response, the base station (eNB) notifies the user apparatus (UE) that this S cell is added for the user apparatus (UE). In this case, since the data retention amount of the user device is large, high-speed communication should be performed using the P cell and the S cell to reduce the data retention amount. Thereafter, although not shown in the figure, similarly, if the data retention amount exceeds the S cell addition threshold, an S cell is added, and if it falls below the S cell deletion threshold, the S cell is deleted.

  Thereby, not only the P cell but also the S cell is used only when the data retention amount of the user apparatus is large. When the data retention amount of the user device is small, it is not meaningful to perform CA, so if an S cell is added, it is deleted.

  In the example shown in the figure, the S cell addition threshold for determining whether or not to add an S cell and the S cell deletion threshold for determining whether or not to delete an S cell are set to different values. ing. The S cell addition threshold is set higher than the S cell deletion threshold to prevent flapping.

  From the viewpoint of preventing flapping of addition and deletion of S cells, it is desirable to average the data retention amount of user devices. For example, instead of the instantaneous value of the user device data retention amount, the magnitude relationship between the data retention amount obtained by averaging the user device data retention amount over a certain period and the S cell addition threshold (or S cell deletion threshold) is determined. May be. In averaging, a plurality of quality values at discrete points in time may be averaged rather than over a certain period of time.

  Furthermore, from the viewpoint of preventing flapping of addition and deletion of S cells, the period during which S cell deletion is prohibited is measured so that deletion of S cells is prohibited for a certain period after the addition of S cells. The S cell deletion prohibition timer may be started together with the addition of the S cell. While the S cell deletion prohibition timer is running, deletion of S cells is prohibited regardless of the amount of data stored in the user equipment, and deletion of S cells is not permitted until after the expiration of the S cell deletion prohibition timer. . In the figure, “T.O.” indicates that the timer has expired. Conversely, the S cell addition prohibition timer that measures the period during which S cell addition is prohibited is started together with the S cell deletion so that the addition of the S cell is prohibited for a certain period after the S cell is deleted. May be. While the S cell addition prohibition timer is running, addition of S cells is prohibited regardless of the amount of data stored in the user equipment, and addition of S cells is not permitted until after the expiration of the S cell addition prohibition timer. . The period counted by the S cell deletion prohibition timer and the S cell addition prohibition timer may be set to any appropriate value. However, from the viewpoint of quickly deleting unnecessary S cells, the S cell deletion prohibition timer It should be shorter than the add prohibition timer.

  The determination method (2.1-2.3) for comparing the measurement value and the threshold value described with reference to FIGS. 5, 6, and 7 may be used alone or in combination. FIG. 8 shows an operation example in which all the determination methods (2.1-2.3) described with reference to FIGS. 5, 6, and 7 are used in parallel. In the flowchart shown in FIG. 4, the illustrated operation example is Y in Step 42 (that is, when it is necessary to notify the user apparatus (UE) of addition or deletion of S cells), Steps 43-45 Used as.

  The flow proceeds from step 801 (if Y in step 42) to steps 802, 809, 811.

  In step 802, it is determined whether the quality of the S cell is equal to or higher than the S cell addition threshold. If the quality of the S cell is equal to or higher than the S cell addition threshold, the flow proceeds to step 803. In Step 803, the base station (eNB) generates a control message including an addition / deletion message indicating that an S cell is added. In step 804, the base station (eNB) notifies the user apparatus of a control message. In response to this, the user apparatus (UE) adds an S cell. Thereafter, the flow proceeds to step 805 and ends.

  On the other hand, if the quality of the S cell is not greater than or equal to the S cell addition threshold in step 802, the flow proceeds to step 806. In step 806, it is determined whether the quality of the S cell is less than the S cell deletion threshold. If the quality of the S cell is less than the S cell deletion threshold, the flow proceeds to step 807. In step 807, the base station (eNB) generates a control message including an additional deletion message indicating that the S cell is deleted. In step 808, the base station (eNB) notifies the user apparatus of a control message. In response to this, the user apparatus (UE) deletes the S cell. Thereafter, the flow proceeds to step 805 and ends. If it is determined in step 806 that the quality of the S cell is not less than the S cell deletion threshold, the flow proceeds to step 805 and ends.

