JPWO2007105625A1 - Base station and handover control method - Google Patents

Abstract

Transfer destination determining means for selecting a plurality of transfer destination base stations for transferring user data to be transmitted to the mobile station to the base station, and transferring the user data to the transfer destination base station determined by the transfer destination determining means And the data transfer means is achieved by transferring the user data to the transfer destination base station at the same time.

Description

  The present invention relates to a handover control technique for transferring user data when a mobile station performs a handover, and more particularly to a base station and a handover control method for transferring user data in a point-to-multipoint manner.

  In a system to which IMT-2000 (International Mobile Telecommunication-2000) is applied, a mobile station (UE: User Equipment) moves, and is connected to two radios connected to the same service GPRS Support Node (SGSN: Service GPRS Support Node). When a handover across a network controller (RNC: Radio Network Controller) is performed, a procedure called “SRNS Relocation (SRNS Relocation)” is activated.

  In the “SRNS Relocation” procedure, the packet data convergence protocol (PDCP) terminated between the UE and the RNC is passed through an upper layer (RRC: Radio Resource Control) between the UE and the RNC. The sequence number is exchanged, and the protocol state is adjusted so that there is no duplicate transmission / reception at the destination. Also included is a function to transfer PDCP PDUs from the source RNC to the target RNC.

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

  In a system to which IMT-2000 is applied, a handover (Handover) across RNCs occurs only infrequently. Therefore, it is only necessary to transfer user data only to the target RNC. In an ordinary hanover, for example, Inter-NodeB, loss and duplication are avoided by a radio layer 2 protocol (RLC: Radio Link Control), and data transfer is not performed as in Relocation.

  However, “E-UTRAN”, which has been discussed as an enhancement technology for a system to which IMT-2000 is applied, includes requirements regarding moving speed, and these requirements include 120 km / h-350 km / h ( According to the frequency band, support up to 500 km / h) is mentioned. In addition, there is a high architectural possibility that the wireless layer 2 protocol is terminated between the mobile station and the base station, and data transfer is indispensable even in a normal Inter-eNodeB Handover because it is lossless.

  Even when a UE performing data communication, for example, E-mail, the Internet, performs handover at a high speed environment such as 350 km / h on the Shinkansen, even if data is transferred from the source base station to the target base station, There is a high possibility of handover to the next base station before all the data has been transferred, and data that has not been transferred will cause data loss, such as a decrease in the throughput of the upper layer (TCP: transmission control protocol). There is a risk of problems.

  Therefore, the present invention has been made in view of the above-described problems, and it is an object of the present invention to provide a base station and a handover control method that can provide lossless handover even during high-speed movement.

In order to solve the above problems, the base station of the present invention
Transfer destination determining means for selecting a plurality of transfer destination base stations for transferring user data to be transmitted to the mobile station;
Data transfer means for transferring the user data to the transfer destination base station determined by the transfer destination determination means,
The data transfer means transfers the user data simultaneously to the transfer destination base station.

  With this configuration, data loss can be prevented even when handover is performed before data transfer is completed.

Further, the handover control method of the present invention includes:
A transfer destination determining step of selecting a plurality of transfer destination base stations to transfer user data to be transmitted to the mobile station;
One of the characteristics is that it includes a data transfer step of simultaneously transferring the user data to the transfer destination base station determined in the transfer destination determination step.

  In this way, data loss can be prevented even when handover is performed before data transfer is completed.

  According to the embodiments of the present invention, it is possible to realize a base station and a handover control method that can provide lossless handover even during high-speed movement.

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 base station concerning one Example of this invention. It is a flowchart 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 source base station concerning one Example of this invention. It is a flowchart which shows operation | movement of the target base station concerning one Example of this invention. It is a flowchart 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 source base station concerning one Example of this invention. It is a flowchart 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 source base station concerning one Example of this invention. It is a flowchart which shows operation | movement of the target base station concerning one Example of this invention. It is a flowchart 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 source 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.

  In this embodiment, as an example, E-UTRA (Evolved-UMTS Terrestrial Radio Access) and E-UTRAN (Evolved-UMTS Terrestrial Radio Access Network) are being standardized by 3GPP.

The radio access network (E-UTRAN) 100 according to the present embodiment includes a core network 200 and an access gateway (aGW) 300 (300 ₁ , 300 that functions as a gateway between the core network 200 and the radio access network. ₂ , 300 ₃ ), a plurality of base stations (eNode B) 400 (400 ₁ , 400 ₂ , 400 ₃ ) connected to the access gateway 300, and a mobile station (UE) 500.

  The core network 200 includes, for example, an IP backbone 250.

