JP5802107B2 - Base station and communication control method - Google Patents

Description

  The present invention relates to a base station and a communication control method for transmitting a PDCP status report for reporting the reception status of uplink data to the mobile station after the start of handover or reconnection of the mobile station.

  In Long Term Evolution (LTE), which is standardized in the 3rd Generation Partnership Project (3GPP), in order to reduce the battery consumption of the mobile station (UE), the base station DRX (Discontinuous Reception) control for intermittently receiving a downlink control channel (PDCCH) transmitted from (eNB) only for a specific period is employed (for example, see Non-Patent Document 1).

As one of the triggers for the mobile station to transition to the DRX state, when the value of the UE Inactive Timer that measures the time when there is no user data to be transmitted to the mobile station for each mobile station exceeds the threshold (Th _drxcommand ), A DRX command MAC Control Element (hereinafter referred to as DRX command MAC CE) transmitted by the base station is defined. When receiving the DRX command MAC CE, the mobile station transits to the DRX state.

  DRX command MAC CE is used to force the mobile station to transition to the DRX state when it is difficult for the mobile station to transition to the DRX state due to reception of a control channel (DCCH) during handover or reconnection of the mobile station. It can be suitably used.

  In LTE, after the mobile station handover or reconnection is completed, the mobile station uses the uplink data (UL data) already received by the base station to perform handover or reconnection destination base station (cell). PDCP status report that reports the reception status of UL data on the base station side to the mobile station is defined.

3GPP TS 36.300 V10.3.0, 3rd Generation Partnership Project; Technical Specification Group Radio Access Network; Evolved Universal Terrestrial Radio Access (E-UTRA) and Evolved Universal Terrestrial Radio Access Network (E-UTRAN); Overall description; Stage 2 (Release 10 ), March 2011

  However, the conventional mobile station control method described above has the following problems. That is, after the handover or reconnection of the mobile station, when the handover destination or reconnection destination base station transmits and receives the PDCP status report, the mobile station that has transitioned to the DRX state by receiving the DRX command MAC CE -Returns to DRX state. For this reason, there has been a problem that battery consumption of the mobile station cannot be effectively suppressed.

  Therefore, the present invention has been made in view of such a situation, and at the time of handover or reconnection, the radio resources accompanying the return from the DRX state of the mobile station to the non-DRX state by transmitting and receiving the PDCP status report An object of the present invention is to provide a base station and a communication control method capable of preventing waste of power and battery consumption of a mobile station.

A first feature of the present invention is that a base station (for example, a PDCP status report for reporting the reception status of uplink data is transmitted to the mobile station after the start of handover or reconnection of the mobile station (mobile station 200) (for example, A DRX control unit (DRX control unit 109) that transmits a DRX command MAC CE for controlling the mobile station to the mobile station in a DRX state in which the control channel is intermittently received, and the mobile station 100A) A timer control unit (timer control unit 107) that controls a pending timer (UIT Pending Timer) that measures an elapsed time from the start of station handover or reconnection, and the DRX control unit is measured by the pending timer If the elapsed time exceeds the pending timer threshold longer than the time required for transmission of the PDCP status report and confirmation of delivery of the PDCP status report, and the data to be transmitted to the mobile station If it is the time measured by the inactive timer for measuring the absence time exceeds inactive timer threshold _(Th drxcommand), to increase the transmission of the DRX COMMAND MAC CE to the mobile station.

  A second feature of the present invention is a communication control method by a communication device that transmits a PDCP status report that reports the reception status of uplink data to the mobile station after the start of handover or reconnection of the mobile station. A step of transmitting a DRX command MAC CE for controlling the mobile station to a DRX state for intermittently receiving a control channel to the mobile station, and measuring an elapsed time from the start of handover or reconnection of the mobile station A step of controlling a pending timer, and in the step of transmitting the DRX command MAC CE, an elapsed time measured by the pending timer is greater than a time required for transmission of the PDCP status report and confirmation of delivery of the PDCP status report. Inactivities that measure the time when the long pending timer threshold is exceeded and there is no data to be transmitted to the mobile station If the timer time measured by the (UE Inactive Timer) is greater than the inactive timer threshold, to increase the transmission of the DRX COMMAND MAC CE to the mobile station.