  In step 809 following step 801, it is determined whether the processing load of the base station is less than the S cell addition threshold. If the processing load of the base station is less than the S cell addition threshold, the processes already described in steps 803, 804, and 805 are performed to add the S cell. On the other hand, if the processing load of the base station is not less than the S cell addition threshold in step 809, the flow proceeds to step 810. In step 810, it is determined whether the processing load of the base station is equal to or greater than the S cell deletion threshold. If the processing load of the base station is equal to or greater than the S cell deletion threshold, the processes already described in steps 807, 808, and 805 are performed to delete the S cell. Also in step 810, if the processing load of the base station is not equal to or greater than the S cell deletion threshold, the flow proceeds to step 805 and ends.

  Further, following step 801, in step 811, it is determined whether the data retention amount of the user apparatus is equal to or greater than the S cell addition threshold. If the data retention amount of the user device is equal to or greater than the S cell addition threshold, the processes already described in steps 803, 804, and 805 are performed to add the S cell. On the other hand, if it is determined in step 811 that the data retention amount of the user apparatus is not equal to or greater than the S cell addition threshold, the flow proceeds to step 812. In step 812, it is determined whether the data retention amount of the user device is less than the S cell deletion threshold. If the data retention amount of the user device is less than the S cell deletion threshold, the processes already described in steps 807, 808, and 805 are performed to delete the S cell. Also in step 812, if the data retention amount of the user device is not less than the S cell deletion threshold, the flow proceeds to step 805 and ends.

  FIG. 8 shows an example in which all of the determination methods (2.1-2.3) described with reference to FIGS. 5, 6, and 7 are used in parallel, but any of the three determination methods (2.1-2.3) The two may be used in combination.

<< 2.4 Changing the number of S cells with other messages >>
In the example described with reference to FIG. 5, FIG. 6, FIG. 7 and FIG. 8, whether or not to add an S cell or whether or not to delete an S cell depending on the magnitude relationship between a predetermined measurement target and a threshold value. It was judged. The disclosed invention is not limited to such an example compared with the threshold value, and the number of S cells may be changed from another viewpoint. The fourth opportunity for adding or deleting an S cell is a procedure in which a base station (eNB) notifies a user apparatus (UE) of a non-addition deletion message other than an addition deletion message indicating addition or deletion of an S cell. based on.

  As will be described later, the non-addition / deletion message includes, for example, (1) a message prompting the user device (UE) to re-establish the RRC connection, and (2) re-establishing the RRC connection in the user device (UE) reconnection. A message prompting the setting, and (3) a message of a handover command when the user apparatus (UE) performs a handover.

(2.4.1)
FIG. 9 shows a procedure at the time of initial access by the user apparatus (UE).

  In step 91, the user apparatus (UE) notifies the base station (eNB) of an RRC connection request message requesting establishment of a connection.

  In step 92, in response to the RRC connection request message, the base station (eNB) sends an RRC connection setup message to the user equipment in order to notify a parameter value or the like necessary for establishing a connection. Notify (UE).

  In step 93, the user apparatus (UE) notifies the base station (eNB) of an RRC connection setup complete message indicating that the establishment of the connection is completed.

  In step 94, an authentication procedure, a NAS (Non Access Stratum) processing procedure, and a security procedure are executed between the user apparatus (UE) and the base station (eNB). At this stage, the user apparatus (UE) is set to be able to communicate using some specific one component carrier (CC). At this stage, carrier aggregation (CA) cannot be performed yet.

  In step 95, a base station (eNB) notifies the user apparatus (UE) of the message of RRC connection reconfiguration (RRC connection reconfiguration) for resetting the setting of a connection. In the case of the embodiment, this message includes a notification that an S cell should be added (addition / deletion message indicating the addition of an S cell).

  In step 96, the user apparatus (UE) notifies the base station (eNB) of an RRC connection reconfiguration complete message indicating that the connection reconfiguration has been completed. Thereby, user apparatus (UE) can perform communication by CA by activating S cell as needed.

(2.4.2)
FIG. 10 shows a procedure when the user apparatus (UE) performs reconnection.

  In step 101, the user apparatus (UE) notifies the base station (eNB) of an RRC connection re-establishment request message requesting reconnection.

  In step 102, in response to the RRC connection reconnection request message, the base station (eNB) sends an RRC connection re-establishment message to notify the parameter values necessary for reconnection. Notify the user equipment (UE).

  In step 103, the user apparatus (UE) notifies the base station (eNB) of an RRC connection re-establishment complete message indicating that reconnection is complete. At this stage, the user apparatus (UE) is set to be able to communicate using some specific one component carrier (CC). At this stage, carrier aggregation (CA) cannot be performed yet.

