WO2007148388A1 - Packet transfer method and base station - Google Patents

Abstract

A transmission delay can be reduced even if a mobile station makes a reconnection to a base station due to a failure in handover. A BS (21) stores remaining packets of a UE (11) when the UE (11) performs handover from the BS (21) to a BS (22). The BS (21) then transfers the remaining packets of the UE (11) to the BS (22) as the handover destination of the UE (11). This enables the UE (11) to receive the remaining packets without any loss thereof from the base station because even if the UE (11) makes the reconnection to the BS (21) due to the failure in the handover, the BS (21) contains the remaining packets.

Description

 Specification

 Packet transfer method and base station

 Technical field

 TECHNICAL FIELD [0001] The present invention relates to a packet transfer method and a base station, and more particularly to a packet transfer method and a base station of a base station that performs radio communication with a mobile station.

 Background art

 [0002] In mobile communication systems such as mobile phones, the third-generation service based on the Code Division Multiple Access (CDMA) method has been started, but next-generation mobile communication that enables higher-speed communication. System review is underway. In this case, in addition to high-speed transmission rate, reduction of transmission delay is a major issue (for example, see Non-Patent Document 1).

 [0003] In mobile communication, when a mobile station moves during communication, switching of the base station with which it communicates (node over) occurs. Conventionally, in a mobile communication system, data communication using circuit switching has been the mainstream, and therefore, soft node over has been used. However, in next-generation mobile communication systems, data communication using packet switching is the mainstream, so hard handover is used. Therefore, in order to reduce transmission delay, it is indispensable to perform node handover so as to prevent packet loss during handover and prevent end-to-end packet retransmission.

 [0004] Therefore, as a handover method in Mobile IP (Internet Protocol), IETF (Intemet Engineering Task Force) proposes a method of transferring the remaining packets of the mobile station from the source base station to the destination base station. (For example, see Non-Patent Document 2). In the next-generation mobile communication handover, the specification of which is being developed by 3GPP (3rd Generation Partnership Project), a method of transferring the residual packet of the mobile station from the source base station to the destination base station is applied ( For example, see Non-Patent Document 3). As a result, the mobile station can reduce the transmission delay for receiving the packet immediately after the handover, and can execute a high-speed handover.

FIG. 27 is a diagram showing a configuration example of a conventional mobile communication system. For example, A mobile communication system of UE (User Equipment) 101, BS (Base Station) 111 to 113, and GW (Gateway) 121, which are mobile phones, is shown. Circles shown in the figure indicate the radio wave coverage of BSs 111 to 113. Also, in the figure, buckets P1 to P4 exchanged in the mobile communication system are shown. In the figure, for simplicity, the upper station of BS is described as GW. 1S Actually, MMEZUPE (Mobile Management Entity / User Plane Entity) fulfills its function.

 [0006] As shown in the figure, it is assumed that handover from BS111 to BS112 occurs due to movement of UE101. In this case, the packets P1 to P4 destined for the UE 101 remaining in the BS 111 are forwarded by 112 BS as shown in the figure.

Accordingly, UE 101 can receive the residual packets P1 to P4 without loss even when a handover occurs from BS 111 to BS 112. That is, UE 101 can suppress a transmission delay that occurs when packets P1 to P4 are not exchanged end-to-end.

FIG. 28 is a sequence diagram of the mobile communication system in FIG. UE101, BS11 in Figure 27

1, 112 and GW 121 proceed according to the following steps.

 [Step S201] The UE 101 notifies the BS 111 of the current radio quality.

[Step S202] The BS 111 receives the radio quality from the UE 101. Based on the received radio quality, the BS 111 determines a movement-destination base station (a HO (handover) destination BS) of the UE 101. Here, it is assumed that BS 111 determines BS 112.

[Step S 203] BS 111 makes an HO request to BS 112. The BS 111 also transmits UE 101 information such as ID (Identification) and QoS (Quality of Service) in the case of an HO request.

 [Step S204] The BS 112 performs call admission control for the UE 101 in response to the HO request from the BS 111. BS 112 performs call admission control based on UE 101 information received from BS 111.

 [Step S205] When the BS 112 performs call admission control, the BS 112 returns an HO response to the BS 111.

 [Step S206] When BS111 receives the HO response from BS112,

Send O instructions.

[0013] [Step S207] The BS 111 transmits a HO instruction to the UE 101, and then transmits a residual parameter of the UE 101. Transfer packets P 1 to P4 to BS 112.

 [Step S208] Upon receiving the HO instruction from the BS 111 in Step S206, the UE 101 ensures synchronization between the BS 112 and the physical layer (L1 synchronization, LI: Layer 1).

[Step S209] When the UE 101 ensures the synchronization between the BS 112 and the physical layer, the UE 101 notifies the BS 112 of HO completion.

 [Step S210] Upon receiving the HO completion from the UE 101, the BS 112 notifies the GW 121 of the higher station of the HO completion.

 [Step S211] When the GW 121 receives the HO completion from the BS 112, the GW 121 performs path switching.

. For example, path switching is performed so that data addressed to UE 101 is transmitted to BS 112.

[Step S212] The GW 121 transmits the reply of Step S210 to the BS 112.

 [Step S213] The BS 112 instructs the BS 111 to release resources.

Note that the packet transfer in step S207 is performed after the HO instruction in step S206, but it may be performed after receiving the HO response in step S205 !.

 FIG. 29 is a diagram showing a hardware configuration example of the BS of FIG. As shown in the figure, the BS 111 includes a transmission / reception unit 131, a measurement unit 132, an HO determination unit 133, a buffer 135, and a control unit 136.

 [0018] The transmission / reception unit 131 performs radio communication with the UE. The transmission / reception unit 131 transmits the packet stored in the buffer 135 to the UE by radio, and receives the packet data by UE power radio.

 Measurement unit 132 receives the radio quality of the UE received by transmission / reception unit 131. The HO determination unit 133 determines the HO destination of the UE based on the radio quality received by the measurement unit 132. For example, the HO determination unit 133 determines the HO destination so that it is HOed by a BS with good radio quality.

 [0020] The buffer 135 stores a packet which is user data to be transmitted to the UE as well as the upper station (GW121) power.

The control unit 136 controls transfer of packets stored in the buffer 135 according to control data transmitted from other BSs and GWs. For example, when an HO response is received from the HO destination BS, the control unit 136 transfers the UE packet remaining in the buffer 135 to the HO destination BS. Rub to do. Also, the control unit 136 transmits control data to other BSs and GWs 121. For example, the HO request is transmitted to the BS according to the determination of the HO destination of the HO determination unit 133.

Note that the BSs 112 and 113 shown in FIG. 27 also have the same configuration as that shown in FIG.

 FIG. 30 is a flowchart showing the operation of the BS of FIG.

 [Step S221] The HO determination unit 133 of the BS 111 determines the HO destination based on the radio quality of the UE 101 of the measurement unit 132. This determination of the HO destination corresponds to step S202 in FIG.

 [Step S222] The control unit 136 of the BS 111 determines whether or not the HO response has been received from the HO destination BS 112. If an HO response is received, the process proceeds to step S223. If no HO response is received, the process proceeds to step S221. The reception of this HO response corresponds to step S205 in FIG.

 [Step S223] The control unit 136 of the BS 111 gives an HO instruction to the UE 101. This HO instruction corresponds to step S206 in FIG.

 [Step S224] The control unit 136 of the BS 111 transfers the UE 101 packet remaining in the buffer 135 to the BS 112. This packet transfer corresponds to step S207 in FIG.

 [0024] Thus, by transferring the packet from the source BS 111 to the destination BS 112, the HO transmission delay of the UE 101 is suppressed.

 The sequence shown in FIG. 28 described above is merely an example, and the sequence described below is also assumed (see, for example, Non-Patent Document 4). For example, in step S203 of FIG. 28, the HO-source BS 111 transmits context data instead of the HO request. In step S205, the HO-destination BS 112 transmits a context data reception response instead of the HO response. In step S210, the HO-destination BS 112 transmits HO completion to the BS 111, and transmits a location information update message to the GW 121.

 [0025] In addition, there is a mobile communication system in which a mobile station establishes a HO with a new base station when the HO fails (see Non-Patent Document 5, for example).