  The access gateway 300 aims to drastically shorten the connection time and reduce the latency, and the gateway GPRS support node (GGSN: Gateway GPRS Support Node), SGSN (Service GPRS Support Node), and RNC in IMT-2000. A node that integrates at least some of the functions. Therefore, the access gateway 300 is a node that has both the function of the core network 200 and the function of the radio access network 100.

  Base station 400 is a node that integrates at least part of functions of RNC and NodeB in IMT-2000 with the aim of dramatically reducing connection time and latency. Here, in the eNodeB, a MAC (Media Access Control) protocol, an RLC (Radio Link Control) protocol, and the like are implemented as a U-plane function, and an RRC (Radio Resource Control) protocol is implemented as a C-plane function.

  Here, E-UTRAN has been described as an example of a radio access network. However, the present invention is not limited to this, and other system architecture configurations may be used.

  When the mobile station 500 performs handover, buffered user data, for example, an outer ARQ service data unit (Outer ARQ SDU (Service Data Unit)), that is, untransmitted data and unconfirmed delivery data, at the Outer ARQ function unit of the source NB A function capable of forwarding to the target NB is implemented in the NB. In addition, a transmission path for forwarding data is set.

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

  The base station 400 according to the present embodiment includes a control unit 402, a data storage unit 404 connected to the control unit 402, a data transfer unit 406, a wired transmission unit 408, a movement speed measurement unit 410 as a movement information collection unit, and a transfer A data transfer destination determination unit 412 and a wireless transmission unit 414 as destination determination means are provided.

  The control unit 402 controls each functional entity included in the Node B, and controls the operation of the entire Node B. Detailed functions will be described later.

  The wired transmission unit 408 receives the user data transferred from the access gateway 300 and transfers the user data to the data storage unit 404. Further, the wired transmission unit 408 exchanges control signals for handover via the interface between base stations. Also, the wired transmission unit 408 transfers user data stored in the data storage unit 404 to a plurality of transfer destinations via an interface between base stations.

  The wireless transmission unit 414 acquires a measurement report (communication quality report) reported from the mobile station.

  The data storage unit 404 stores user data transmitted to the user transmitted from the access gateway 300.

  When the handover procedure is activated, the data transfer unit 406 transfers the user data stored in the data storage unit 404 to the transfer destination base station determined by the data transfer destination determination unit 412.

  The data transfer destination determination unit 412 determines a transfer destination for transferring user data stored in the data storage unit 404 at the time of handover. For example, the data transfer destination determination unit 412 includes a base station having the best communication quality among base stations that can secure resources based on a measurement report reported from the mobile station, and base stations arranged around the base station. Stations are grouped (grouped) to be a transfer destination base station. That is, the data transfer destination determination unit 412 always includes a base station (cell) with the best communication quality and a base station (cell) that can secure resources based on the measurement report reported from the mobile station. Group base stations around the base station.

  Further, the data transfer destination determination unit 412 may estimate the moving direction of the mobile station from the passage history of the mobile station in the past base station, and group and select the base stations in the moving direction. Alternatively, in an environment where the moving direction is limited to some extent, such as a train or an automobile on a highway, base stations in the moving direction may be grouped. For example, in the case of a train, the mobile station may notify the NW that it is in a train. (At that time, in order to make the mobile station recognize that it is in the train, it may be notified by the notification information.) As a result, the data transfer destination determination unit 412 estimates the moving direction of the mobile station and moves the moving direction. Group and select base stations in

  The grouping method assumed in the present embodiment is not limited to these, and grouping may be performed based on other rules.

  In addition, the data transfer destination determination unit 412 determines the number of base stations that transfer user data, that is, the number of base stations that perform grouping, based on at least one of the transfer capability of user data and the transfer capability of the connected transmission path. Decide. For example, the data transfer destination determination unit 412 determines the number of base stations that transfer user data based on at least one of the CPU load, the amount of stored data, and the transmission path bandwidth.

  The moving speed measurement unit 410 acquires the moving speed of the mobile station from another base station via a wire, or estimates information related to the movement of the mobile station such as the moving speed of the mobile station via wireless. The movement speed may be estimated from a frequency at which the mobile station hands over the base station or a Doppler frequency (fd). It is not limited to the estimation method other than this, Other estimation methods may be used. In addition, the moving speed measuring unit 410 notifies the data transfer destination determining unit 412 of information relating to the movement of the mobile station, for example, information indicating the moving speed. In this case, the data transfer destination determination unit 412 determines whether or not the moving speed exceeds a threshold defined in advance by the system, based on the moving speed notified by the moving speed measuring unit 410. If the moving speed does not exceed the threshold value, the data transfer destination determination unit 412 determines the base station to transfer data as the handover destination base station.

  Next, a handover sequence in the radio access network 100 according to the present embodiment will be described with reference to FIG.