  In step 104, a base station (eNB) notifies the user apparatus (UE) of the message of the RRC connection reconfiguration (RRC connection reconfiguration) for resetting the setting of a connection. In the case of the embodiment, this message includes a notification that an S cell should be added (addition / deletion message indicating the addition of an S cell).

  In Step 105, the user apparatus (UE) notifies the base station (eNB) of an RRC connection reconfiguration complete message indicating that the connection reconfiguration has been completed. Thereby, user apparatus (UE) can perform communication by CA by activating S cell as needed.

(2.4.3)
FIG. 11 shows a procedure when the user apparatus (UE) performs a handover.

  In step 111, the user apparatus (UE) transmits a measurement report (measurement report) to the base station (eNB) to notify that handover is necessary.

  In step 112, the base station (eNB) notifies the user apparatus (UE) of a handover command (HO command) in order to instruct that handover should be performed. In the case of the embodiment, this message includes a notification that an S cell should be added or deleted (addition / deletion message indicating the addition or deletion of an S cell).

  In step 113, the user apparatus (UE) notifies the base station (eNB) of an RRC connection reconfiguration complete message indicating that the connection reconfiguration has been completed.

  As shown in Step 95 of FIG. 9, Step 104 of FIG. 10, Step 112 of FIG. 11, after or during the procedure of notifying the user equipment (UE) of instruction information other than addition or deletion of S cells, S By notifying the user apparatus (UE) of instruction information for adding or deleting a cell, it is possible to improve the efficiency of the procedure.

<< 2.5 Changing the number of S cells with DRX state transition >>
The fifth opportunity for adding or deleting an S cell is based on a procedure in which the user apparatus (UE) transitions from a discontinuous reception state (DRX) to a non-discontinuous reception state (non-DRX). When there is no data to be transmitted / received and a certain period of time elapses, the user apparatus (UE) moves to an intermittent reception state (DRX) in which a control signal is intermittently received, and saves battery consumption.

  FIG. 12 shows a procedure when the user apparatus (UE) moves from the DRX state to the non-DRX state. First, when the user apparatus (UE) is in the DRX state, it is assumed that data to be transmitted to the user apparatus (UE) is generated. In this case, in step 121, the base station (eNB) notifies the user apparatus (UE) of a message of a synchronization request (Sync Request) for requesting synchronization. Thereby, in step 122, a random access (RA) procedure is performed, and user apparatus (UE) changes from a DRX state to a non-DRX state. At this stage, the user apparatus (UE) is set to be able to communicate using some specific one component carrier (CC). At this stage, carrier aggregation (CA) cannot be performed yet.

  When uplink data is generated when the user apparatus (UE) is in the DRX state, a random access (RA) procedure is started from the user apparatus (UE) side.

  In step 123, a base station (eNB) notifies the user apparatus (UE) of the message of the RRC connection reconfiguration (RRC connection reconfiguration) for resetting the setting of a connection. In the case of the embodiment, this message includes a notification of adding an S cell (addition deletion message indicating the addition of an S cell).

  In step 124, the user apparatus (UE) notifies the base station (eNB) of an RRC connection reconfiguration complete message indicating that the connection reconfiguration has been completed. Thereby, user apparatus (UE) can perform communication by CA by activating S cell as needed.

  In the example shown in FIG. 12, the S cell is activated in response to the occurrence of downlink data, but the disclosed invention is not limited to such a case, and the base station (eNB) is separate from the occurrence of downlink data. ) May add or delete S cells. However, when adding or deleting an S cell, the user apparatus (UE) needs to be in a non-DRX state. Therefore, the user apparatus (UE) that has been in the DRX state transitions from the DRX state to the non-DRX state after the RA procedure as in step 122 in FIG. And after S cell is added or deleted, user apparatus (UE) may change to the original DRX state again.

<< 2.6 Periodic change of the number of S cells >>
The sixth opportunity for adding or deleting S cells is based on periodic timing. FIG. 13 shows how S cells are added and deleted based on periodic timing. In this case, an additional timer for measuring the periodic timing for adding the S cell and a deletion timer for measuring the periodic timing for deleting the S cell are used. The period of the additional timer is longer than the period of the deletion timer. In this case, as shown in the figure, every time the addition timer expires, an addition deletion message for adding an S cell is notified from the base station (eNB) to the user apparatus (UE). Along with the notification of the addition / deletion message, an addition timer and a deletion timer are started. Furthermore, every time the deletion timer shorter than the addition timer expires, an additional deletion message for deleting the S cell is notified from the base station (eNB) to the user apparatus (UE). Therefore, after the S cell addition timer and the S cell deletion timer are started, the S cell is added until the S cell deletion timer expires. Then, after the S cell deletion timer expires, the S cell is deleted until the S cell addition timer and the S cell deletion timer are started again.

