JP2017511662A - Method and apparatus for processing uplink data - Google Patents

Abstract

Embodiments of the present invention provide an uplink data processing method and apparatus, and a target base station activates a full configuration setting option in the process of a user terminal handover from a higher version base station to a lower version base station. By knowing this, the uplink data of the user terminal can be delivered directly to the service gateway at the source base station without reversing to the target side, improving the utilization rate of the X2 or S1 interface bandwidth, Effectively reduce width occupancy. In addition, the source side does not need to reverse the uplink data and does not need to create a reverse tunnel, and the source side and the target side simplify the processing for the uplink data and improve the processing performance of the system. [Selection] Figure 2

Description

  The present invention relates to the field of wireless communication, and more particularly, to a processing method and apparatus for uplink data when starting full configuration in the process of handover between stations in a Long Term Evolution (LTE) system.

  FIG. 1 is a handover flowchart for identifying the full configuration of a traditional X2 handover request for uplink data processing according to the prior art. As shown in FIG. 1, a version base station with a high user equipment (UE, User Equipment) When handing over or re-establishing to a lower version base station, the lower version base station cannot know the current setting status of the UE. In this case, the target base station D-ENB transmits a full configuration (a full configuration identifier is transmitted to the source side base station S-ENB by a handover request response, and the source side base station S-ENB sends a handover command. By transmitting to the UE as it is, it is possible to clean the dedicated resource setting in the source side base station S-ENB and prevent the occurrence of an unpredictable abnormality.

  When the UE receives a configuration message for full configuration radio resource control protocol reconfiguration (RRC Connection Reconfiguration, Radio Resource Control Connection Reconfiguration), it must clean all dedicated resources including measurement configuration and other configuration Otherconfig Cell radio network temporary identifier (CRNTI) / security parameters / radio link control (RLC) / packet data convergence protocol (PDCP) / logical channel settings are held Need to ensure a subsequent possible re-establishment flow.

  In the acknowledge mode AM (Acknowledged Mode), after the source side receives the data reverse request in the handover process, any discontinuous data in the uplink needs to be reversed to the target side. When a terminal hands over from a higher version base station to a lower version base station, the lower version base station, which is the target base station, prevents the appearance of unpredictable anomalies by determining that the full configuration setting needs to be activated. However, for uplink data processing, the target-side base station may discard the reverse data or directly deliver the reverse data to a service gateway (SGW). However, if the target base station activates the full configuration setting in the process of handing over from the higher version base station to the lower version base station, the source side reverses the uplink message to the target side and the target side discards or Delivered directly to the service gateway, which wastes the bandwidth of the X2 interface, increases the processing flow that the source and target base stations do not need, and introduces extra overhead to the system.

  Embodiments of the present invention provide an uplink data processing method and apparatus, and an interface by reversing uplink data to a target base station in a process in which a terminal is handed over from a higher version base station to a lower version base station. The problem of low bandwidth utilization can be solved.

In one aspect, the present invention provides a method for processing uplink data,
In the process of handover of the user equipment UE, after the source side base station knows that the target side base station has already activated the full configuration setting option, the uplink data transmitted by the user equipment UE is delivered directly to the service gateway. Including doing.

  Optionally, the source side base station indicates that the target side base station has already activated the full configuration configuration option by a handover request response message including a full configuration identifier or a full configuration instruction message transmitted by the target side base station. know.

Optionally, the source side base station knows that the target side base station has already activated the full configuration configuration option by means of a handover request response message including a full configuration identifier transmitted by the target side base station,
For X2 handover, the source base station receives the handover request response message including the full configuration identifier from the target base station, and obtains the full configuration identifier by analyzing the handover request response message. Knowing that the target base station has already activated the full configuration configuration option,
For S1 handover, the source base station receives a handover command including the constructed full configuration identifier based on the handover request response message including the full configuration identifier transmitted from the target base station from the mobility management entity MME. And obtaining the full configuration identifier by analyzing the handover command, thereby knowing that the target base station has already activated the full configuration configuration option.

Optionally, the source side base station knows by the full configuration indication message sent by the target side base station that the target side base station has already activated the full configuration configuration option,
For X2 handover, the source side base station receives the full configuration instruction message from the target side base station, and analyzes the instruction message to confirm that the target side base station has already activated the full configuration setting option. Knowing,
For S1 handover, the target side base station sends a full configuration instruction message to the MME, the MME sends the full configuration instruction message to the source side base station, and the source side base station analyzes the instruction message. Thereby knowing that the target base station has already activated the full configuration setting option.