In the present embodiment, the mobile station 500, the case of handover from the source base station 400 ₁ connected to the access gateway 300 ₁ subordinate to the target base station 400 _2.

Mobile station 500, as the source base station 400 ₁ can select a proper handover destination base station, information indicating the communication quality of the base station as a handover destination candidate for the source base station 400 ₁ is stored measurement A report (Measurement report) is reported (step S302).

The source base station 400 _1, based on a measurement report from the mobile station 500 selects an appropriate target base station to check the availability of resources (HO decision) (step S304). For example, the base station 400 ₂ is selected as the target base station.

Next, the source base station 400 _1, the context, for example, to transfer the C-plane-related information to the base station 400 ₂ (HO request) (step S306).

Then, the base station 400 _2, based on QoS information included in the context transferred from the source base station 400 ₁ allocates resources (Resource allocation). The target base station 400 _2, the reservation of the allocated resources (step S308).

Then, _second base station 400, if the reservation of necessary resources succeeds, notifies the source base station 400 _1, a context transfer response indicating that preparation is completed for the handover (HO response) (Step S310).

Here, the base station 400 _2, when the necessary resources can not be secured, the source base station 400 _1, the resource to the mobile station 500 to notify that can not be secured.

When the source base station 400 ₁ receives the context transfer response, the source base station 400 ₁ measures or estimates the moving speed of the mobile station 500 to be handed over, and is higher than the moving speed specified in advance by the system, that is, is equal to or higher than a predetermined threshold. In such a case, grouping of the transfer destination base stations is performed. The source base station 400 _1, the grouping candidate, always include a target base station selected to the handover destination, otherwise, of the transfer capacity of the transmission path that the user data transfer capability and base station of the base station is connected Based on at least one, a plurality of candidates are selected from the measurement report of the mobile station (User mobility analysis).

Further, the source base station 400 ₁ determines the base station 400 ₂ handover destination base station, i.e. a target base station (forwarding NBs decision) (step S312).

On the other hand, when the source base station 400 ₁ is notified that the resources from the base station 400 ₂ to the mobile station 500 cannot be secured, the source base station 400 ₁ confirms the availability of resources based on the measurement report from the mobile station 500. Choose another appropriate target base station. That is, the same operation as in step S304 is performed.

Next, the source base station 400 ₁ receives ACK (Acknowledge) from the mobile station 500 as user data to be transferred to the mobile station 500 to a plurality of grouped base stations including the target base station 400 _2. received from the user data and the access gateway 300 ₁ not, still starts transferring the user data that is not transmitted to the mobile station 500 (start user data forwarding) (step S314, the step S316, step S318).

The source base station 400 ₁ notifies the mobile station 500 of cell-specific information necessary for re-establishing a radio channel with the target base station 400 ₂ , that is, cell-specific information (HO Command) (step S320). .

Next, the mobile station 500 receives the synchronization channel from the target base station 400 _2, to establish a target base station 400 ₂ and the radio synchronization, sets a radio channel (L1 / L2 HO Rx SCH from tNB) ( step S322 ).

After setting the radio channel with the target base station 400 _2, the mobile station 500 to notify that the handover to the target base station 400 ₂ has been completed (HO complete) (step S324).

Next, target base station 400 ₂ notifies handover confirmation completion notification indicating that the handover is completed to the source base station 400 ₁ (HO confirm) (step S326). Step S326 is preferably present, but may or may not be present.

Next, target base station 400 ₂ transmits a path update request (Path: switch) to the access gateway 300 ₁ (step S328). The access gateway 300 ₁ updates the destination from the source base station 400 ₁ to the target base station 400 ₂ .

The source base station 400 _1, discards the data stored in the data storage unit 404 (step S330).

Next, the access gateway 300 ₁ releases, that is, releases the signaling between the base station and the access gateway to the source base station 400 ₁ (step S332).

  Next, the operation of the base station 400 in the radio access network 100 according to the present embodiment will be described.

  In this embodiment, the operation will be described separately for a source base station and a target base station.

  The operation of the source base station will be described with reference to FIG.

The source base station 400 _1, the control unit 402 determines whether it has received a a measurement report from the mobile station 500 (step S402).

  When determining that the measurement report is not received from the mobile station 500 (step S402: NO), the control unit 402 ends the process.

  When it is determined that the measurement report has been received from the mobile station 500 (step S402: YES), the control unit 402 is information indicating the communication quality of the neighboring base stations (cells) stored in the measurement report reported from the mobile station 500. Based on the above, the base station with the best communication quality is selected as the candidate for the handover destination base station, the mobile station context is transferred to the base station selected as the candidate for the handover destination, and the resource reservation of the handover destination candidate base station is made. This is performed (step S404).

  Next, the control unit 402 determines whether or not a resource reservation completion response, for example, a context transfer response has been received from the base station selected as the handover destination candidate (step S406).