  As described above, by periodically adding and deleting S cells based on the addition timer and the deletion timer, the time during which the user apparatus (UE) can communicate with the CA can be distributed on the time axis.

<< 2.7 Change in the number of S cells based on a request from the UE >>
A seventh opportunity for adding or deleting an S cell is based on a request from a user apparatus (UE). FIG. 14 shows an operation example when an S cell is added or deleted in response to a request from the user apparatus (UE).

  As shown in step 141, the user equipment (UE) in which the S cell is set sends a battery saving request message that the user equipment (UE) desires to perform battery saving (e.g., transition to the DRX state) to the base station (eNB). Send to.

  In step 142, a base station (eNB) notifies the user apparatus (UE) of the message of RRC connection reconfiguration (RRC connection reconfiguration) for resetting the setting of a connection. In the case of the embodiment, this message includes a notification that the S cell should be deleted (additional deletion message indicating the deletion of the S cell).

  In step 143, user apparatus (UE) notifies the message of the RRC connection reconfiguration complete (RRC connection re-configuration complete) which shows that the reset of the connection was completed to a base station (eNB). Thereby, after that, user apparatus (UE) deletes S cell.

  In the illustrated example, the S cell is deleted in response to a battery saving request from the user apparatus (UE), but the embodiment is not limited to this example. For example, instead of step 141, the user apparatus (UE) may transmit a message requesting high-speed communication to the base station (eNB), and in response thereto, an S cell may be added in step S142. Further, for example, instead of Step 141, the user equipment (UE) notifies the base station (eNB) of the state of the traffic buffer (which may indicate the data retention amount), and in response thereto, the S cell is It may be added or deleted. The battery saving request, the high-speed communication request, and the notification of the buffer state are merely examples, and the S cell may be added or deleted in response to some request from the user apparatus (UE).

<< 2.8 Change of number of S cells based on bearer type >>
The eighth opportunity for adding or deleting an S cell is based on the bearer type set for the user apparatus (UE). When the user apparatus (UE) performs communication, a bearer is set for each data type. For example, when performing Best Effort (BE) type data communication, a large amount of data is expected to be transmitted and received, so it is conceivable to add S cells. Conversely, when audio data is transmitted / received, it is expected that the amount of transmitted / received data will not be large, so it is conceivable not to add an S cell (or delete a set S cell).

  FIG. 15 shows an example of adding an S cell based on the bearer type. In step 151, it is assumed that the base station (eNB) has decided to add a bearer for performing BE type data communication.

  In Step 152, the base station (eNB) notifies the user apparatus (UE) of a message of RRC connection reconfiguration (RRC connection reconfiguration) for resetting the connection settings. In the case of the embodiment, this message includes a notification that an S cell should be added (addition / deletion message indicating addition of an S cell).

  In step 153, the user apparatus (UE) notifies the base station (eNB) of an RRC connection reconfiguration complete message indicating that the connection reconfiguration has been completed. Thereby, user apparatus (UE) can perform communication by CA by activating S cell as needed.

  If an S cell is set in the user equipment (UE), if it is determined in step 151 to add a bearer that transmits and receives voice data instead of BE type data communication, in step 152, the S cell Is notified to the user apparatus (UE).

  The eight triggers described in 2.1-2.8 are only examples, and other triggers may be used. Further, S cells may be added and deleted one by one, or two or more S cells may be added and deleted at a time. Furthermore, the eight triggers in 2.1-2.8 may be used alone, or a combination of any two or more of the eight triggers may be used. In particular, the addition and deletion of one or more S cells may be determined based on the quality of the S cell in 2.1, the amount of data retention in 2.3, and the bearer type in 2.8.

<3. Base station>
FIG. 16 shows a functional block diagram of the base station. FIG. 16 shows various functional units or processing units provided in the base station that are particularly relevant to the embodiment. The base station shown in FIG. 16 is the base station 11, 13, and / or 15 shown in FIG. The base station includes at least a DL signal transmission unit 161, a UL signal reception unit 162, a threshold determination unit 163, an S cell management unit 164, and a control message generation unit 165.

  The DL signal transmission unit 161 performs processing for transmitting a signal to the user apparatus.

  The UL signal receiving unit 162 performs processing for receiving a signal from the user device.