Non-Patent Document 1: "3GPP TR25.913 V7.3.0 Requirements for Evolved UTRA (E-UTRA) and Evolved UTRAN (E-UTRAN) (Release 7), 3GPP (France), 2006— 03 Non-Patent Document 2: R. Koodl 'RFC4068 Fast Handover for Mobile IPv6 ", IETF (America), 2005-07

 Non-Patent Document 3: Siemens, "R3—060759 C—plane correction on TR25.912”, 3GPP (France), 2006-05, p2

 Non-Patent Document 4: "3GPP TR25.813 VI.0.0 Evolved Universal Terrestrial Radio Access (

E-UTRA) and Evolved Universal Terrestrial Radio Access Network (E-UTRAN); Radio interface protocol aspects (Release 7) ", 3GPP (France), 2006-05, p28

 Non-Patent Document 5: Siemens, "R3- 060468 LTE ACTIVE mobility in" non-canonical "HO c ases", 3GPP (France), 2006-04

 Disclosure of the invention

 Problems to be solved by the invention

[0026] By the way, even when the HO to the destination base station fails, the residual bucket of the source base station is transferred to the destination base station that failed the HO. For this reason, even if the mobile station tries to resume communication with the source base station, the remaining packet is missing, so this packet must be retransmitted end-to-end, resulting in a transmission delay.

 [0027] Further, in Non-Patent Document 5, the sequence indicated when the HO fails is not possible. The mobile station cannot immediately receive the packet immediately after the HO from the source base station.

 The present invention has been made in view of such points, and even if HO fails, it can communicate with a base station without missing residual packets, and a packet transfer method and method that suppress transmission delay during HO and The purpose is to provide a base station.

 Means for solving the problem

 In the present invention, in order to solve the above problem, in the bucket transfer method of a base station that performs radio communication with a mobile station, when the mobile station is handed over, the residual bucket of the mobile station is stored, A packet transfer method is provided, wherein the residual packet is transferred to a destination base station that is a handover destination of the mobile station.

[0029] According to such a packet transfer method, when a mobile station performs handover, the mobile station stores the residual packet of the mobile station, and transfers the residual packet to the destination mobile station of the handover destination. As a result, even if the mobile station fails to perform handover and reconnects to the base station, it remains in the base station. Since the retained packet is stored, the mobile station can receive from the base station without missing the remaining packet.

 [0030] Further, in order to solve the above problem, in the packet transfer method of a base station that performs radio communication with a mobile station, the residual packet of the mobile station is transferred to a target base station that is a handover destination of the mobile station, When the mobile station fails in handover and reconnects to the base station, the packet transfer method is provided, wherein the residual packet is received from the destination base station.

 [0031] According to such a packet transfer method, when a mobile station transfers a residual packet of a mobile station to a mobile destination base station that is a handover destination of the mobile station, and the mobile station fails in handover and reconnects to the base station. The destination base station power receives the residual packet. As a result, even if the mobile station fails to hand over and reconnects to the base station, since the base station has residual packets, the mobile station receives the residual packets from the base station without missing them. It becomes possible.

 [0032] Further, in order to solve the above problems, in the base station that performs radio communication with the mobile station of the present invention, when the mobile station performs handover, the residual packet storage that stores the residual packet of the mobile station A base station characterized by having a unit is provided.

 [0033] According to such a base station, when the mobile station performs handover, the residual packet of the mobile station is stored. As a result, even if the mobile station fails to perform a handover and reconnects to the base station, the base station stores the residual packet, so the mobile station is not able to drop the residual packet. It becomes possible to receive.

 [0034] Further, in order to solve the above problem, the base station that performs radio communication with the mobile station is transferred to the destination base station that is the handover destination of the mobile station, and the residual packet of the mobile station is transferred. When the mobile station fails in handover and reconnects to the base station, a base station is provided that receives the residual packet from the destination base station.

[0035] According to such a base station, when the mobile station transfers the residual packet of the mobile station to the destination base station that is the handover destination of the mobile station, and the mobile station fails in the handover and reconnects to the base station, Destination base station power Receives residual packets. As a result, even if the mobile station fails to perform handover and reconnects to the base station, there are residual packets in the base station. The station can also receive base station power without missing residual packets. The invention's effect

 [0036] According to the present invention, when a mobile station hands over, the mobile station's residual packets are stored (held). Then, the residual packet is transferred to the destination base station that is the handover destination of the mobile station.

 As a result, even if the mobile station fails to perform handover and reconnects to the base station, the mobile station receives the residual packet from the base station without missing the residual packet because the base station holds the residual packet. Transmission delay at the time of handover can be suppressed.

 [0037] The above and other objects, features, and advantages of the present invention are preferred as examples of the present invention, and will become apparent from the following description in conjunction with the accompanying drawings showing embodiments.

 Brief Description of Drawings

 FIG. 1 is a diagram showing a configuration example of a mobile communication system according to a first embodiment.

 FIG. 2 is a HO sequence diagram of FIG.

 FIG. 3 is a diagram showing an example of a hardware configuration of the BS in FIG. 1.

 FIG. 4 is a flowchart when transferring a residual packet of a source base station.

 FIG. 5 is a flowchart when receiving a residual packet of a destination base station.

 FIG. 6 is a diagram showing a hardware configuration example of a BS according to the second embodiment.

 FIG. 7 is a diagram illustrating a header storage unit.

 FIG. 8 is a flowchart when transferring a residual packet of a source base station.

 FIG. 9 is a diagram showing a configuration example of a mobile communication system according to a third embodiment.

 FIG. 10 is an HO sequence diagram of FIG.

 FIG. 11 is a flowchart when transferring a residual packet of a source base station.

 FIG. 12 is a flowchart when a residual packet of a new base station is received.

 FIG. 13 is another HO sequence diagram of FIG.

 FIG. 14 is a flowchart when transferring a residual packet of a source base station.

 FIG. 15 is a flowchart when transferring a residual packet of an old destination base station.

FIG. 16 is a flowchart when transferring a residual packet of a new base station. FIG. 17 is a flowchart when transferring a residual packet of a source base station.

 FIG. 18 is a diagram showing a configuration example of a mobile communication system according to a fifth embodiment.

 FIG. 19 is an HO sequence diagram of FIG.

 FIG. 20 is a diagram showing a hardware configuration example of the BS of FIG.

 FIG. 21 is a flowchart showing the operation of the source base station.

 FIG. 22 is a diagram showing a configuration example of a mobile communication system according to a sixth embodiment.

 FIG. 23 is an HO sequence diagram of FIG.

 FIG. 24 is a flowchart showing the operation of the source base station.

 FIG. 25 is another HO sequence diagram of FIG.

 FIG. 26 is a flowchart when transferring a residual packet of an old destination base station.

 FIG. 27 is a diagram showing a configuration example of a conventional mobile communication system.

 FIG. 28 is a sequence diagram of the mobile communication system in FIG. 27.

 FIG. 29 is a diagram showing a hardware configuration example of the BS of FIG. 27.

 FIG. 30 is a flowchart showing the operation of the BS of FIG. 29.

 BEST MODE FOR CARRYING OUT THE INVENTION

 [0039] Hereinafter, a first embodiment of the present invention will be described in detail with reference to the drawings.

 FIG. 1 is a diagram illustrating a configuration example of a mobile communication system according to the first embodiment. In the figure, for example, UE11, BS21 to 23, and GW31, which are mobile phones, are shown. Areas A1 to A3 shown in the figure indicate the radio wave coverage of BS21 to 23. UE11 and BS21-23 perform radio | wireless communication using OFDM (Orthogonal Frequency Division Multiplexing) in a LTE (Long Term Evolution) system, for example. In the figure, packets P1 to P4 exchanged in the mobile communication system are shown.

 [0040] It is assumed that UE11 moves from area A1 to area A2. The BS 21 that is the source base station makes a HO request to the BS 22 that is the destination base station, and transfers the remaining packets P1 to P4 of the UE 11 to the BS 22. This is so that when UE11 succeeds in BS22 and HO, packets P1 to P4 can be received from BS22 without being lost. BS21 copies packets P1 to P4 to a storage device such as a notifier and transfers them to BS22.