  If no resource reservation completion response has been received (step S406: NO), the process returns to step S404.

  On the other hand, when the resource reservation confirmation response is received (step S406: YES), the moving speed measurement unit 410 acquires the moving speed of the mobile station 500 via radio. The data transfer destination determination unit 412 analyzes the moving speed, and sets a plurality of target base stations when the moving speed exceeds a predetermined moving speed, that is, when the moving speed is equal to or more than a threshold value determined in advance by the system. I do. The data transfer unit 406 starts data transfer of user data to the target base station set by the data transfer destination determination unit 412 (step S408). Here, the moving speed measuring unit 410 may acquire the moving speed of the mobile station 500 via a wire.

After starting the transfer of user data to the target base station group, the control unit 402 transmits a radio channel switching request to the mobile station 500. For example, the control unit 402, the cell-specific information required to re-set the target base station 400 ₂ and the radio channel to the mobile station 500, that is, it notifies the cell-specific information (step S410).

  Next, the control unit 402 determines whether a handover completion confirmation response has been received from the target base station (step S412).

  If the handover completion confirmation response has not been received (step S412: NO), the process returns to step S410.

  On the other hand, when the handover completion confirmation response is received (step S412: YES), the user data stored locally is discarded (step S414).

  Next, the control unit 402 determines whether or not a path release notification has been received from the access gateway 300 (step S416).

  If no path release notification has been received (step S416: NO), the process returns to step S414.

  On the other hand, when the path release notification is received (step S416: YES), the processing ends normally.

  The operation of the target base station will be described with reference to FIG.

Target base station, the control unit 402 determines whether it has received a resource securing request from the source base station 400 ₁ (step S502).

  If a resource securing request has not been received (step S502: NO), the process ends.

On the other hand, when receiving the resource reservation request from the source base station 400 ₁ (step S502: YES), the target base station based on the QoS information in a context included in the resource allocation request, it performs resource reservation, the source base station to 400 _1, and transmits the resource reservation completion response notifying that a resource reservation is completed, for example, a context transfer response (step S504).

  Next, the control unit 402 determines whether or not a wireless channel switching completion notification, for example, HO complete has been received from the mobile station 500 (step S506).

  When the wireless channel switching completion notification has not been received from the mobile station 500 (step S506: NO), the process ends.

On the other hand, when the wireless channel switching completion notification is received from the mobile station 500 (step S506: YES), the control unit 402 transmits a path switching request, for example, a path update request (Path switch) to the access gateway 300. The control unit 402 to the source base station 400 ₁ transmits a handover confirmation completion notification (step S508). Next, the process ends normally.

  Next, a radio access network according to another embodiment of the present invention will be described.

  The configuration of the radio access network according to this embodiment is the same as that of the radio access network described with reference to FIG.

  Since the configuration of the base station according to the present embodiment is the same as the base station described with reference to FIG. 2, the description thereof is omitted.

  Next, a handover sequence in the radio access network 100 according to the present embodiment will be described with reference to FIG.

In the present embodiment, the mobile station 500, the case of handover from the source base station 400 ₁ connected to the access gateway 300 ₁ subordinate to the target base station 400 _2.

Mobile station 500, as the source base station 400 ₁ can select a proper handover destination base station, information indicating the communication quality of the base station as a handover destination candidate for the source base station 400 ₁ is stored measurement A report is reported (step S602).

Next, the source base station 400 ₁ measures or estimates the moving speed of the mobile station 500 to be handed over, and when it is faster than the moving speed specified in advance by the system, that is, when it is equal to or higher than a predetermined threshold, Group the base candidates that are the previous candidates. The source base station 400 _1, the grouping candidate, based on at least one of the transfer capacity of the transmission path that the user data transfer capability and base station of the base station is connected, a plurality of base station as a handover destination candidate Is selected based on the measurement report of the mobile station (User mobility analysis & HO decision) (step S604). For example, base stations 400 _{2 to} 400 _{m are} selected as base stations that are candidates for the handover destination.

Next, the source base station 400 _1, the context, for example, transfers C-plane-related information to the handover destination candidate to become the base station _{400 2 ~400 m (HO request)} ( step S606, the step S608). For example, the source base station 400 _{1 transfers} the context by multicast to the base stations 400 _{2 to} 400 _{m that} are candidates for the handover destination.

Next, the base stations 400 _{2 to} 400 _{m that} are candidate handover destinations allocate resources based on the QoS information included in the context transferred from the source base station 400 ₁ (Resource allocation). Further, 400 _{2 to} 400 _{m that} are candidates for the handover destination reserve the allocated resources (steps S610 and S612).