  According to the features of the present invention, at the time of handover or reconnection, radio resources are wasted due to the mobile station returning from the DRX state to the non-DRX state by transmitting and receiving the PDCP status report, and the mobile station battery consumption is reduced. A base station and a communication control method that can be prevented can be provided.

1 is an overall schematic configuration diagram of a wireless communication system according to an embodiment of the present invention. FIG. 3 is a functional block configuration diagram of a base station 100A according to the embodiment of the present invention. FIG. 4 is a diagram showing a communication sequence at the time of handover between the base station 100A and the mobile station 200 according to the embodiment of the present invention. FIG. 7 is a diagram showing a DRX command MAC CE transmission operation flow in the base station 100A in accordance with the handover decision of the mobile station 200 according to the embodiment of the present invention.

  Next, an embodiment of the present invention will be described. In the following description of the drawings, the same or similar parts are denoted by the same or similar reference numerals. However, it should be noted that the drawings are schematic and ratios of dimensions and the like are different from actual ones.

  Accordingly, specific dimensions and the like should be determined in consideration of the following description. Moreover, it is a matter of course that portions having different dimensional relationships and ratios are included between the drawings.

(1) Overall Schematic Configuration of Radio Communication System FIG. 1 is an overall schematic configuration diagram of a radio communication system according to the present embodiment. As shown in FIG. 1, the radio communication system according to the present embodiment employs a Long Term Evolution (LTE) scheme, and includes a core network 50, base stations 100A, 100B (eNB), and a mobile station 200 (UE). Including.

  The base station 100A is connected to the core network 50. Base station 100A (100B) forms cell C1 (cell C2) and performs radio communication with mobile station 200 according to the LTE scheme. In particular, in the present embodiment, base station 100A (or base station 100B, hereinafter the same) reports the reception status of uplink data (hereinafter, UL data) after the start of handover or reconnection of mobile station 200. A PDCP status report is transmitted to the mobile station 200.

  The mobile station 200 determines the content of UL data to be transmitted to the base station 100A based on the PDCP status report received from the base station 100A.

(2) Functional Block Configuration of Radio Communication System Next, a functional block configuration of the radio communication system according to the present embodiment will be described. Specifically, the functional block configuration of base station 100A will be described. FIG. 2 is a functional block configuration diagram of the base station 100A.

  As shown in FIG. 2, the base station 100A includes a radio communication unit 101, a data transmission / reception unit 103, a PDCP control unit 105, a timer control unit 107, and a DRX control unit 109. Note that the base station 100A realizes these functional blocks by a platform unit (PF) and an application unit (AP).

  The radio communication unit 101 performs radio communication with the mobile station 200 according to the LTE scheme.

  The data transmission / reception unit 103 transmits / receives control data (C-plane data) and user data (U-Plane data) for the mobile station 200 via the wireless communication unit 101. In particular, in the present embodiment, the data transmission / reception unit 103 transmits a PDCP status report, which is a type of control data transmitted from the PDCP control unit 105, to the mobile station 200 via the downlink control physical channel (PDCCH).

  The PDCP control unit 105 transmits a PDCP status report for reporting the reception status of UL data to the mobile station 200. In addition, a PDCP status report that reports the reception status of downlink data (hereinafter referred to as DL data) is received from the mobile station 200.

  Specifically, after starting the handover or reconnection of the mobile station, the PDCP control unit 105 receives the UL data that the mobile station 200 has already received by the base station that forms the handover or reconnection source cell. (Actually, the mobile station 200 transmits UL data for which delivery confirmation has not been received from the base station) to prevent the mobile station 200 from transmitting again to the base station forming the handover or reconnection destination cell. The reception status of UL data at the station side is reported to the mobile station 200 by PDCP status report.

  In addition, the PDCP control unit 105 receives the DL data reception status at the mobile station 200 transmitted by the mobile station 200 after the handover or reconnection is started and before the handover or reconnection procedure of the mobile station 200 is performed. PDCP status report indicating is received. The received PDCP status report is used for downlink scheduling in the base station that forms the handover or reconnection destination cell of the mobile station 200.

  The timer control unit 107 controls various timers used in the base station 100A. Specifically, the timer control unit 107 has a UIT Pending Timer and a UE Inactive Timer.