[0041] UE11 returns to area A1 as shown in the figure without performing L1 synchronization with BS22. . In other words, UEl l fails to HO with BS 22. In this case, UE11 communicates with BS21 again. At this time, the residual packets P1 to P4 are transferred from BS21 to BS22. However, since they are copied and transferred, UE11 can receive packets P1 to P4 from BS21 without missing them. .

 [0042] Thus, when HO occurs, BS21 as the source base station copies residual packets P1 to P4 and transfers them to BS22 as the destination base station. Therefore, even if UE11 fails in BS22 and HO which are destination base stations, communication with BS21 which is a source base station without missing packets P1 to P4 can be resumed, and transmission delay can be suppressed.

 Next, the HO sequence in FIG. 1 will be described using a sequence diagram.

 Figure 2 is the HO sequence diagram of Figure 1. UE11 and BS21, 22 in Fig. 1 proceed according to the following steps.

 [Step S1] The BS 21 receives radio quality such as UE11 power, eg, SINR (Signal to Interface and Noise Ratio). BS21 determines the HO destination of UE11 based on the received radio quality. Here, it is assumed that BS22 is determined as the HO destination.

 [0045] BS21 makes an HO request to BS22, which is the HO destination. BS22 performs call admission control in response to the HO request of BS21, and returns an HO response to BS21. BS21 gives HO instruction to UE11 in response to HO response of BS22 force.

 Note that the sequence of step S1 is the same as the sequence of steps S201 to S206 in the sequence shown in FIG.

 [Steps S2, S3] BSs 21 and 22 start timers.

 [Step S 4] BS 21 holds UE 11 mobile station information. The mobile station information is, for example, UE 11 ID or QoS. BS21 also keeps UE11's remaining packets in a buffer. BS21 then transfers the remaining packet of UE11 to BS22.

 [0048] The mobile station information is transmitted to BS 22 at the time of the HO request to BS 22, as described in step S203 of FIG. In addition, the residual packet may be transferred after the HO response from BS22.

[Step S5] UE11 receives the HO instruction from BS21 in step S1, and ensures synchronization between BS22 and the physical layer (L1 synchronization, LI: Layer 1). And here, as explained in Figure 1 Furthermore, UE11 returns to area Al from area A2, and therefore L1 synchronization with BS22 fails.

 [Step S6] UE 11 ensures L1 synchronization with BS 21 that is the source base station due to HO failure with BS 22 that is the destination base station. BS21 holds the remaining packet of UE11 in step S4. As a result, the UE 11 can communicate with the BS 21 without missing a packet.

 [Step S7] BS21 transmits an instruction to release resources to BS22.

 [Steps S8, S9] When BS21 transmits a resource release to BS22, it stops the timer started in step S2. BS22 receives the resource release from BS21 and stops the timer started in step S2.

 [Step S10] The BS 22 deletes the mobile station information of UE11 and the residual packet.

 Note that BS22 will continue to hold UE11's residual packet if it cannot receive the resource release from BS21 due to a communication failure, for example. In order to prevent such a continuous holding of the residual packet, the BS 22 erases the residual packet of the UE when the timer expires. Similarly, BS1 cannot delete the retained UE's residual packet due to some failure.

 Next, the hardware configuration of BS21 in FIG. 1 will be described.

 FIG. 3 is a diagram illustrating a hardware configuration example of the BS of FIG. As shown in the figure, the BS 21 has a transmission / reception unit 41, a measurement unit 42, an HO determination unit 43, buffers 44 and 45, a mobile station information unit 46, a timer 47, a scheduler 48, and a control unit 49.

 [0054] The transmission / reception unit 41 performs radio communication with the UE. The transmission / reception unit 41 transmits the packet stored in the buffer 44 to the UE by radio, and the UE power also receives the packet data transmitted by radio.

 Measurement unit 42 receives the UE radio quality received by transmission / reception unit 41. The HO determination unit 43 determines the HO destination of the UE based on the radio quality received by the measurement unit 42. For example, the HO determination unit 43 determines the HO destination so that it is HOed by a BS with good radio quality.

[0056] In the noffer 44, a packet sent from the host station is temporarily stored. buffer 45 stores a residual packet of the UE transferred at the time of HO.

 The mobile station information unit 46 manages and holds mobile station information such as UE ID and QoS.

 [0057] The scheduler 48 receives UE QoS and the like from the control unit 49, and assigns UE transmission rights. The scheduler 48 reads the required number of packets to be transmitted to the UE from the buffer 44 and outputs the packets to the transmission / reception unit 41.

 The control unit 49 performs transfer control of the packet stored in the buffer 44 in accordance with control data transmitted from another BS or GW. For example, when an HO response is received from the HO-destination BS, the control unit 49 transfers the UE packet remaining in the buffer 44 to the HO-destination BS. In addition, the control unit 49 transmits control data to other BSs and GWs. For example, the HO request is transmitted to the BS according to the determination of the HO destination of the HO determination unit 43.

 [0059] When transferring the residual packet to the HO destination BS, the control unit 49 stores (holds) the residual packet to be transferred in the nother 45. In addition, the mobile station information unit 46 holds the mobile station information of the UE that performs HO.

 [0060] Further, the control unit 49 transmits the residual packet held in the nother 45 to the UE that has failed in HO and reconnected.

 In addition, the control unit 49 starts the timer 47, and when the timer 47 expires, erases the residual packet held in the nother 45 and the mobile station information of the UE held in the mobile station information unit 46. To do.

 [0061] The reason why the buffers 44 and 45 are separately managed as described above is because of the relationship with the scheduler 48. For example, it is assumed that five packets are stored in the noffer 44. When an HO occurs, the control unit 49 transfers the five packets in the buffer 44 to the BS of the HO destination, deletes them, and stores them in the noffer 45. Therefore, at this time, even if the scheduler 48 grants the transmission right to the UE, since there is no packet in the buffer 44, it is possible to prevent UE scheduling.

[0062] In addition, the first one packet in the buffer 44 may be transmitted to the UE before HO, and only the remaining four packets may be forwarded to the HO destination. In this case, only the first one packet remains in the nota 44, and the remaining four packets are stored in the buffer 45. Therefore, when scheduler 48 assigns a transmission right to the UE, the first one Only packets can be sent to the UE.

[0063] BSs 22 and 23 have the same hardware configuration as BS 21, and a description thereof is omitted.

 Next, the operation when the source base station BS21 transfers a packet will be explained using a flow chart.

 FIG. 4 is a flowchart when transferring the residual packet of the source base station.

 [Step S 21] The mobile station information unit 46 holds UE 11 mobile station information to which the residual packet is transferred. This process corresponds to the mobile station information holding in step S4 of FIG.

[Step S22] The control unit 49 holds the residual packet of the UE 11 stored in the buffer 44 in the buffer 45 and transfers it to the BS 22 that is the HO destination. This process corresponds to the packet holding and packet transfer in step S4 of FIG.

[Step S23] The control unit 49 detects reconnection with the UE 11. This process corresponds to step S6 in FIG.

 [Step S24] The control unit 49 transmits the residual packet of the UE 11 held in the nother 45 to the UE 11 that has reconnected.

[Step S 25] The control unit 49 instructs the BS 22 that is the HO destination to release resources. This process corresponds to step S7 in FIG.

 Next, the operation of BS22 of the destination base station that receives the residual packet will be described using a flow chart.

 FIG. 5 is a flowchart when receiving a residual packet of the movement-destination base station. Note that the hardware configuration example shown in FIG. 3 is described as an example of the hardware configuration of BS 22 of the target base station.

 [Step S31] The mobile station information unit 46 holds the mobile station information received from the BS 21 that is the source base station. The mobile station information is received when, for example, an HO request is received from BS21.

 [Step S 32] The control unit 49 receives the residual packet transferred from the BS 21 and holds it in the buffer 44.

[Step S33] The control unit 49 detects L1 synchronization failure with the UE11. This process corresponds to step S5 in FIG. [Step S34] The control unit 49 receives the resource release from the BS 21 that is the source base station. The control unit 49 stops the timer 47 in response to the resource release from the BS 21. This process corresponds to steps S7 and S9 in FIG.

[Step S 35] Upon receiving the resource release from the BS 21, the control unit 49 deletes the mobile station information in the mobile station information unit 46 and the UE 11 residual packet held in the notifier 44. This process corresponds to step S10 in FIG.