Next, when the necessary resources are successfully reserved, the base stations 400 _{2 to} 400 _m notify the source base station 400 ₁ of a context transfer response indicating that preparation for handover is completed ( HO response) (step S614, step S616).

Here, when the necessary resources cannot be secured, the base stations 400 _{2 to} 400 _m notify the source base station 400 ₁ that the resources to the mobile station 500 cannot be secured.

The source base station 400 _1, when the resource from the base station 400 ₂ to the mobile station 500 is informed that can not be ensured, based on the measurement report from the mobile station 500, suitable to check the availability of the resource A base station that is another candidate for the handover destination is selected. That is, the same operation as in step S604 is performed.

Next, the source base station 400 ₁ receives ACK (Acknowledge) from the mobile station 500 as user data to be transferred to the mobile station 500 to a plurality of grouped base stations including the target base station 400 _2. received from the user data and the access gateway 300 ₁ not, still starts transferring the user data that is not transmitted to the mobile station 500 (start user data forwarding) (step S618, step S620, step S622). For example, the source base station 400 ₁ multicasts user data to a plurality of grouped base stations including the target base station 400 ₂ by multicast.

The source base station 400 ₁ notifies the mobile station 500 of cell-specific information necessary for re-establishing a radio link with the target base station 400 ₂ , that is, cell-specific information (HO Command) (step S624). .

Next, the mobile station 500 receives the synchronization channel from the target base station 400 _2, to establish a target base station 400 ₂ and the radio synchronization, sets a radio channel (L1 / L2 HO Rx SCH from tNB) ( step S626 ).

After setting the radio channel with the target base station 400 _2, the mobile station 500 to notify that the handover to the target base station 400 ₂ has been completed (HO complete) (step S628).

Next, target base station 400 ₂ notifies handover confirmation completion notification indicating that the handover is completed to the source base station 400 ₁ (HO confirm) (step S630).

Next, target base station 400 ₂ transmits a path update request (Path: switch) to the access gateway 300 ₁ (step S632). The access gateway 300 ₁ updates the destination from the source base station 400 ₁ to the target base station 400 ₂ .

The source base station 400 _1, discards the data stored in the data storage unit 404 (step S634).

Next, the access gateway 300 ₁ releases, that is, releases the signaling between the base station and the access gateway to the source base station 400 ₁ (step S636).

  Next, the operation of the base station 400 in the radio access network 100 according to the present embodiment will be described.

  In this embodiment, the operation of the target base station is the same as that described with reference to FIG. 5, and therefore the operation of the source base station will be described with reference to FIG.

The source base station 400 _1, the control unit 402 determines whether it has received a a measurement report from the mobile station 500 (step S702).

  If it is determined that no measurement report has been received from the mobile station 500 (step S702: NO), the process ends.

  When it is determined that the measurement report has been received from the mobile station 500 (step S702: YES), the moving speed measurement unit 410 acquires the moving speed of the mobile station 500 via radio (step S704). Further, the moving speed measuring unit 410 may acquire the moving speed of the mobile station 500 via a wire.

The data transfer destination determination unit 412 analyzes the moving speed and determines whether or not the moving speed exceeds a predetermined moving speed, that is, whether or not the moving speed is equal to or higher than a threshold value determined in advance by the system (step S706).
If the moving speed is equal to or higher than a threshold value determined in advance by the system (step S706: YES), the data transfer destination determining unit 412 communicates with neighboring base stations (cells) stored in the measurement report reported from the mobile station 500. Based on the information indicating quality, a plurality of target base stations are set and grouping is performed (step S708).

  On the other hand, when the moving speed is not equal to or higher than the threshold value determined in advance by the system (step S706: NO), the data transfer destination determining unit 412 stores the data of the neighboring base stations (cells) stored in the measurement report reported from the mobile station 500. Based on the information indicating the communication quality, a target base station is set (step S710).

  Next, the control unit 420 transfers the mobile station context to the base station selected as the handover destination candidate, for example, via the wired transmission unit 408, and performs resource reservation for the handover destination candidate base station (step S712). .

  Next, the control unit 402 determines whether or not a resource reservation completion response has been received from the base station selected as the handover destination candidate (step S714).

  If no resource reservation completion response has been received (step S714: NO), the process returns to step S712.

  On the other hand, when the resource reservation confirmation response is received (step S714: YES), the data transfer unit 406 starts data transfer of user data to the target base station set by the data transfer destination determination unit 412 (step S716).

  After starting the transfer of user data to the target base station group, the control unit 402 transmits a radio channel switching request to the mobile station 500 (step S718).

  Next, the control unit 402 determines whether or not a handover completion confirmation response has been received from the target base station (step S720).

  When the handover completion confirmation response has not been received (step S720: NO), the process returns to step S718.

