JPWO2007116702A1 - Central node, base station, and handover control method - Google Patents

Abstract

Transmitted from the handover source base station or the handover destination base station to the central node according to the handover of the mobile station, and in the handover source base station and the handover destination base station, they are arranged in the correct order according to the sequence numbers assigned continuously. A sequence number assigning means for assigning a continuous sequence number to user data packets transmitted from a mobile station to a base station, and a user data packet assigned with a sequence number continuously in a central node It is achieved by providing a transmission means for transmitting to.

Description

  The present invention relates to a technique for controlling the order of transmission data during handover between two base stations connected to a central node, and more particularly to a central node and a base station that control the order of transmission data from a mobile station, and The present invention relates to a handover control method.

  In the IMT-2000 system, UE (User Equipment) performs handover (relocation) across NodeBs connected to two RNCs (Radio Network Controllers) connected under the same SGSN (Serving GPRS Support Node). .

  In this case, lossless handover is realized in a sublayer of layer 2, for example, PDCP (Packet Data Convergence Protocol). For this purpose, protocol state synchronization, for example, synchronization of the PDCP sequence number, is performed between the new RNC and the UE from the old RNC that is the handover source to the new RNC that is the handover destination, and an unreceived PDCP PDU (Protocol Data Unit) is transferred.

  At this time, after the transfer of the PDCP PDU stored in the old RNC is completed, the new RNC requests the SGSN to open the downlink U-plane.

In the IMT-2000 system, the RNC-UE terminates an RLC (radio link control), and “In-sequence” in the RAN (Radio Access Network) is guaranteed.
TS 25.323

  However, the background art described above has the following problems.

  In an LTE (Long Term Evolution) system that is currently being standardized by 3GPP, only an in-sequence in the UE-eNode B can be guaranteed by placing an RLC (Radio Link Control) in the base station. However, “In-sequence” throughout the RAN is not guaranteed.

  The present invention has been made in view of this point, and an object of the present invention is to provide a central node, a base station, and a handover control method capable of correcting the order of uplink data at the time of handover.

In order to solve the above problems, the central node of the present invention is:
According to the handover of the mobile station, transmitted from the handover source base station or the handover destination base station,
One of the features is that the handover source base station and the handover destination base station are provided with order correcting means for rearranging them in the correct order according to the sequence numbers assigned continuously.

  With this configuration, it is possible to correct the order of uplink data.

The base station of the present invention
Sequence number assigning means for assigning continuous sequence numbers to user data packets transmitted from a mobile station;
Transmission means for continuously transmitting user data packets assigned sequence numbers to the central node,
One feature of the sequence number assigning means is that, when the mobile station performs handover, information indicating the sequence number assigned to the user data packet in the handover source base station is transmitted to the handover destination base station.

  With this configuration, when the mobile station performs handover, for example, the sequence number of the transport network protocol can be notified from the handover source base station to the handover destination base station.

The handover control method of the present invention
A sequence number assigning step in which the handover source base station assigns a continuous sequence number to the user data packet transmitted from the mobile station;
A transmission step in which a handover source base station continuously transmits a user data packet assigned a sequence number to a central node;
A handover command transmission step in which a handover source base station transmits a handover command to the mobile station; and
One of the features is that the handover source base station has a sequence number transmission step of transmitting information indicating the sequence number assigned to the received user data packet to the handover destination base station.

  In this way, when the mobile station performs handover, for example, the sequence number of the transport network protocol can be notified from the handover source base station to the handover destination base station.

  According to the embodiment of the present invention, it is possible to realize a central node, a base station, and a handover control method that can correct the order of uplink data during handover.

It is explanatory drawing which shows the radio | wireless access network concerning one Example of this invention. It is a block diagram which shows the access gateway concerning one Example of this invention. It is a block diagram which shows the base station concerning one Example of this invention. It is explanatory drawing which shows FP data frame. It is explanatory drawing which shows operation | movement of the radio | wireless access network concerning one Example of this invention. It is a flowchart which shows operation | movement of the access gateway concerning one Example of this invention. It is a flowchart which shows operation | movement of the base station concerning one Example of this invention. It is a flowchart which shows operation | movement of the base station concerning one Example of this invention.