[0073] Thus, BS21, which is the source base station, transfers the remaining packet of UE11 to BS22 of the destination base station, and holds it in the nota 45. This causes HO to fail and U

Even if E11 resumes communication with BS21, residual packets can be received from BS21 without being lost, and transmission delay can be suppressed.

[0074] In the above description, the force for realizing the buffers 44 and 45 separately may be realized by dividing one storage device into two areas to realize two buffers 44 and 45 !.

 Next, a second embodiment of the present invention will be described in detail with reference to the drawings. In the first embodiment, two notpers are prepared, and the residual packet to be transferred is held in one buffer. On the other hand, in the second embodiment, the remaining packets are held by one buffer.

 FIG. 6 is a diagram illustrating a hardware configuration example of the BS according to the second embodiment. In FIG. 6, the same components as those in FIG.

 As shown in the figure, the BS 21 has an identifier (header) storage unit 51. For FIG. 3, the koffa 45 is omitted.

 When transferring the residual packet stored in the buffer 44 to the HO destination BS 22, the control unit 52 stores the identifier (header) of the residual packet to be transferred in the header storage unit 51. This is because the residual packet to be transferred is held in one buffer 44, so that the transferred residual packet is distinguished from other packets. The control unit 52 does not erase the residual packet stored in the buffer 44 even if the residual packet is transferred to the BS 22 of the HO destination.

 The control unit 52 refers to the header stored in the header storage unit 51, and transmits the packet held in the buffer 44 to the UE 11.

For example, it is assumed that five packets are held in the notifier 44. Control unit 52 is HO It is assumed that four packets excluding the first packet in the buffer 44 are transferred to the BS 22 of the HO destination due to the occurrence of. In other words, it is assumed that only the first packet among the five packets can be transmitted to U E11.

[0078] At this time, if the transmission right is assigned to UE11 by scheduler 48, since the remaining packets are also held in nota 44, scheduler 48 will transmit all five packets to UE11. .

 However, since the headers of the four transferred residual packets are stored in the header storage unit 51, the control unit 52 refers to the header storage unit 51 to transfer the transferred residual packets to the UE 11. The scheduler 48 is controlled so that it is not transmitted to. As a result, only the first packet is sent to UE11.

 [0080] When the UE 11 resumes communication with the BS 21, the control unit 52 refers to the header storage unit 51, and controls the scheduler 48 to transmit the residual packet stored in the noffer 44 to the UE 11. Good.

 FIG. 7 is a diagram illustrating the header storage unit. In the figure, the packets P11 to P15 and header storage unit 51 stored in the notifier 44 are shown. Assume that packets P11 to P15 have headers HD11 to HD15. Packet P11 is a packet transmitted to UE11, and packets P12 to P15 are assumed to be residual packets transferred to BS22. In this case, the headers HD12 to HD15 of the packets P12 to P15 are stored in the header storage unit 51.

 Note that the sequence in the second embodiment is the same as the sequence diagram in FIG. 2, since the method of holding the residual packet in the buffer is different from that in the first embodiment. However, the BS 21 performs processing for storing the header of the residual packet in the header storage unit 51 when transferring the residual packet.

 [0083] Hereinafter, the operation when BS21 which is the source base station transfers the residual packet will be described using a flow chart.

 FIG. 8 is a flowchart when transferring the residual packet of the source base station.

[Step S41] The mobile station information unit 46 holds the mobile station information of the UE 11 to which the residual packet is transferred. This process corresponds to the mobile station information holding in step S4 of FIG. [Step S42] The control unit 52 holds the residual packet of the UE 11 stored in the buffer 44 and transfers it to the BS 22 that is the HO destination. This process corresponds to the packet holding and packet transfer in step S4 of FIG.

[Step S 43] The control unit 52 puts the header of the residual packet to be transferred into the header storage unit 51. .

 [Step S44] The control unit 52 detects reconnection with the UE 11. This process corresponds to step S6 in FIG.

 [0086] [Step S45] The control unit 52 transmits the remaining packet of the UE 11 held in the buffer 44 to the UE 11 that has reconnected.

 [Step S46] The control unit 52 erases the contents of the header storage unit 51.

 Note that the operation of BS 22 as the movement-destination base station is the same as that in the flowchart of FIG. 5, but BS 22 stores the transferred residual packet in one buffer 44. Then, when the resource is released from the BS 21 or the timer expires, the residual packet of the BS 21 stored in the nota 44 is deleted.

 In this way, the BS 21 that is the source base station transfers the residual packet of the UE 11 to the BS 22 of the destination base station and holds it in one buffer 44. At this time, the BS 21 stores the header of the transferred residual packet in the header storage unit 51. As a result, the BS 21 can suppress the transmission delay of the UE 11 and can cope with the failure of the HO with one buffer. In addition, the cost can be reduced by using one notch.

 Note that, in the above description, the power for storing the header of the packet in the header storage unit 51 is not limited to the header as long as it can identify the packet such as an identifier.

 Next, a third embodiment of the present invention will be described in detail with reference to the drawings. In the first embodiment, the UE 11 resumes communication with the BS 21 that is the source base station when the HO fails. In the third embodiment, a case will be described in which communication is resumed with BS23, which is another base station other than the source base station.

 FIG. 9 is a diagram illustrating a configuration example of a mobile communication system according to the third embodiment. 9, the same components as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.

UE11 performs HO for BS62 but fails. In Figure 1, UE11 The ability to resume communication with the source base station BS61 In Fig. 9, communication with the new base station BS63 is resumed.

 [0091] For example, it is assumed that UE11 cannot communicate with BS62 because it entered a power tunnel that performed HO to BS62, and failed in HO. And when you exit the tunnel, you are in area A3 of BS63. In this case, UE11 resumes communication with BS63 that is not BS61 of the source base station.

[0092] There is no residual packet of UE11 in BS63. Therefore, even if communication with UE11-powered SBS 63 is resumed, packets are lost and transmission delay increases. Thus, BS 61 as the source base station holds the residual packet to be transferred, and transfers the residual packet to BS 63 as the new base station, as in the first embodiment.

[0093] As a result, there are residual packets in BS 63, and UE 11 can resume communication with BS 63 without dropping packets, and can suppress transmission delay.

 BS 61 transfers the residual packet to BS 62. Therefore, BS62 needs to delete the transferred UE11 residual packet.

Next, the HO sequence in FIG. 9 will be described using a sequence diagram.

 FIG. 10 is the HO sequence diagram of FIG. UE11 and BS61-63 of FIG. 9 advance a process according to the following steps.

[Step S51] The BS 61 receives the radio quality such as SINR from the UE 11.

 The BS 61 determines the HO destination of UE11 based on the received radio quality. Here, it is assumed that BS62 is determined as the HO destination.

[0096] BS61 makes an HO request to BS62, which is the HO destination. BS62 performs call admission control in response to the HO request from BS61, and returns an HO response to BS61. BS61 issues a HO instruction to UE11 in response to the HO response of BS62 power.

Note that the sequence of step S51 is the same as the sequence of steps S201 to S206 in the sequence diagram shown in FIG.

 [Steps S52 and S53] The BSs 61 and 62 start timers.

[Step S54] The BS 61 holds the mobile station information of the UE 11. UE11 receives the HO instruction from BS61 and others and secures L1 synchronization with BS62. As explained in Figure 9, UE1 Since 1 entered area A3, L1 synchronization with BS62 failed.

Note that the sequence of step S54 is the same as the sequence of steps S4 and S5 in the sequence diagram shown in FIG.

 [Step S55] Since UE11 is in area A3, it ensures BS1 and L1 synchronization.

[Step S56] UE11 makes a cell update request to BS63. At this time, UE11 transmits the cell information (area A1 information) and the own ID to BS63. The cell information is, for example, an ID given to the cell.

[0101] [Step S57] Upon receiving a cell update request from the UE 11, the BS 63 requests the HO call to the BS 61 of the senor where the UE 11 was originally located.

 [Step S58] Upon receiving the HO call from BS63, BS61 makes an HO request to BS63. At this time, BS 61 transmits mobile station information such as UE 11 ID and QoS to BS 63.

 [0102] [Step S59] BS63 performs call admission control for UE11 in response to the HO request from BS61. BS63 performs call admission control based on the UE11 mobile station information received from BS61.