  UIT Pending Timer measures the elapsed time from the start of handover or reconnection of the mobile station 200. In the present embodiment, the UIT Pending Timer constitutes a pending timer. Further, the UE Inactive Timer measures the time when there is no user data to be transmitted to the mobile station 200. In the present embodiment, the UE Inactive Timer constitutes an inactivity timer.

  The DRX control unit 109 controls the mobile station 200 to either a DRX (Discontinuous Reception) state or a non-DRX state. The mobile station 200 in the DRX state receives the control channel, specifically, the PDCCH intermittently only for a specific period. On the other hand, the mobile station 200 in the non-DRX state continuously receives the PDCCH.

  Specifically, the DRX control unit 109 controls the mobile station 200 to the DRX state by transmitting a DRX command MAC CE to the mobile station 200. In a normal case, when there is no user data to be transmitted by the mobile station 200, the PDCCH is not transmitted from the base station 100A, so the DRX Inactivity Timer of the mobile station 200 reaches the threshold (that is, the DRX Inactivity Timer expires). The mobile station 200 transitions to the DRX state.

When the elapsed time measured by the UIT Pending Timer exceeds the pending timer threshold and the time measured by the UE Inactive Timer exceeds the inactive timer threshold (Th _drxcommand ), the DRX control unit 109 The MAC CE is transmitted to the mobile station 200. The pending timer threshold (TH _{uit, HO} or TH _{uit, re-est} ) is set longer than the time required for transmitting the PDCP status report and confirming the delivery of the PDCP status report (ACK).

The DRX control unit 109 measures with the UE Inactive Timer until the transmission of the PDCP status report and the delivery confirmation of the PDCP status report are completed, that is, until the UIT Pending Timer exceeds TH _{uit, HO} or TH _{uit, re-est. Stops} determining whether the elapsed time exceeds the _inactivity timer threshold (Th _drxcommand ).

On the other hand, if the elapsed time measured by the UIT Pending Timer exceeds TH _{uit, HO} or TH _{uit, re-est} , the DRX control unit 109 determines whether the elapsed time measured by the UE Inactive Timer exceeds the Th _drxcommand . Resumes determination of no. Note that the values of TH _{uit, HO} or TH _{uit, re-est} and Th _drxcommand may be the same.

Also, the DRX control unit 109, when the UE Inactive Timer is reset when the elapsed time measured by the UIT Pending Timer exceeds TH _{uit, HO} or TH _{uit, re-estt} , the DRX command MAC Stop sending CE.

  Further, after transmitting the DRX command MAC CE to the mobile station 200, the DRX control unit 109 receives a delivery confirmation (ACK) for the MAC PDU including the DRX command MAC CE, or retransmits by hybrid ARQ (HARQ) Determines that the mobile station 200 has transitioned to the DRX state.

(3) Operation of Radio Communication System Next, the operation of the radio communication system according to the present embodiment will be described. Specifically, the control operation to the DRX state of the mobile station 200 (UE) by the base station 100A (eNB) will be described.

(3.1) Communication Sequence FIG. 3 shows a communication sequence at the time of handover between the base station 100A and the mobile station 200. Here, description will be made assuming that mobile station 200 has been handed over to base station 100A.

  As shown in FIG. 3, the base station 100A executes a handover RBSID setting process (macro) that is executed in conjunction with the handover of the mobile station 200 (S10). Here, the state of the UE Inactive Timer is inherited between the PF and the AP.

  When the handover of the mobile station 200 is started, the base station 100A starts the UE Inactive Timer and the UIT Pending Timer, and starts measurement by both timers (S20).

  The mobile station 200 executes a Random Access (RA) procedure with the base station 100A, and establishes a connection with the base station 100A (S30 to S40).

  Next, the base station 100A and the mobile station 200 transmit and receive PDCP status reports in the uplink (UL) and downlink (DL) (S50).

After the transmission of the PDCP status report and the delivery confirmation of the PDCP status report is completed, the measurement time of the UIT Pending Timer reaches TH _{uit, HO} , the UIT Pending Timer expires, and the measurement is stopped (S60). If the measurement time of the UE Inactive Timer exceeds the Th _drxcommand after the UIT Pending Timer expires, the base station 100A transmits a DRX command MAC CE to the mobile station 200 (S70).