Explanation of symbols

100 wireless access network 200 core network 300, 300 ₁ , 300 ₂ , 300 ₃ access gateway (aGW)
400, 400 ₁ , 400 ₂ , 400 ₃ base stations (eNB: eNode B)
500 Mobile Station (UE: User Equipment)

Next, embodiments of the present invention will be described with reference to the drawings.
In all the drawings for explaining the embodiments, the same reference numerals are used for those having the same function, and repeated explanation is omitted.

  A radio access network according to an embodiment of the present invention will be described with reference to FIG.

A radio access network (RAN) according to this embodiment includes an access gateway (ACGW) 300 as a central node and a base station 400 connected under the access gateway 300, for example, a base station 400 _1. and a base station 400 _2, the mobile station 500. The access gateway 400 includes, for example, an MME (Mobility Management Entity) / SAE (System Architecture Evolution) gateway. In the radio access network 100 according to this embodiment, the base station 400 ₁ is a handover source of the old base station (source base station), the base station 400 ₂ is for the case where a handover target of a new base station (target base station) Description To do.

  In the present embodiment, description will be given focusing on a radio access network. However, the actual radio communication system includes components other than the radio access network 100, such as a core network (CN).

  In this embodiment, a case where two base stations are connected via the access gateway 300 will be described. However, the present invention should not be limited to this. For example, the access gateway 300 may be connected using a relay device such as a router or a switch.

  A TNL protocol for transferring user data is defined between the access gateway 300 and the base station 400, and a sequence number is assigned to each PDU in this TNL protocol PDU (Protocol Data Unit).

  Further, between the access gateway 300 and the base station 400, the user data packet is transferred using the data frame, and a protocol for forming the data frame, for example, a frame protocol (FP) is terminated. Is done.

  In the present embodiment, a case where a frame protocol is applied will be described as an example of a protocol terminated between the access gateway 300 and the base station 400, but should not be limited to this. For example, a protocol other than the frame protocol, for example, a GPRS tunneling protocol (GTP) may be used.

  Next, an access gateway 300 according to an embodiment of the present invention will be described with reference to FIG.

  The access gateway 300 according to the present embodiment includes a control unit 302, a wired transmission unit 304 as a transfer unit connected to the control unit 302, an FP unit 306, and a data storage order correction unit as a data storage unit and an order correction unit. 308. The FP unit 306 inputs and outputs data with the wired transmission unit 304 and the data storage order correction unit 308.

  The control unit 302 controls each functional entity included in the access gateway.

Wired transmission unit 306 receives the data frame of the handover source old base station 400 ₁ and the handover target new base station 400 ₂ from the frame protocol, and inputs to the FP unit 306. Also, the wired transmission unit 306 transmits a frame protocol data frame to an upper layer.

FP unit 304, processing of the radio access network specific data frame more input handover source old base station 400 ₁ and the handover destination of the new base station 400 ₂ from the frame protocol wired transmission unit 306, for example, confidential for security For the data unit subjected to the header compression, the sequence number stored in the FP data frame is referred to and stored in the data storage order correction unit 308 described later. Also, if the GTP is applied as described above, the sequence number stored from the new base station 400 ₂ in handover source of the old base station 400 ₁ and the handover destination that is input to the GTP PDU from the wired transmission unit 306 The data may be stored in a data storage order correction unit 308 to be described later.

  Further, for each PDU constituting the FP data frame, the sequence number stored in the PDU may be referred to and stored in the data storage order correction unit 308 described later.

Data storage order correcting unit 308 aligns the order of the data units from the source base station 400 ₁ and the target base station 400 ₂ that is transferred from the FP unit 306 in the sequence number order, and stores the aligned data. For example, the data storage order correction unit 410 includes a buffer, and a sequence number is designated in advance in the buffer (reordering buffer). The data storage order correction unit 410 stores the PF data frame in the corresponding sequence number in the reordering buffer. Further, the data storage order correction unit 308 transmits the input PF data frame to the upper layer.

  In the present embodiment, a case where the PDCP PDU and the data frame of the frame protocol are in one-to-one correspondence will be described. In this case, one frame protocol data frame is one PDCP PDU. Further, one FP data frame may be configured to include a plurality of PDUs. Further, when GTP is applied as described above, the IP packet and the GTP PDU may correspond to each other one-to-one, or the 1GTP PDU may be configured to include a plurality of IP packets. Good.