  On the other hand, when the handover completion confirmation response is received (step S720: YES), the user data stored locally is discarded (step S722).

  Next, the control unit 402 determines whether or not a path release notification has been received from the access gateway 300 (step S724).

  When the path release notification has not been received (step S724: NO), the process returns to step S722.

  On the other hand, when the path release notification is received (step S724: YES), the processing ends normally.

  A radio access network according to another embodiment of the present invention will be described.

  The configuration of the radio access network according to the present embodiment is the same as the configuration described with reference to FIG.

  Base station 400 is a node that integrates at least part of functions of RNC and NodeB in IMT-2000 with the aim of dramatically reducing connection time and latency. Here, in the eNodeB, MAC (Media Access Control) protocol, RLC (Radio Link Control) protocol, PDCP (Packet Data Convergence Protocol), etc. are implemented as U plane functions, and RRC (Radio Resource Control) as C plane functions. ) Protocol, S1-AP (S1-Application Part), X2-AP (X2-Application Part) are implemented.

  When the mobile station 500 is handed over, the user data buffered by the PDCP function unit of the source NB, for example, service data unit (SDU), that is, untransmitted data and unconfirmed delivery data, are transferred to the target NB. A function capable of forwarding is implemented in the NB. In addition, a transmission path for forwarding data is set. This transmission path may be wireless or wired.

  The configuration of the base station 400 according to the present embodiment is the same as the configuration described with reference to FIG.

  The control unit 402 recognizes the information indicating the completion of handover transmitted from the mobile station 500, and confirms that the handover has been completed in order to make a request to change the transfer path to the access gateway 300 based on the information. Notification of handover completion to be notified is performed. Further, the control unit 402 notifies the handover source base station that the handover has been completed by a resource release message.

  Next, a handover sequence in the radio access network 100 according to the present embodiment will be described with reference to FIG.

In the present embodiment, the mobile station 500, the case of handover from the source base station 400 ₁ connected to the access gateway 300 ₁ subordinate to the target base station 400 _2.

Mobile station 500, as the source base station 400 ₁ can select a proper handover destination base station, information indicating the communication quality of the base station as a handover destination candidate for the source base station 400 ₁ is stored measurement A report (Measurement report) is reported (step S802).

The source base station 400 _1, based on a measurement report from the mobile station 500 selects an appropriate target base station to check the availability of resources (HO decision) (step S804). For example, the base station 400 ₂ is selected as the target base station.

Next, the source base station 400 _1, the context, for example, to transfer the C-plane-related information to the base station 400 ₂ (HO request) (step S806).

Then, the base station 400 _2, based on QoS information included in the context transferred from the source base station 400 ₁ allocates resources (Control Admission). The target base station 400 _2, the reservation of the allocated resources (step S808).

Then, the base station 400 _2, if the reservation of necessary resources succeeds, the source base station 400 _1, the cell-specific information required to re-set the radio channel, i.e. the cell specific information Including a handover request acknowledgment (HO request Ack) indicating that preparation for handover has been completed (step S810).

Here, the base station 400 _2, when the necessary resources can not be secured, the source base station 400 _1, the resource to the mobile station 500 to notify that can not be secured.

When the source base station 400 ₁ receives the handover request acknowledgment, the source base station 400 ₁ measures or estimates the moving speed of the mobile station 500 that is scheduled to be handed over. In some cases, transfer destination base stations are grouped. The source base station 400 _1, the grouping candidate, always include a target base station selected to the handover destination, otherwise, of the transfer capacity of the transmission path that the user data transfer capability and base station of the base station is connected Based on at least one, a plurality of candidates are selected from the measurement report of the mobile station (User mobility analysis). Further, the source base station 400 ₁ determines the base station 400 ₂ handover destination base station, i.e. a target base station (forwarding NBs decision) (step S812).

On the other hand, when the source base station 400 ₁ is notified that the resources from the base station 400 ₂ to the mobile station 500 cannot be secured, the source base station 400 ₁ confirms the availability of resources based on the measurement report from the mobile station 500. Choose another appropriate target base station. That is, the same operation as in step S804 is performed.

Next, the source base station 400 ₁ receives ACK (Acknowledge) from the mobile station 500 as user data to be transferred to the mobile station 500 to a plurality of grouped base stations including the target base station 400 _2. received from the user data and the access gateway 300 ₁ not, still starts transferring the user data that is not transmitted to the mobile station 500 (start user data forwarding) (step S814, step S 816, step S818).

The source base station 400 ₁ notifies the mobile station 500 of cell specific information necessary for resetting the radio channel with the target base station 400 ₂ , that is, cell-specific information (HO Command) (step S 820). .

Next, the mobile station 500 receives the synchronization channel from the target base station 400 _2, to establish a target base station 400 ₂ and the radio synchronization, sets a radio channel (L1 / L2 HO Rx SCH from tNB) ( step S822 ).