  The mobile station 200 that has received the DRX command MAC CE transitions to the DRX state (S80).

(3.2) Operation Flow of Base Station 100A FIG. 4 shows a transmission operation flow of the DRX command MAC CE in the base station 100A when the handover of the mobile station 200 is determined.

  As shown in FIG. 4, the base station 100A executes a procedure (RA procedure or the like) necessary for handover with the mobile station 200 (S110). As described above, when the handover of the mobile station 200 is started, the UE Inactive Timer and the UIT Pending Timer are started.

Next, the base station 100A determines whether or not the UIT Pending Timer has expired (S120). When the UIT Pending Timer has already expired, the base station 100A determines whether or not the measurement time of the UE Inactive Timer exceeds the Th _drxcommand (S130).

When the measurement time of the UE Inactive Timer exceeds the Th _drxcommand , the base station 100A transmits a DRX command MAC CE to the mobile station 200 (S140). When the base station 100A receives an acknowledgment (ACK) for a MAC PDU including the DRX command MAC CE, or when the HARQ maximum number of retransmissions in the MAC layer is exceeded, the base station 100A considers that the mobile station 200 has transitioned to the DRX state.

  The above-described operation example was a case of handover between base stations of the mobile station 200, but also in the case of a handover within the base station 100A of the mobile station 200 or a reconnection to the base station 100A, The base station 100A may perform substantially the same processing. In this case, the state of the UE Inactive Timer is taken over in the base station 100A.

(4) Action / Effect According to the base station 100A, the DRX command MAC CE moves when the elapsed time measured by the UIT Pending Timer exceeds the pending timer threshold (TH _{uit, HO} or TH _{uit, re-est} ) Transmitted to station 200. Also, TH _{uit, HO} or TH _{uit, re-est} is set longer than the time required for transmitting the PDCP status report and confirming the delivery of the PDCP status report.

  For this reason, after the mobile station 200 is handed over or reconnected, the transmission of the DRX command MAC CE is suspended during the period in which the base station 100A transmits and receives the PDCP status report. That is, according to the base station 100A, the mobile station that has transitioned to the DRX state due to the transmission of the DRX command MAC CE is prevented from returning to the non-DRX state due to the transmission / reception of the PDCP status report. The battery consumption of the mobile station 200 can be prevented while suppressing waste.

  More specifically, when the mobile station 200 frequently repeats handovers or reconnections, it becomes possible to transmit a DRX command MAC CE to the mobile station 200 at an appropriate timing, and unnecessary PDCCH transmission thereafter. As a result, battery consumption of the mobile station 200 can be prevented. That is, even when there is no user data to be transmitted / received, when the handover or reconnection procedure is activated, the base station 100A transmits the PDCCH to the mobile station 200 to transmit control data. The station 200 transitions to the non-DRX state due to reception of the PDCCH.

  Once the mobile station 200 has transitioned to the non-DRX state, it cannot transition to the DRX state until the DRX Inactivity Timer expires again.Therefore, if the handover or reconnection is frequently repeated, the mobile station 200 will enter the DRX state during that time. It will not be possible to transition. According to the above-described embodiment, such a problem is also solved.

In this embodiment, when the UE Inactive Timer is reset when the elapsed time measured by the UIT Pending Timer exceeds TH _{uit, HO} or TH _{uit, re-est} , the DRX command MAC CE Transmission is canceled. Therefore, when there is data to be transmitted / received by the mobile station 200, it is possible to prevent the mobile station 200 from inadvertently transitioning to the DRX state due to the transmission of the DRX command MAC CE.

  Furthermore, in this embodiment, after the base station 100A transmits the DRX command MAC CE to the mobile station 200, when receiving a delivery confirmation (ACK) for a MAC PDU including the DRX command MAC CE, or a hybrid ARQ (HARQ ) Reaches the maximum number of times, it is determined that the mobile station 200 has transitioned to the DRX state. For this reason, if the delivery confirmation (ACK) for the MAC PDU including the DRX command MAC CE can be confirmed, it can be ensured that the mobile station 200 has transitioned to the DRX state. In addition, when the maximum number of retransmissions by HARQ for the MAC PDU including the DRX command MAC CE reaches the maximum number, the mobile station 200 determines that the mobile station 200 has transitioned to the DRX state, so that the mobile station 200 transmits the MAC PDU including the DRX command MAC CE. If reception is possible, a state mismatch regarding the DRX state can be avoided between the base station 100A and the mobile station 200, and appropriate scheduling can be performed.