 [Step S60] BS63, when performing call admission control, returns an HO response to BS61.

 [Step S61] BS61 receives the HO response from BS63 and transfers the retained residual bucket to BS63.

 [Step S62] Upon receiving the residual packet from the BS 61, the BS 63 transmits a cell update response to the UE 11. As a result, the HO for the BS 63 of the UE 11 is completed, and the UE 11 can communicate with the BS 63.

 [Step S63] BS61, after transferring the residual packet to BS63, releases resources to BS62.

 [Step S64] BS62 receives the resource release from BS61 and stops the timer.

[Step S65] The BS 62 deletes the mobile station information and residual packets transferred from the UE 11.

[Steps S66, S67] The BS 61 waits for the timer to expire and deletes the mobile station information of the UE 11. Since BS61 does not resume communication with UE11, the timer is stopped. The mobile station information is deleted after waiting for expiration. Of course, the BS 61 may delete the mobile station information after the resource release transmission in step S63.

[0107] Note that the timer is started in steps S52 and S53 so that the mobile station information and the remaining packets are not retained when a communication failure or the like occurs as in the description of FIG. It is.

 [0108] The hardware configuration of BSs 61 to 63 is the same as in Fig. 3, but the control unit 49 has the following functions. The control rods of BS61 to 63 exchange control data shown in steps S57, S58, S60, etc. in FIG. When BSs 61 to 63 are source base stations, the control unit 49 transfers the residual packets held in the buffer 45 to the new base stations BS61 to 63. The control unit 49 of the new base station stores the received residual packet in the buffer 44.

 [0109] Next, the operation when BS 61, which is the source base station, transfers a packet will be described using a flow chart.

 FIG. 11 is a flowchart when transferring the residual packet of the source base station.

[Step S71] The mobile station information unit 46 of the BS 61 holds the mobile station information of the UE 11 to which the residual packet is transferred. This process corresponds to the mobile station information holding in step S4 of FIG.

[Step S 72] The control unit 49 of the BS 61 holds the residual packet of the UE 11 stored in the buffer 44 in the buffer 45 and transfers it to the BS 62 that is the HO destination. This process corresponds to the packet holding and packet transfer in step S4 of FIG.

 [0112] Note that UE11 fails in HO with BS62. The UE 11 then performs L1 synchronization with the new BS 63 without resuming communication with the source BS 61. Then, UE11 makes a cell update request to BS63, and BS63 makes a HO call to BS61, which is a source base station. This processing corresponds to steps S55 to S57 in FIG.

 [Step S73] The control unit 49 of the BS 61 receives the HO alert from the BS 63.

 [Step S74] The control unit 49 of the BS 61 receives an HO call from the BS 63 and transmits an HO request to the BS 63. This process corresponds to step S58 in FIG.

[0114] [Step S75] The control unit 49 of the BS 61 determines whether or not an HO response is received from the BS 63. . If there is an HO response, proceed to step S76. If there is no HO response, go to step S74.

 [Step S76] The control unit 49 of the BS 61 transfers the residual packet held in the buffer 45 to the BS 63. This process corresponds to step S61 in FIG.

 [Step S77] The control unit 49 of the BS 61 releases resources to the BS 62. This process corresponds to step S63 in FIG. In addition, when BS 62 receives a resource release from BS 61, BS 62 deletes the residual packet and mobile station information transferred from BS 61.

 Next, the operation of BS 63 that receives a residual packet will be described using a flowchart.

 FIG. 12 is a flowchart when receiving a residual packet of a new base station. Figure 1

As shown in steps S55 and S56 of 0, UE11 secures L1 synchronization with BS63 and makes a cell update request to BS63.

[Step S81] The control unit 49 of the BS 63 receives a cell update request from the UE 11. Note that, when receiving a cell update request from the UE 11, the control unit 49 receives information on the cell in which the UE 11 was originally located and its own ID.

[0118] [Step S82] The control unit 49 of the BS 63 receives the cell update request from the UE 11,

Send HO alert to BS61 of the original cell of 1. This process is the step of Figure 10

Corresponds to S57.

 [0119] In response to the HO call from BS63, BS61 makes an HO request to BS63. This process corresponds to step S58 in FIG.

 [Step S83] The control unit 49 of the BS 63 receives the HO request from the BS 61.

[Step S 84] Upon receiving the HO request from the BS 61, the control unit 49 of the BS 63 performs call admission control for the UE 11 and transmits an HO response to the BS 61. This processing corresponds to steps S59 and S60 in FIG.

[0121] BS 61 receives the HO response from BS 63 and transmits the remaining packet of UE 11 held in buffer 45 to BS 63. This process corresponds to step S61 in FIG.

[Step S85] The control unit 49 of the BS 63 stores the residual packet of the UE 11 transferred from the BS 61 in the buffer 44. [Step S86] Upon receiving all remaining packets from the BS 61, the control unit 49 of the BS 63 transmits a cell update response to the UE 11. This process corresponds to step S62 in FIG.

 [0123] Note that UE11 can resume communication with BS63 upon receiving a cell update response from BS63.

 In this way, when the UE 11 does not resume communication with the source base station BS61 but resumes communication with the new base station BS63, the BS61 retransmits the residual packet to the BS63. As a result, UE 11 can resume communication with BS 63, which is a new base station, without packet loss.

[0124] In the above, BS63, which is a new base station, transmits a HO alert to BS61 of the cell where UE11 originally resided. However, the UE 11 is temporarily connected to the BS 62 and temporarily disconnected from the BS 61. Therefore, BS63, which is a new base station, transmits HO alert to BS62. Hereinafter, the sequence in this case will be described.

FIG. 13 is another HO sequence diagram of FIG. UE11 and BS61-63 of FIG. 9 advance a process according to the following steps. In FIG. 13, steps having the same processing as in FIG. 10 are denoted by the same reference numerals.

[Steps S51 to S56] The processing in this step is the same as the processing in steps S51 to S56 in FIG. 10, and a description thereof will be omitted.

 [Step S57a] BS63 receives the cell update request from UE11,

O Request for arousal. In the sequence of Fig. 10, BS63 made a request for HO call to BS61 of the cell where UE11 was originally located.

[Step S58a] BS62 receives an HO call from BS63 and makes an HO request to BS63.

 [Step S59] BS63 performs call admission control for UE11 in response to the HO request from BS62. BS63 performs call admission control based on the UE11 mobile station information received from BS62.

[Step S60a] BS63, when performing call admission control, returns an HO response to BS62. [Step S61a] BS62 receives the HO response from BS63, and transfers the residual packet transferred from BS61 to BS63.

[Step S62a] Upon receiving the residual packet from BS62, BS63 transmits a cell update response to UE11. As a result, the HO for BS63 of UE11 is completed, and UE11 can communicate with BS63.

[Step S63a] BS62, after transferring the residual packet to BS63, releases resources to BS61.

 [Step S64a] BS61 receives the resource release from BS62 and stops the timer.

[Step S65a] The BS 61 deletes the mobile station information and residual packets transferred from the UE 11.

 [Steps S66a, S67a] The BS 62 waits for the timer to expire and deletes the UE 11 mobile station information. Since BS62 does not resume communication with UE11, it does not need to stop the timer and waits for expiration to clear mobile station information. Of course, the BS 62 may delete the mobile station information after the resource release transmission in step S63a.

Next, the operation of BS 61 in the above sequence will be described using a flowchart.

 FIG. 14 is a flowchart when transferring the residual packet of the source base station.

[Step S81a] The BS 61 holds the mobile station information of the UE 11.

 [Step S82a] BS61 holds the remaining packet of UE11 in the buffer and transfers it to BS62 which is the HO destination.

 [Step S83a] The BS 61 receives the resource release from the BS 62. This process corresponds to step S63a in FIG.

 Next, the operation of the BS 62 in the above sequence will be described using a flowchart.

 FIG. 15 is a flowchart when transferring the residual packet of the old destination base station.

 [Step S81b] BS62, which is the old destination base station of UEll, holds the residual packet transferred from BS61 in the buffer.

[Step S82b] BS62 receives the HO alert from BS63. [Step S83b] BS62 receives an HO call from BS63 and sends an HO request to BS63. This process corresponds to step S58a in FIG.

[Step S84b] The BS 62 determines whether or not an HO response is received from the BS 63. If there is an HO response, proceed to step S85b.