After setting the wireless channel with the target base station 400 _2, the mobile station 500 to notify that the handover to the target base station 400 ₂ has been completed (HO complete) (step S824).

Next, the target base station 400 ₂ notifies that the handover has been completed in order to change the path from the access gateway 300 ₁ set in the source base station 400 ₁ to the target base station 400 ₂ . (Handover Complete) to be transmitted to the access gateway 300 ₁ (step S826).

Receiving the handover completion notification, the access gateway 300 ₁ notifies the target base station 400 ₂ of a handover completion acknowledgment (Handover Complete ACK) in order to notify the completion of the path switch (step S828).

Target base station 400 ₂ receives the handover completion acknowledgment sends resource release message to the source base station 400 ₁ (step S830).

The source base station 400 ₁ that receives the resource release message discards the context that duplicates (Delete context) (step S832).

  Next, the operation of the base station 400 in the radio access network 100 according to the present embodiment will be described with reference to FIG.

  In this embodiment, the operation will be described separately for a source base station and a target base station.

Regarding the operation of the source base station, the processing in step S412 and subsequent steps differs in the operation of the source base station described with reference to FIG. In step S412, it checks whether it has received a resource release message from the target base station 400 ₂ (step S912). If the target base station 400 ₂ has received the resource release message (step S912: YES), the control unit 402 discards the replicated context and user data (step S914), and ends.

  The operation of the target base station will be described with reference to FIG.

Regarding the operation of the target base station, the processing after step S508 is different from the operation of the source base station described with reference to FIG. At step S508, the channel setting completion notification from the mobile station 500, for example, if it is determined that it has received the HO complete (step S506: YES), the control unit 402 to the access gateway 300 ₁ transmits a handover completion notification (step S1008).

Next, the control unit 402, from the access gateway 300 _1, determines whether it has received the handover completion acknowledgment (HO Complete Ack) (step S1010). Control unit 402, from the access gateway 300 _1, when receiving the handover complete acknowledgment (HO Complete Ack) (step S1010), to the source base station transmits a resource release message (step S1012).

  Next, a handover sequence in the radio access network 100 according to the present embodiment will be described with reference to FIG.

In the present embodiment, the mobile station 500, the case of handover from the source base station 400 ₁ connected to the access gateway 300 ₁ subordinate to the target base station 400 _2.

Mobile station 500, as the source base station 400 ₁ can select a proper handover destination base station, information indicating the communication quality of the base station as a handover destination candidate for the source base station 400 ₁ is stored measurement A report is reported (step S1102).

Next, the source base station 400 ₁ measures or estimates the moving speed of the mobile station 500 to be handed over, and when it is faster than the moving speed specified in advance by the system, that is, when it is equal to or higher than a predetermined threshold, Group the base candidates that are the previous candidates. The source base station 400 _1, the grouping candidate, based on at least one of the transfer capacity of the transmission path that the user data transfer capability and base station of the base station is connected, a plurality of base station as a handover destination candidate Is selected based on the measurement report of the mobile station (User mobility analysis & HO decision) (step S1104). For example, base stations 400 _{2 to} 400 _{m are} selected as base stations that are candidates for the handover destination.

Next, the source base station 400 _1, the context, for example, transfers C-plane-related information to the handover destination candidate to become the base station _{400 2 ~400 m (HO request)} ( Step S1106, Step S1108). For example, the source base station 400 _{1 transfers} the context by multicast to the base stations 400 _{2 to} 400 _{m that} are candidates for the handover destination.

Next, the base stations 400 _{2 to} 400 _{m that} are candidate handover destinations allocate resources based on the QoS information included in the context transferred from the source base station 400 ₁ (Admission Control). Further, 400 _{2 to} 400 _{m that} are candidates for the handover destination reserve the allocated resources (steps S1110 and S1112).

Next, when the necessary resources have been successfully reserved, the base stations 400 _{2 to} 400 _m notify the source base station 400 ₁ of a handover request acknowledgment indicating that preparation for handover has been completed. (HO request Ack) (steps S1114 and S1116).

Here, when the necessary resources cannot be secured, the base stations 400 _{2 to} 400 _m notify the source base station 400 ₁ that the resources to the mobile station 500 cannot be secured.

The source base station 400 _1, when the resource from the base station 400 ₂ to the mobile station 500 is informed that can not be ensured, based on the measurement report from the mobile station 500, suitable to check the availability of the resource A base station that is another candidate for the handover destination is selected. That is, the same operation as that in step S1104 is performed.