  The threshold determination unit 163 compares and / or determines the measurement value of the predetermined measurement target and the threshold, and notifies the S cell management unit 164 of the comparison result and / or the determination result. The predetermined measurement objects are the quality of the S cell, the processing load of the base station (eNB), the data retention amount of the user apparatus (UE), and the like. The threshold values are an S cell addition threshold value and an S cell deletion threshold value.

  The S cell management unit 164 performs control or management related to carrier aggregation (CA) by a plurality of cells managed by the base station for each user apparatus (UE). For example, the S cell control unit 164 determines whether or not the user apparatus is performing CA, and if so, which cell is the P cell, which cell is the S cell, and whether or not to add the S cell. Manage whether to delete the S cell, whether to activate the added S cell, whether to deactivate the activated S cell, etc. .

  The control message generation unit 165 generates a control message to be notified to the user apparatus (UE). The control message in the embodiment may include an arbitrary message notified to the user apparatus (UE) by an RRC message or the like. For example, the control message includes an add / delete message indicating that an S cell is to be added. Alternatively, the control message includes an additional deletion message indicating that the S cell is to be deleted.

  As mentioned above, although embodiment which performs CA with an appropriate opportunity has been described, the disclosed invention is not limited to such a form, and those skilled in the art will recognize various modifications, modifications, alternatives, substitutions, etc. You will understand. Although specific numerical examples have been described in order to facilitate understanding of the invention, these numerical values are merely examples and any appropriate values may be used unless otherwise specified. The classification of items in the above description is not essential to the present invention, and the items described in two or more items may be used in combination as necessary, or the items described in one item may be used in different items. It may apply to the matters described in (as long as there is no conflict). The boundaries between functional units or processing units in the functional block diagram do not necessarily correspond to physical component boundaries. The operations of a plurality of functional units may be physically performed by one component, or the operations of one functional unit may be physically performed by a plurality of components. For convenience of explanation, the base station has been described using a functional block diagram, but such a device may be implemented in hardware, software, or a combination thereof. Software operating in accordance with the present invention includes random access memory (RAM), flash memory, read only memory (ROM), EPROM, EEPROM, registers, hard disk (HDD), removable disk, CD-ROM, database, server and other suitable It may be stored in any storage medium. The present invention is not limited to the above embodiments, and various modifications, modifications, alternatives, substitutions, and the like are included in the present invention without departing from the spirit of the present invention.

161 DL signal transmitter
162 UL signal receiver
163 Threshold judgment unit
164 S Cell Management Department
165 Control message generator

Claims (7)

A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
And a generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is added or deleted, and the management unit adds an SCC according to a comparison result between a measurement value and a threshold value for a predetermined measurement target. If it is determined to delete, the communication unit notifies the user apparatus of the control message. The measurement value for the predetermined measurement object is:
Quality of wireless communication with the user equipment,
2. The base station according to claim 1, which represents a processing load of the base station or a retention amount of data transmitted or received by the user apparatus. A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
A generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is to be added or deleted, and when it is necessary to notify the user device of a non-addition / deletion message different from the addition / deletion message Further, when or after notifying the user device of the non-addition / deletion message, the generation unit generates a control message including the addition / deletion message, and the communication unit notifies the user device of the control message. base station. The non-add / delete message is:
A message prompting resetting of the RRC connection in the initial access of the user equipment,
A message prompting re-setting of the RRC connection in the re-connection of the user equipment,
4. The base station according to claim 3, wherein the base station is a handover command message when the user apparatus performs handover, or a message prompting re-establishment of an RRC connection when the user apparatus transitions from the intermittent reception state to the non-intermittent reception state. Bureau. A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
And a generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is to be added or deleted, and the generation unit includes a control message including an addition / deletion message indicating that an SCC is added in a first cycle. And the communication unit notifies the user device of the control message,
The base station, wherein the generation unit generates a control message including an addition / deletion message indicating that the SCC is deleted in a second period, and the communication unit notifies the user apparatus of the control message. A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
A generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is added or deleted, and the generation unit includes a control including the addition / deletion message in response to a request signal from the user device. A base station that generates a message and the communication unit notifies the user apparatus of the control message. A communication unit for communicating with the user device;
A management unit for managing a primary component carrier (PCC) and a secondary component carrier (SCC) for each user device;
A generation unit that generates a control message including at least an addition / deletion message indicating that an SCC is to be added or deleted, and the generation unit includes a control message including the addition / deletion message along with the addition / deletion of a predetermined bearer. And the communication unit notifies the user apparatus of the control message.

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