 [Step S85b] The BS 62 transfers the residual packet held in the buffer to the BS 63. This process corresponds to step S61a in FIG.

[Step S86b] The BS 62 releases resources to the BS 61. This process corresponds to step S63a in FIG.

 Next, the operation of BS63 in the above sequence will be described.

FIG. 16 is a flowchart when transferring a residual packet of a new base station.

 [Step S81c] The BS 63 receives a cell update request from the UE 11.

 [Step S82c] In response to the cell update request from the UE 11, the BS 63 transmits an H O alert to the BS 62. This process corresponds to step S57a in FIG.

[Step S83c] BS63 receives the HO request from BS62.

 [Step S84c] Upon receiving the HO request from the BS 62, the BS 63 performs call admission control for the UE 11 and transmits an HO response to the BS 62. This process corresponds to steps S59 and S60a in FIG. BS62 receives the HO response from BS63 and transmits the remaining UE11 packet held in the buffer to BS63. This process corresponds to step S61a in FIG.

 [0141] [Step S85c] BS63 holds the residual packet of UE11 transferred from BS62 in the buffer.

 [Step S86c] Upon receiving all remaining packets from the BS 62, the BS 63 transmits a cell update response to the UE 11. This process corresponds to step S62a in FIG.

[0142] In this way, even if BS63, which is a new base station, transmits a HO alert to BS62, which is an old destination base station, UE11 can resume communication without dropping packets. .

Next, a fourth embodiment of the present invention will be described in detail with reference to the drawings. In the third embodiment, the BS includes two buffers 44 and 45, and holds residual packets in the buffer 45. I tried to do it. In the fourth embodiment, as described in the second embodiment, the header of the residual packet is managed and the residual packet is held in one buffer.

 [0144] The configuration example of the mobile communication system in the fourth embodiment is the same as that in Fig. 9. In other words, HO with UE11 BS BS62 in BS61 area A1 fails, and communication with BS61, the source base station, is not resumed, but communication with BS63, the new base station, is resumed.

 [0145] The hardware configuration example of BSs 61 to 63 is the same as that of Fig. 6 shown in the second embodiment. However, the function described in the third embodiment is added to the control unit 52 in FIG. That is, the BSs 61 to 63 according to the fourth embodiment hold a residual packet in one buffer 44 and manage a header of the residual packet in the header storage unit 51. When there are 361 to 63 source base stations, the control unit 52 transfers the residual packets held in one buffer 44 to BS 61 to 63, which are new base stations. The control unit 52 of the new base station stores the received residual packet in the buffer 44.

 [0146] Note that the sequence of UE 11 and BSs 61 to 63 according to the fourth embodiment is the same as the sequence diagram of FIG. Since BS61-63 only keeps the remaining packets in one buffer 44, the sequence between UE11 and BS61-63 does not change.

 [0147] Hereinafter, the operation of BS 61, which is the source base station, will be described using a flowchart.

 FIG. 17 is a flowchart when transferring the residual packet of the source base station.

[Step S91] The mobile station information unit 46 of the BS 61 holds the mobile station information of the UE 11 to which the residual packet is transferred. This process corresponds to the mobile station information holding in step S4 of FIG.

[Step S92] The control unit 52 of the BS 61 transfers the residual packet of the UE 11 stored in the buffer 44 to the BS 62 that is the HO destination. This process corresponds to the packet holding and packet transfer in step S4 of FIG.

 [Step S93] The control unit 52 of the BS 61 stores the header of the residual packet to be transferred in the header storage unit 51.

Note that UE11 failed to HO with BS62. Then, it is assumed that UE11 does not resume communication with the source BS 61 but performs L1 synchronization with a new BS 63. And UE11 is BS Assume that a cell update request is sent to 63, and BS63 issues a HO call to BS61, which is the source base station. This processing corresponds to steps S55 to S57 in FIG.

[0151] [Step S94] The control unit 52 of the BS 61 receives the HO alert from the BS 63.

 [Step S95] Upon receiving the HO call from the BS 63, the control unit 52 of the BS 61 transmits an HO request to the BS 63. This process corresponds to step S58 in FIG.

[0152] [Step S96] The control unit 52 of the BS 61 determines whether or not an HO response is received from the BS 63.

. If there is an HO response, go to step S97. If there is no HO response, go to step S95.

 [Step S97] The control unit 52 of the BS 61 transfers the residual packet held in the buffer 44 to the BS 63. This process corresponds to step S61 in FIG.

 [Step S98] The control unit 52 of the BS 61 releases resources to the BS 62. This process corresponds to step S63 in FIG. In addition, when BS 62 receives a resource release from BS 61, BS 62 deletes the residual packet and mobile station information transferred from BS 61.

 Thus, even if there is one buffer 44 for BS 61 to 63, UE 11 can resume communication with BS 63, which is a new base station, without missing packets.

 Next, a fifth embodiment of the present invention will be described in detail with reference to the drawings. In the fifth embodiment, the source base station does not hold the residual packet as in the first to fourth embodiments. In the fifth embodiment, when the UE fails in HO, the residual bucket transferred to the HO destination is sent back to the source base station again so that the UE can resume communication with the source base station.

 [0155] FIG. 18 is a diagram illustrating a configuration example of a mobile communication system according to the fifth embodiment.

 18, the same components as those in FIG. 1 are denoted by the same reference numerals, and the description thereof is omitted.

 Assume that UE11 moves from area A1 to area A2. The BS 71 that is the source base station makes a HO request to the BS 72 that is the destination base station, and transfers the remaining packets P1 to P4 of the UE 11 to the BS 72. This is so that UE11 can communicate with BS72 without dropping packets P1 to P4 when it succeeds in BS72 and HO. The BS 71 transfers the packets P1 to P4 to the BS 72 without holding them.

[0156] Suppose UE11 fails to HO with BS72. In this case, UE11 communicates with BS71 again. I will believe. At this time, since the remaining packets P1 to P4 are transferred from BS71 to BS72, they do not exist in BS71. Therefore, BS71 sends back the transferred residual packets P1 to P4 to BS72.

[0157] As a result, UE11 is a source base station even if HO destination BS72 and HO fail.

Communication with BS 71 can be resumed.

 Next, the HO sequence in FIG. 18 will be described using a sequence diagram.

FIG. 19 is a HO sequence diagram of FIG. UE11 and BS71, 72 in Fig. 18 proceed according to the following steps.

 [Step S101] BS71 receives radio quality such as SINR from UE11, for example.

. BS 71 determines the HO destination of UEl l based on the received radio quality. Here, it is assumed that BS72 has been determined as the HO destination.

[0159] BS71 makes an HO request to BS72, which is the HO destination. BS72 performs call admission control in response to the HO request from BS71, and returns an HO response to BS71. BS71 gives a HO instruction to UE11 in response to the HO response of BS72 power.

Note that the sequence of step S101 is the same as the sequence of steps 201 to S206 in the sequence diagram shown in FIG.

 [Steps S102 and S103] BS71 and BS72 start timers.

[0161] [Step S104] The BS 71 retains the mobile station information of the UE 11, and forwards the remaining packet to the BS 72 that is the HO destination.

 [Step S105] UE11 receives the HO instruction from BS71 in Step S101,

Ensure L1 synchronization. However, as described in FIG. 18, it is assumed that UE11 has failed in L1 synchronization with BS72.

 [Step S106] UE11 ensures L1 synchronization with BS71, which is the source base station, due to failure of HO with BS72, which is the destination base station.

 [Step S107] BS71 requests BS72 to send back a residual packet. BS7

1 is because it retains UE11's residual packet!

[0163] [Step S108] The BS 72 receives the return request from the BS 71 and transmits the remaining packet of the UE 11 to the BS 71. [Step S109] BS72 stops the timer after sending the residual packet back to BS71.

[0164] [Step S110] The BS 71 receives the return of the residual packet from the BS 72 and stops the timer.

 [Step S111] The BS 72 deletes the mobile station information of the UE 11. Since the residual packet is sent back to BS 71, it is deleted from the buffer in step S108.

 [0165] It should be noted that there is a case where step S107 cannot be received due to the power communication failure after receiving the packet return request in step S107. In this case, the packet is sent back after the timer started in step S103 expires.