  Next, the base station 400 according to the present embodiment will be described with reference to FIG.

  The base station 400 according to this embodiment includes a control unit 402, a wired transmission unit 404 as a transmission unit connected to the control unit 402, a frame protocol (FP) unit 406 as a sequence number assignment unit, and a sequence number transfer unit 408. With. The FP unit 406 inputs and outputs data with the sequence number transfer unit 408 and the wired transmission unit 404. The sequence number transfer unit 408 performs data input / output with the wired transmission unit 404.

  The control unit 402 controls each functional entity included in the own base station. For example, the control unit 402 activates a handover procedure.

The wired transmission unit 404 inputs the PF data frame transferred from the mobile station 500 to the FP unit 406. Also, the wired transmission unit 404 transfers the information indicating the sequence number transferred from the sequence number notification unit 408 to the new base station that is the handover destination. Also, the wired transmission unit 404 inputs information indicating the sequence number notified from the source base station 400 ₁ to the FP unit 406.

The FP unit 406 assigns a continuous sequence number to each input FP data frame, stores information indicating the sequence number in the corresponding FP data frame, and accesses the FP data frame storing the sequence number. Transmit to the gateway 300. Also, FP unit 406, based on the information indicating the sequence number transmitted from the source base station 400 _1, the PF data frame sequence number of continuous sequence numbers sent from the source base station 400 _1, which is input And information indicating the sequence number is stored in the corresponding PF data frame. Further, the FP unit 406 inputs information indicating the sequence number assigned to the PF data frame to the sequence number notification unit 408. When GTP is applied as described above, a continuous sequence number is assigned to each input GTP PDU, information indicating the sequence number is stored in the corresponding GTP PDU, and the sequence number is stored. May be transmitted to the access gateway 300. Further, based on the information indicating the sequence number transmitted from the source base station 400 _1, the sequence number of continuous sequence numbers sent from the source base station 400 ₁ is assigned to each GTP PDU inputted, the sequence number May be stored in the corresponding GTP PDU. Further, information indicating the sequence number assigned to the GTP PDU may be input to the sequence number notification unit 408.

Sequence number notifying unit 408, based on the information indicating the sequence number that has been input, to the handover destination base station 400 _2, the information indicating the sequence number assigned to the mobile station transmits data packets, for example, the base station 400 ₁ the information indicating the next sequence number of the sequence number assigned in, notifies the target base station 400 _2. In this way, to the target base station 400 _2, it is possible to notify the sequence number to be assigned to the PF data frame.

  Next, the FP data frame according to the present embodiment will be described with reference to FIG.

  The FP data frame according to this embodiment includes a header part, a payload part, and a trailer part.

  The header part includes at least a sequence number. In addition to the sequence number, the header part may be assigned to spare bits assuming base station 400 priority information for recognizing the priority of user data and future function expansion. For example, a priority control flag such as an SAE Access Bearer identifier is stored in the header portion.

  The payload portion includes at least one PDCP PDU.

  The trailer unit includes a CRC (Cyclic Redundancy Check) for checking an error in the FP data frame. Further, the trailer unit may be assigned to spare bits assuming future function expansion.

  Here, the configuration of the data frame described in the present embodiment is an example, and the present invention is not limited to this.

Further, when GTP is applied as described above, the header part includes at least a sequence number. In addition to the sequence number, the base station 400 may include a TE-ID for identifying a bearer in the header part. It is good also as a structure which can expand a header.
The payload portion includes at least one IP packet.

  Next, the operation of the access gateway 300 according to the present embodiment will be described with reference to FIG.

As an example, the case where the mobile station 500 performs handover from the area covered by the source base station 400 ₁ to the area covered by the target base station 400 _2.

For example, the mobile station 500, to the source base station 400 _1, after transmitting the FP to the sequence number (SN) corresponding to the # 5 and # 1, handover to the area covered by the target base station 400 ₂ (1 ).

In this case, the source base station 400 ₁ is assigned the # 1 as the sequence number in the FP to # 5, and stores the FP to the appropriate information indicating the sequence number, and transmits to the access gateway 300 (2). Also, the source base station 400 ₁ sends information indicating a sequence number assigned to the data packet transmitted from the mobile station to the handover destination base station 400 ₂ to the target base station 400 ₂ , for example, the source base station 400 ₁ the information indicating the next sequence number of the assigned sequence number, and notifies the target base station 400 ₂ (3). For example, information indicating the sequence number is included in the information notified by context transfer.