  Optionally, delivering the uplink data sent by the user terminal directly to the service gateway includes an uplink message with consecutive numbers and an uplink message with discontinuous numbers from the user terminal, Direct delivery to the service gateway.

In another aspect, the present invention provides an apparatus for processing uplink data,
In the process of handover of the user equipment UE, the source side base station delivers the uplink data transmitted by the user equipment UE directly to the service gateway after knowing that the target side base station has already activated the full configuration setting option. Includes delivery units that are set up to.

Optionally, the delivery unit is
The source side base station is set to know that the target side base station has already activated the full configuration setting option by a handover request response message including a full configuration identifier or a full configuration instruction message transmitted from the target side base station. Including learning modules.

Optionally, the learning module further comprises:
For X2 handover, the source base station receives the handover request response message including the full configuration identifier from the target base station, and obtains the full configuration identifier by analyzing the handover request response message. An X2 response analysis submodule configured to know that the target base station has already activated the full configuration configuration option;
For S1 handover, the source base station receives a handover command including the constructed full configuration identifier based on the handover request response message including the full configuration identifier transmitted from the target base station from the mobility management entity MME. Analyzing the handover command to obtain the full configuration identifier, and thereby an S1 command analysis submodule configured to know that the target base station has already activated the full configuration configuration option; Including.

Optionally, the learning module further comprises:
For X2 handover, the source side base station receives the full configuration instruction message from the target side base station, and analyzes the instruction message to confirm that the target side base station has already activated the full configuration setting option. An X2 instruction analysis submodule configured to know,
For S1 handover, the target base station transmits a full configuration instruction message to the MME, the MME transmits the full configuration instruction message to the source base station, and the source side base station analyzes the instruction message. Thereby including an S1 indication analysis submodule configured to know that the target base station has already activated the full configuration configuration option.

Optionally, the delivery unit further comprises:
A message delivery module configured to deliver directly from the user terminal to the service gateway, including uplink messages with consecutive numbers and uplink messages with discontinuous numbers;

  In another aspect, the present invention provides a computer program and a medium thereof, and the computer program includes a program command, and when the program command is executed by the source side base station device, the source side base station device The link data processing method can be executed.

  Compared to the prior art, the beneficial effect of the embodiment of the present invention is that by knowing that the target side has activated the full configuration configuration option, it delivers the uplink data directly on the source side, without reversing to the target side, X2 or S1 interface bandwidth utilization can be improved and bandwidth utilization can be effectively reduced. In addition, the source side does not need to reverse the uplink data and does not need to create a reverse tunnel, and the source side and the target side simplify the processing for the uplink data and improve the processing performance of the system.

FIG. 1 is a handover flowchart for identifying the full configuration of a traditional X2 handover request for uplink data processing according to the prior art. FIG. 2 is a principle diagram of an uplink data processing method according to an embodiment of the present invention. FIG. 3 is a structural diagram of an uplink data processing apparatus according to an embodiment of the present invention. FIG. 4 is a handover flowchart for identifying a full configuration of an X2 handover request for uplink data processing according to an embodiment of the present invention. FIG. 5 is a flowchart of an X2 handover in which a full configuration is notified to the source side by an uplink data processing message according to an embodiment of the present invention. FIG. 6 is a handover flowchart for identifying the full configuration of the S1 handover request for uplink data processing according to an embodiment of the present invention. FIG. 7 is a flowchart of an S1 handover in which a full configuration is notified to the source side by an uplink data processing message according to an embodiment of the present invention.

  Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings. However, the preferred embodiments described below are only for explaining and interpreting the present invention, and the present invention is not limited thereto. Not meant to be In the case where no contradiction occurs, the embodiments in the present application and the features in the embodiments can be arbitrarily combined with each other.

  FIG. 2 is a principle diagram of an uplink data processing method according to an embodiment of the present invention. As shown in FIG. 2, specific steps are as follows.

  Step S1: In the process of handover of the user apparatus UE, the source side base station directly knows that the target side base station has already activated the full configuration setting option, and then directly serves the uplink data transmitted by the user apparatus UE. Deliver to the gateway.

  In step S1, the source side base station confirms that the target side base station has already activated the full configuration setting option by a handover request response message including a full configuration identifier or a full configuration instruction message transmitted by the target side base station. know.