 Next, the hardware configuration of BS 71 in FIG. 18 will be described.

 FIG. 20 is a diagram illustrating a hardware configuration example of the BS of FIG. In FIG. 20, the same components as those in FIG. 3 are denoted by the same reference numerals, and the description thereof is omitted.

 [0167] The control unit 81 performs transfer control of the residual packet stored in the buffer 44 in accordance with control data transmitted from another BS or GW. At this time, the control unit 81 does not hold the residual bucket to be transferred. In addition, when the UE fails to HO and reconnects, the control unit 81 has the remaining packet sent back from the transfer destination. The control unit 81 stores the returned residual packet in the buffer 44.

 [0168] Also, when BS 71 is a movement-destination base station, when receiving a request for returning a remaining packet from the movement-source base station, control unit 81 moves the remaining packet stored in nota 44. Send back to the source base station. Other functions are the same as those of the control unit 49 in FIG.

 [0169] Hereinafter, the operation of BS 71, which is the source base station, will be described using a flowchart.

 FIG. 21 is a flowchart showing the operation of the source base station.

[Step S121] The mobile station information unit 46 of the BS 71 holds the mobile station information of the UE 11 to which the residual packet is transferred. This processing corresponds to the mobile station information holding in step S104 of FIG.

[Step S122] The control unit 81 of the BS 71 stores the remaining UE 11 stored in the buffer 44. Transfer the packet to BS72, which is the HO destination. Note that the control unit 81 does not hold the residual packet when transferring the residual packet.

[0172] It is assumed that UE11 fails to HO with BS72. Then, UE 11 performs LI synchronization with BS 71 of the source base station.

 [Step S123] The control unit 81 of the BS 71 detects reconnection with the UE 11. This process

This corresponds to step S106 in FIG.

[Step S124] The control unit 81 of the BS 71 transmits a residual packet return request to the BS 72 that is a transfer destination of the residual packet. This process corresponds to step S107 in FIG. BS72 receives the return request from BS71 and transfers the remaining packet to BS71.

 [Step S125] The control unit 81 of the BS 71 receives the residual packet from the BS 72. As a result, the residual packet returns to BS 71, and UE 11 can resume communication with BS 71, which is the source base station without missing the packet.

 [0175] Note that the control unit 81 of the BS 72 that is the movement-destination base station stores the residual packet transferred from the BS 71 that is the movement-source base station in the buffer 44. Then, the control unit 81 of the BS 72 sends back the residual packet stored in the notifier 44 to the BS 71 when there is a return request from the BS 71.

[0176] In this way, when the UE 11 fails in the HO, the BS 71 has the remaining packet transferred to the BS 72 sent back again so that communication with the UE 11 can be resumed without dropping the packet. As a result, transmission delay can be suppressed, and the BS 71 does not need to have a notch for holding a residual packet, so that the cost can be reduced. It is also effective when there is no room in BS71's capacity.

 [0177] Next, a sixth embodiment of the present invention will be described in detail with reference to the drawings. In the fifth embodiment, if the HO fails, communication with the BS 71 that is the source base station is resumed. In the sixth embodiment, a case will be described in which communication is resumed with another base station other than the source base station.

 FIG. 22 is a diagram showing a configuration example of the mobile communication system according to the sixth embodiment.

In FIG. 22, the same components as those in FIG. 18 are denoted by the same reference numerals, and the description thereof is omitted. UE11 performs HO for BS92 but fails. In FIG. 18, UE 11 resumes communication with BS 91, which is the source base station, but in FIG. 22, it resumes communication with new base station BS 93.

 [0179] For example, suppose UE11 cannot communicate with BS92 because it entered a power tunnel that performed HO to BS92 and failed HO. And when you exit the tunnel, you are in area A3 of BS93. In this case, UE11 resumes communication with BS93 which is not BS91 of the source base station.

 [0180] BS91, which is the source base station, transfers residual packets P1 to P4 to BS92, which was the HO destination. Accordingly, there are no residual packets P1 to P4 in BS91. Also in BS93, UE11's residual packets P1 to P4 do not exist. Therefore, even if UE11 resumes communication with BS93, packets P1 to P4 are lost and transmission delay increases.

 [0181] Therefore, BS91, which is the source base station, sends back the transferred residual packets P1 to P4 from BS92 and transfers them to BS93. As a result, there are residual packets P1 to P4 in BS93, and UE11 can resume communication with BS93 without dropping packets, thereby reducing transmission delay.

 Next, the HO sequence in FIG. 22 will be described using a sequence diagram.

 FIG. 23 is the HO sequence diagram of FIG. UE11 and BS91 to 93 in FIG. 22 proceed according to the following steps.

 [Step S131] The BS 91 receives, for example, radio quality such as SINR from the UE 11. The BS 91 determines the HO destination of UEl l based on the received radio quality. Here, it is assumed that BS92 is determined as the HO destination.

 [0184] BS91 makes an HO request to BS92, which is the HO destination. BS92 performs call admission control in response to the HO request from BS91, and returns an HO response to BS91. BS91 gives HO instruction to UE11 in response to HO response of BS92 power.

 Note that the sequence of step S131 is the same as the sequence of steps S201 to S206 in the sequence diagram shown in FIG.

 [Steps S132, S133] BS91 and BS92 start timers.

[0186] [Step S134] The BS 91 holds the mobile station information of the UE 11, and Transfer to BS92. BS91 does not hold the residual packet in the buffer when transferring the residual packet.

 [0187] In response to the HO instruction from BS91, UE11 performs L1 synchronization with BS92. However, here, as described in FIG. 22, it is assumed that the UE 11 fails in L1 synchronization with the BS 92 and takes L1 synchronization with the BS 93. This process is the same as steps S54 and S55 in FIG. 10. The residual packet is not held in the buffer.

 [Step S135] UE11 makes a cell update request to BS93. At this time, the UE 11 transmits the cell information and the own ID to the BS 93. The cell information is, for example, an ID given to the cell.

[Step S136] Upon receiving a cell update request from the UE 11, the BS 93 requests the HO call to the BS 91 of the Senole where the UE 11 was originally located.

 [Step S137] Since the BS 91 does not transfer and retain the residual packet of the UE 11 to the BS 92, the BS 91 requests the BS 92 to send back the residual packet.

[Step S138] The BS 92 receives the return request from the BS 91 and transmits the remaining packet of the UE 11 to the BS 91.

 [Step S139] BS92 stops the timer.

[Step S140] The BS 92 deletes the mobile station information of the UE 11.

 [Step S141] BS91 makes an HO request to BS93 in response to the HO call of BS93 power in Step S136. At this time, the BS 91 transmits mobile station information such as UE 11 ID and Qos to the BS 93.

 [Step S142] BS93 performs call admission control for UE11 in response to the HO request from BS91. BS93 performs call admission control based on UE11 mobile station information received from BS91.

 [Step S143] BS93, when performing call admission control, returns an HO response to BS91.

 [Step S144] In response to the HO response from BS93, BS91 transfers the residual packet sent back by BS92 to BS93.

[Step S145] Upon receiving the remaining packet from the BS 91, the BS 93 transmits a cell update response to the UE 11. This completes the HO for BS93 of UE11. Can communicate with BS93.

 [0195] [Step S146] The BS 91 expires the timer.

 [Step S147] BS91 deletes the mobile station information of UE11.

 The hardware configuration of BS 91 to 93 is the same as that in FIG. 20, but the control unit 81 has the following functions. The control rod 81 of the BS 91 to 93 exchanges control data shown in steps S136, S137, S141, etc. in FIG. When BSs 91 to 93 are the source base stations, the control unit 81 retransmits the residual packets held in the buffer 44 to the new base stations BS 91 to 93. The control unit 81 of the new base station stores the received residual packet in the buffer 44.

 [0196] Hereinafter, the operation of BS 91, which is the source base station, will be described using a flowchart.

 FIG. 24 is a flowchart showing the operation of the source base station.

[Step S151] The mobile station information unit 46 of the BS 91 holds the mobile station information of the UE 11 to which the residual packet is transferred.

 [Step S 152] The control unit 81 of the BS 91 transfers the remaining packet of the UE 11 stored and stored in the notcher 44 to the BS 92 that is the HO destination. Note that the control unit 81 does not hold the residual packet when transferring the residual packet.