Next, the source base station 400 ₁ receives ACK (Acknowledge) from the mobile station 500 as user data to be transferred to the mobile station 500 to a plurality of grouped base stations including the target base station 400 _2. received from the user data and the access gateway 300 ₁ not, still starts transferring the user data that is not transmitted to the mobile station 500 (start user data forwarding) (step S1118, step S1120, step S1122). For example, the source base station 400 ₁ multicasts user data to a plurality of grouped base stations including the target base station 400 ₂ by multicast.

The source base station 400 ₁ notifies the mobile station 500 of cell-specific information necessary for re-establishing a radio channel with the target base station 400 ₂ , that is, cell-specific information (HO Command) (step S 1124). .

Next, the mobile station 500 receives the synchronization channel from the target base station 400 _2, to establish a target base station 400 ₂ and the radio synchronization, sets a radio channel (L1 / L2 HO Rx SCH from tNB) ( step S1126 ).

After setting the radio channel with the target base station 400 _2, the mobile station 500 to notify that the handover to the target base station 400 ₂ has been completed (HO complete) (step S1128).

Next, the target base station 400 ₂ notifies that the handover has been completed in order to change the path from the access gateway 300 ₁ set in the source base station 400 ₁ to the target base station 400 ₂ . (Handover Complete) to be transmitted to the access gateway 300 ₁ (step S1130).

Access gateway 300 ₁ that receives the handover completion notification, to the target base station 400 _2, and notifies the handover completion acknowledgment to notify the path switch complete (Handover Complete ACK) (step S1132).

Target base station 400 ₂ receives the handover completion acknowledgment sends resource release message to the source base station 400 ₁ (step S1134).

The source base station 400 ₁ that receives the resource release message discards the context that duplicates (Delete context) (step S1136).

  Next, the operation of the base station 400 in the radio access network 100 according to the present embodiment will be described with reference to FIG.

  In this embodiment, the operation of the target base station is similar to the operation described with reference to FIG. 10, and therefore the operation of the source base station will be described.

Regarding the operation of the source base station, the processing after step S720 is different from the operation of the source base station described with reference to FIG. In step S720, it checks whether it has received a resource release message from the target base station 400 ₂ (step S1220). If the target base station 400 ₂ has received the resource release message (step S1220: YES), the control unit 402 discards the replicated context and user data (step S1222), and ends.

  According to the embodiment of the present invention, a handover destination base station and a mobile station to which user data is transferred can be determined simultaneously based on the moving speed of the mobile station.

  As described above, according to the embodiment of the present invention, base stations (cells) that are highly likely to be handed over are grouped, and at the time of handover, user data is forwarded to the grouped base stations, Even in an environment in which a mobile station moves at high speed, it is possible to prevent data from being lost without being able to send data, and to effectively transfer data and ensure communication quality.

  This international application claims priority based on Japanese Patent Application No. 2006-66280 filed on Mar. 10, 2006, the entire contents of which are incorporated herein by reference.

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

Claims (10)

Transfer destination determining means for selecting a plurality of transfer destination base stations for transferring user data to be transmitted to the mobile station;
Data transfer means for transferring the user data to the transfer destination base station determined by the transfer destination determination means;
With
The data transfer means transfers the user data to the transfer destination base station at the same time. In the base station according to claim 1:
Movement information collection means for collecting information on movement of the mobile station;
With
The transfer destination determining means selects a plurality of transfer destination base stations to which user data to be transmitted to a mobile station is transferred based on the information on the movement. In the base station according to claim 1:
The transfer destination determining means selects a transfer destination base station based on the communication quality of another base station notified from the mobile station. In the base station according to claim 1:
The transfer destination determining means estimates a moving direction of a mobile station based on a passage history of the mobile station or a report from the mobile station, and selects a base station in the moving direction. In the base station according to claim 1:
The transfer destination determining means determines the number of base stations that transfer user data based on at least one of a CPU load, a stored data amount, and a transmission path band. A transfer destination determination step of selecting a plurality of transfer destination base stations to transfer user data to be transmitted to the mobile station;
A data transfer step of simultaneously transferring the user data to the transfer destination base station determined by the transfer destination determination step;
A handover control method comprising: In the handover control method according to claim 6,
A movement information collecting step for collecting information on movement of the mobile station;
Have
The transfer destination determining step selects a plurality of transfer destination base stations to which user data to be transmitted to a mobile station is transferred based on the information related to the movement. In the handover control method according to claim 6,
The transfer destination determining step selects a transfer destination base station based on the communication quality of another base station notified from the mobile station. In the base station according to claim 6:
In the handover control method, the transfer destination determination step estimates a moving direction of the mobile station based on a passage history of the mobile station or a report from the mobile station, and selects a base station in the moving direction. In the handover control method according to claim 6,
The transfer destination determining step determines the number of base stations that transfer user data based on at least one of a CPU load, a stored data amount, and a transmission path band.

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