Mobile station 500, to the target base station 400 ₂ transmits the FP to the sequence number corresponding to the subsequent # 6.

The target base station 400 _2, based on the information indicating the notified sequence number, the sequence number of continuous sequence numbers assigned in the source base station, assigned to the received FP, information indicating the sequence number Store in the corresponding FP and send. For example, target base station 400 _2, based on the information indicating the notified sequence number, assigns a # 6 or later as the sequence number in FP, and transmits to the access gateway 300 (4).

Access gateway 300 receives the FP transmitted from the source base station 400 ₁ and the target base station 400 _2, stored in the FP, the source base station and the target base station, continuously assigned sequence number Based on this, the order of the FP is corrected. When FPs corresponding to all the sequence numbers are received, they are transmitted to the upper layer (5).

In this case, for example, the line is congested between the source base station 400 ₁ and the access gateway 300, from FP (PDU) corresponding to # 5 transmitted from the source base station 400 _1, the target base station 400 ₂ May be received by the access node 300 first. In this case, the access gateway 300 waits for a predetermined time until a PDU corresponding to a sequence number that has not been received is received. If the PDU is not received even after a predetermined time has elapsed, it is transmitted to the upper layer as it is.

  Next, the operation of the access gateway 300 will be described with reference to FIG.

FP unit 306 of the access gateway 300 determines whether it has received the FP data frame from the source base station 400 ₁ and the target base station 400 ₂ (step S602).

If the source base station 400 ₁ and the target base station 400 ₂ has not received the FP data frame (Step S602: NO), the process ends.

On the other hand, when receiving the FP data frame from the source base station 400 ₁ and the target base station 400 ₂ (step S602: YES), FP 306 to the appropriate sequence number in the reordering buffer of the data storage reordering unit 308, PF The PDU included in the data frame is stored (step S604). Next, the data storage order correction unit 308 determines whether there is a PDU that is not stored in the sequence number in the reordering buffer (step S606).

  If there is a PDU that is not stored in the sequence number in the reordering buffer (step S606: YES), the data storage order correction unit 308 activates, for example, a timer and determines whether or not a predetermined time has elapsed ( Step S608).

  If the predetermined time has not elapsed (step S608: NO), the process returns to step S606.

  On the other hand, when the predetermined time has elapsed (step S608: YES) and when it is determined in step S606 that there is no PDU not stored in the sequence number in the ordering buffer (step S606: NO), the data storage order correction The unit 308 transmits the stored PDU to the upper layer (step S510).

  In this embodiment, the case where an FP data frame is created for each protocol data unit has been described as an example, but the present invention is not limited to this.

  Next, the operation of the base station 400 according to the present embodiment will be described with reference to FIG. 7 and FIG.

Here, the operation will be described separately for the old base station 400 ₁ that is the handover source and the new base station 400 ₂ that is the handover destination.

The handover source operation flow of the old base station 400 ₁ is described with reference to FIG.

Control unit 402 of the base station 400 ₁ performs a predetermined process based on the measurement report transmitted from the mobile station, to the mobile station 500 transmits a handover command (HO Command) (step S702). As a result, the mobile station 500 performs a handover.

  Next, the FP unit 406 assigns a continuous sequence number to the PDUs transmitted from the mobile station 500, and stores information indicating the sequence number in the corresponding PDU (step S704).

  Next, the FP unit 406 creates an FP data frame from the PDU storing the sequence number and transmits it to the access gateway 300 (step S706). Further, as described above, when GTP is applied, a GTP PDU may be created from user data storing a sequence number.

  Next, the FP unit 406 determines whether or not sequence number assignment has been completed for the received PDU (step S708).

  If the sequence number assignment is not completed for the received PDU (step S708: NO), the process returns to step S704.

On the other hand, when sequence number assignment has been completed for the received PDU (step S708: YES), the FP unit 406 inputs information indicating the assigned sequence number to the sequence number notification unit 408. Sequence number notifying unit 408, based on the information indicating the sequence number that has been input, to the handover destination base station 400 _2, the information indicating the sequence number assigned to the mobile station 500 transmits data packets, for example, its own source base station the information indicating the next sequence number of the sequence number 400 ₁ is assigned, and notifies the target base station 400 ₂ (step S710).