(5) Other Embodiments As described above, the content of the present invention has been disclosed through one embodiment of the present invention. However, it is understood that the description and drawings constituting a part of this disclosure limit the present invention. should not do. From this disclosure, various alternative embodiments will be apparent to those skilled in the art.

For example, in the above-described embodiment, when the UE Inactive Timer is reset when the elapsed time measured by the UIT Pending Timer exceeds TH _{uit, HO} or TH _{uit, re-est} , the DRX command MAC Although the CE transmission has been cancelled, such processing does not necessarily have to be executed.

  Further, in the above-described embodiment, the base station 100A executes processing related to transmission of the DRX command MAC CE. However, all or part of such processing is performed by, for example, another process connected to the core network 50. You may make it perform in a communication apparatus (for example, MME).

  As described above, the present invention naturally includes various embodiments that are not described herein. Therefore, the technical scope of the present invention is defined only by the invention specifying matters according to the scope of claims reasonable from the above description.

50 ... Core network
100A, 100B ... Base station
101 ... Wireless communication part
103 ... Data transceiver
105 ... PDCP controller
107 ... Timer control unit
109… DRX control unit
200 ... Mobile station
C1, C2 ... cell

Claims (5)

After starting the handover or reconnection of the mobile station, a base station that transmits a PDCP status report for reporting the reception status of uplink data to the mobile station,
A DRX control unit for transmitting a DRX command MAC CE for controlling the mobile station to a DRX state for intermittently receiving a control channel to the mobile station;
A timer control unit for controlling a pending timer for measuring an elapsed time from the start of handover or reconnection of the mobile station,
The DRX control unit, when the elapsed time measured by the pending timer exceeds a pending timer threshold longer than a time required for transmission of the PDCP status report and confirmation of delivery of the PDCP status report, and the mobile station A base station that transmits the DRX command MAC CE to the mobile station when the time measured by the inactivity timer that measures the time when there is no data to be transmitted exceeds the inactivity timer threshold. The timer control unit has an inactivity timer that measures a time when there is no user data to be transmitted to the mobile station,
The DRX controller is
Until the transmission of the PDCP status report and the delivery confirmation of the PDCP status report are completed, the determination whether the elapsed time measured by the inactivity timer exceeds the inactivity timer threshold is stopped,
The determination as to whether or not the elapsed time measured by the inactive timer exceeds the inactive timer threshold is resumed when the elapsed time measured by the pending timer exceeds the pending timer threshold. The listed base station.   The DRX control unit, when the elapsed time measured by the pending timer exceeds the pending timer threshold, when the inactive timer is reset, stops the transmission of the DRX command MAC CE. Item 4. The base station according to Item 1.   When the DRX control unit receives a delivery confirmation for a MAC PDU including the DRX command MAC CE after transmitting the DRX command MAC CE to the mobile station, or when retransmission by hybrid ARQ reaches the maximum number of times The base station according to claim 1, wherein the mobile station determines that the mobile station has transitioned to a DRX state. A communication control method by a communication device for transmitting a PDCP status report for reporting the reception status of uplink data to the mobile station after the start of handover or reconnection of the mobile station,
Transmitting a DRX command MAC CE for controlling the mobile station to a DRX state for intermittently receiving a control channel to the mobile station;
Controlling a pending timer for measuring an elapsed time from the start of handover or reconnection of the mobile station,
In the step of transmitting the DRX command MAC CE, when the elapsed time measured by the pending timer exceeds a pending timer threshold that is longer than the time required for transmission of the PDCP status report and confirmation of delivery of the PDCP status report, And a communication control method for transmitting the DRX command MAC CE to the mobile station when a time measured by an inactivity timer that measures a time when there is no data to be transmitted to the mobile station exceeds an inactivity timer threshold .

Images