[0198] UE11 fails to HO with BS92. Then, UE11 performs L1 synchronization with a new BS93 that does not resume communication with the source BS91. And UE11 is BS

Assume that a cell update request is sent to 93, and BS93 issues a HO call to BS91, the source base station.

 [0199] [Step S153] The control unit 81 of the BS 91 receives the HO alert from the BS 93. This process corresponds to step S136 in FIG.

 [Step S154] The control unit 81 of the BS 91 receives a HO call from the BS 93 and transmits a return request to the BS 92. This is because BS91 does not transfer and hold the residual packet to BS92. This process corresponds to step S137 in FIG.

[Step S155] The control unit 81 of the BS 91 receives the residual packet of the UE 11 from the BS 92. This process corresponds to step S138 in FIG. [Step SI 56] The control unit 81 of the BS 91 makes an HO request to the new base station BS93. This process corresponds to step S141 in FIG.

[0201] [Step S157] The control unit 81 of the BS 91 determines whether or not an HO response is received from the BS 93. If there is an HO response, go to step S158. If there is no HO response, proceed to step S1 56.

 [0202] [Step S158] The control unit 81 of the BS 91 transfers the residual packet received from the BS 92 to the BS 93. This process corresponds to step S144 in FIG.

 In this way, when the UE 11 fails in HO, the BS 91 as the source base station has the residual packet transferred to the BS 92 sent back again. Then, the residual packet is transferred to BS93, which is a new base station reconnected by UE11. As a result, the UE 11 can resume communication without dropping a packet, and can suppress transmission delay. Since the BS 91 does not need to have a buffer for holding a residual packet, the cost can be reduced. It is also effective when there is no room for BS91 buffer capacity.

 [0203] In the above, BS93, which is a new base station, transmits a HO alert to BS 91 of the cell where UE 11 originally resided. However, UE11 is connected to BS92 temporarily, and it is considered that the connection with BS91 is lost. Therefore, BS93, which is a new base station, sends an HO alert to BS92. Hereinafter, the sequence in this case will be described.

[0204] FIG. 25 is another HO sequence diagram of FIG. UE11 and BS91-93 of FIG. 22 advance a process according to the following steps. In FIG. 25, steps having the same processing as in FIG. 23 are denoted by the same reference numerals.

 [Steps S131 to S135] The processing in this step is the same as the processing in steps S131 to S135 in FIG. 23, and a description thereof will be omitted.

 [Step S136a] BS93 receives the cell update request from UE11, and requests BS92 to call HO.

[0206] Note that, in the sequence of Fig. 23, BS93 made a HO call request to BS91 of the cell where UE11 originally resided. The BS 91 made a request to send back the residual packet to the BS 92 to which the residual packet was transmitted. However, in the sequence of Figure 25, the remaining Since BS93, which is a new base station, directly calls HO to BS92, which is a destination for forwarding toll packets, there is no need to send back residual packets.

[0207] [Step S137a] BS92 receives an HO call from BS93 and makes an HO request to BS93.

 [Step S138a] BS93 performs call admission control for UE11 in response to the HO request from BS92. BS93 performs call admission control based on the mobile station information of UE11 received from BS92.

 [Step S139a] BS93, when performing call admission control, returns an HO response to BS92.

 [Step S140a] Upon receiving the HO response from BS93, BS92 transfers the residual packet transferred from BS91 to BS93.

[Step S141a] Upon receiving the residual packet from the BS 92, the BS 93 transmits a cell update response to the UE 11. This completes the HO for BS93 of UE11, and UE1

1 can communicate with BS93.

[0210] [Step S142a] BS92, after transferring the residual packet to BS93, releases resources to BS91.

 [Step S143a] BS91 stops the timer upon receiving the resource release from BS92.

[0211] [Step S144a] The BS 91 deletes the mobile station information transferred from the UE 11.

 [Steps S145a, S146a] The BS 92 waits for the timer to expire and deletes the UE 11 mobile station information and packet. Since BS92 does not resume communication with UE11, it does not need to stop the timer and waits for expiration to clear mobile station information. Of course, the BS 92 may delete the mobile station information after transmitting the resource release in step S142a.

 [0212] Next, the operation of BS92 in the above sequence will be described using a flowchart.

 FIG. 26 is a flowchart when the residual packet of the old destination base station is transferred.

[0213] [Step S161] BS92, which is the old destination base station of UE11, holds the residual packet transferred from BS91 in a buffer. [Step S162] BS92 receives the HO alert from BS93.

[0214] [Step S163] Upon receiving the HO call from BS93, BS92 sends an HO request to BS93. This process corresponds to step S137a in FIG.

 [Step S164] BS92 determines whether or not an HO response is received from BS93. If an HO response is received, the process proceeds to step S165.

[0215] [Step S165] The BS 92 transfers the residual packet held in the buffer to the BS 93. This processing corresponds to step S140a in FIG.

 In the example of the sequence in FIG. 23, the BS 92 received the return request in step S137 and sent the residual packet back to the BS 91. However, in the sequence in FIG. 25 and this flow chart, the BS 93 is a new base station. In response to the HO response, the remaining packet is sent to BS93 ¾5.

 [Step S166] BS92 releases resources to BS91. This process corresponds to step S 142a in FIG.

 Thus, even if BS93, which is a new base station, transmits an HO alert to BS92, which is an old destination base station, UE11 can resume communication without dropping packets.

 [0217] The above merely illustrates the principle of the present invention. In addition, many variations and modifications are possible to those skilled in the art, and the invention is not limited to the precise configuration and application shown and described above, but all corresponding variations and equivalents are It is regarded as the scope of the present invention by the claims and their equivalents.

 Explanation of symbols

[0218] 11 UE

 21-23 BS

 31 GW

 A1-A3 area

 P1 to P4

Claims

The scope of the claims

 [1] Based on the packet transfer method of the base station that performs wireless communication with the mobile station,

 A packet transfer method comprising: storing a residual packet of the mobile station when the mobile station performs a handover, and transferring the residual packet to a destination base station that is a handover destination of the mobile station.

 [2] When the mobile station fails in handover and reconnects to the base station, the stored residual packet is transferred to the mobile station. Packet transfer method.

 [3] The claim 1, wherein, when the mobile station fails in handover and reconnects to another base station, the stored residual packet is transferred to the other base station. The packet transfer method described.

4. The packet transfer method according to claim 1, wherein an identifier of the residual packet is stored when the residual packet is transferred to a movement-destination base station.

5. The packet transfer method according to claim 1, wherein when the mobile station fails in handover, the mobile base station is instructed to delete the residual packet to the destination base station.

 6. The packet transfer method according to claim 1, wherein mobile station information relating to the mobile station is stored.

 7. The packet transfer method according to claim 1, wherein the stored residual packet is erased after a predetermined time has elapsed.

[8] Receiving the residual packet from the source base station,

 2. The packet transfer method according to claim 1, wherein the residual packet received after a predetermined time elapses is deleted.

[9] According to the packet transfer method of the base station that performs wireless communication with the mobile station,

 Transfer the residual packet of the mobile station to the destination base station of the handover destination of the mobile station;

When the mobile station fails in handover and reconnects to the base station, the mobile station receives the residual packet from the destination base station. And a packet transfer method.

 10. The method according to claim 10, wherein when the mobile station fails in handover and reconnects to another base station, the received residual packet is transferred to the other base station. Packet transfer method.

 [11] For base stations that communicate wirelessly with mobile stations,

 A base station comprising a residual packet storage unit for storing a residual packet of the mobile station when the mobile station performs a handover.

 [12] The residual packet stored in the residual packet storage unit is transferred to the mobile station when the mobile station fails in handover and reconnects to the base station. The base station according to item 11.

[13] When the mobile station fails in handover and reconnects to another base station, the residual packet stored in the residual packet storage unit is transferred to the other base station. The base station according to claim 11.

[14] In a base station that performs radio communication with a mobile station,

 Transfer the residual packet of the mobile station to the destination base station of the handover destination of the mobile station;

 When the mobile station fails in handover and reconnects to the base station, the mobile station receives the residual packet from the destination base station.

 A base station characterized by that.

15. The range according to claim 14, wherein when the mobile station fails in handover and reconnects to another base station, the received residual packet is transferred to the other base station. Base station.