Next, the operation flow of the new base station 400 ₂ in handover destination, will be described with reference to FIG.

  The control unit 402 determines whether or not a channel setting completion notification is notified from the mobile station 500 (step S802).

  When the channel setting completion notification is not notified from the mobile station 500 (step S802: NO), the process returns to step S802.

On the other hand, if the channel setting completion notification from the mobile station 500 has been notified (Step S802: YES), FP unit 406 determines whether it has received the information indicating the sequence number from the source base station 400 ₁ (step S804 ).

If the source base station 400 ₁ has not received the information indicating the sequence number (step S804: NO), the flow returns to step S804.

On the other hand, when receiving the information indicating the sequence number from the source base station 400 ₁ (step S804: YES), FP unit 406, based on the information indicating the sequence number for the received PDU, assigns a sequence number ( Step S806). For example, FP 406, based on the information indicating the sequence number from the source base station 400 _1, continuously the user data packet transmitted from the mobile station, the sequence number assigned in the source base station 400 ₁ A sequence number is assigned, and information indicating the sequence number is stored in the corresponding user data packet.

  Next, the FP unit 406 creates an FP data frame from the PDU storing the sequence number and transmits it to the access gateway (step S808).

  According to the embodiment of the present invention, when a mobile station performs a handover, the mobile station transmits the uplink data to the central node by notifying the sequence number of the transport network protocol from the handover source base station to the handover destination base station. You can correct the order.

  In addition, since the data can be transferred to the upper protocol in the correct order, deterioration of the upper characteristics can be suppressed.

  This international application claims priority based on Japanese Patent Application No. 2006-089425 filed on Mar. 28, 2006, and the entire contents of 2006-089425 are incorporated herein by reference.

  The central node, base station, and handover control method according to the present invention can be applied to a radio communication system.

Claims (10)

Order correction means for transmitting data from the handover source base station or the handover destination base station according to the handover of the mobile station, and rearranging them in the correct order according to the sequence numbers continuously assigned in the handover source base station and the handover destination base station. ;
A central node characterized by comprising: In the central node according to claim 1:
The central node, wherein the sequence number is a sequence number assigned to a data unit of a frame protocol defined with the base station. In the central node according to claim 1:
The sequence number is a sequence number assigned to a data unit of GTP-u defined with the base station. Sequence number assigning means for assigning consecutive sequence numbers to user data packets transmitted from a mobile station;
A transmission means for continuously transmitting user data packets assigned sequence numbers to the central node;
With
When the mobile station performs handover, the sequence number assigning means transmits information indicating the sequence number assigned to the user data packet in the handover source base station to the handover destination base station. In the base station according to claim 4:
The base station characterized in that the information indicating the sequence number is a sequence number next to the sequence number assigned by the handover source base station. In the base station according to claim 4,
The sequence number assigning means is continuous with the sequence number assigned in the handover source base station for the user data packet transmitted from the mobile station based on the information indicating the sequence number from the handover source base station. A base station characterized by assigning a sequence number. In the base station according to claim 4:
The base station, wherein the sequence number is a sequence number assigned to a data unit of a frame protocol defined between the base station and the base station. In the base station according to claim 4:
The base station is characterized in that the sequence number is a sequence number assigned to a GTP-u data unit defined between the base station and the base station. A sequence number assigning step in which the handover source base station assigns a continuous sequence number to the user data packet transmitted from the mobile station;
A transmitting step in which the handover source base station continuously transmits user data packets assigned sequence numbers to the central node;
A handover command transmission step in which a handover source base station transmits a handover command to the mobile station;
A sequence number transmission step in which the handover source base station transmits information indicating the sequence number assigned to the received user data packet to the handover destination base station;
A handover control method comprising: In the handover control method according to claim 9,
Based on the information indicating the sequence number transmitted from the handover source base station, the handover destination base station sets the sequence number assigned in the handover source base station to the user data packet transmitted from the mobile station. A sequence number assigning step for assigning consecutive sequence numbers;
A transmitting step in which a handover destination base station continuously transmits user data packets to which sequence numbers are assigned to the central node;
An order correction step in which the central node rearranges the user data packets transmitted from the handover source base station or the handover destination base station in the correct order according to the sequence number assigned continuously;
A handover control method comprising:

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