Optionally, the source side base station knows that the target side base station has already activated the full configuration configuration option by means of a handover request response message including a full configuration identifier transmitted by the target side base station,
For X2 handover, the source base station receives the handover request response message including the full configuration identifier from the target base station, and obtains the full configuration identifier by analyzing the handover request response message. Knowing that the target base station has already activated the full configuration configuration option,
For S1 handover, the source side base station sends a handover command including the full configuration identifier constructed based on the handover request response message including the full configuration identifier transmitted from the target management base station from the mobility management entity MME. Receiving and analyzing the handover command to obtain the full configuration identifier, thereby knowing that the target base station has already activated the full configuration configuration option.

Optionally, the source side base station knows by the full configuration indication message sent by the target side base station that the target side base station has already activated the full configuration configuration option,
For X2 handover, the source side base station receives the full configuration instruction message from the target side base station, and analyzes the instruction message to confirm that the target side base station has already activated the full configuration setting option. Knowing,
For S1 handover, the target side base station sends a full configuration instruction message to the MME, the MME sends the full configuration instruction message to the source side base station, and the source side base station analyzes the instruction message. Thereby knowing that the target base station has already activated the full configuration setting option.

  Optionally, the direct delivery of uplink data transmitted by the user terminal includes direct delivery to the service gateway including uplink messages with consecutive numbers and uplink messages with non-consecutive numbers from the user terminal. To do.

  FIG. 3 is a structural diagram of an apparatus for processing uplink data according to an embodiment of the present invention. As shown in FIG. 3, the structure is as follows.

  In the process of the handover of the user equipment UE, the delivery unit knows that the source side base station has already activated the full configuration setting option, and then transmits the uplink data transmitted by the user equipment UE. Set to deliver directly to the service gateway. Among them, the learning module of the delivery unit is configured so that the target base station has already set the full configuration by the handover request response message including the full configuration identifier or the full configuration instruction message transmitted from the target base station by the source base station. Set to know that the option has been activated. The X2 response analysis submodule of the learning module receives the handover request response message including the full configuration identifier from the target base station, and analyzes the handover request response message for the X2 handover. By doing so, the full configuration identifier is obtained, so that the target base station is set to know that the full configuration setting option has already been activated. The S1 command analysis sub-module of the learning module is based on a handover request response message including a full configuration identifier transmitted from the target base station by the source base station from the mobility management entity MME for the S1 handover. Receiving the handover command including the constructed full configuration identifier and analyzing the handover command to obtain the full configuration identifier, thereby knowing that the target base station has already activated the full configuration configuration option Set to The X2 indication analysis sub-module of the learning module receives the full configuration indication message from the target side base station and analyzes the indication message when the source side base station receives the full configuration indication message for the X2 handover. Is set to know that has already started the full configuration configuration option. The S1 indication analysis submodule of the learning module sends a full configuration indication message to the MME for the S1 handover, and the MME sends the full configuration indication message to the source base station, The base station is set to know that the target base station has already activated the full configuration setting option by analyzing the instruction message. The message delivery module of the delivery unit is set to deliver directly from the user terminal to the service gateway including uplink messages with consecutive numbers and uplink messages with discontinuous numbers.

  FIG. 4 is a handover flowchart for identifying the full configuration of an X2 handover request for uplink data processing according to an embodiment of the present invention. As shown in FIG. 4, in the handover request handover request ack for an X2 interface handover, The flow for transmitting to the source side including the full configuration and delivering the uplink data directly is as follows.

(1) The source-side base station S-ENB transmits a handover request handover request to the target-side base station D-ENB and notifies the target-side base station D-ENB to prepare for handover.
(2) The target-side base station D-ENB finds that the version of the source-side base station S-ENB is higher than the version of the base station, and activates the full configuration setting option.
(3) The target-side base station D-ENB transmits a handover request response handover request acknowledge to the source-side base station S-ENB and includes a full configuration identifier.
(4) After receiving the handover request response handover request acknowledge, the source-side base station S-ENB performs analysis, and if it finds that the target-side base station D-ENB has already activated the full configuration setting option, It is not necessary to transmit an RRC Connection Reconfiguration setting message including an identifier to the UE to deliver uplink data directly to the service gateway SGW, and to perform uplink data reverse and uplink reverse tunnel creation.
(5) The UE completes the configuration based on the received RRC Connection Reconfiguration configuration message and realizes contention access, and the UE is the most preferential UE in the current priority, and the target base station D -The resources of ENB are allocated and the RRC Connection Reconfiguration setting is completed, and handover between base stations can be realized. The UE can also realize non-contention random access, and the UE is the current randomly selected UE, and the resources of the target base station D-ENB are allocated to complete the RRC Connection Reconfiguration setting. Thus, handover between base stations can be realized.
(6) The UE transmits RRC connection reconfiguration completion information RRC Connection Reconfiguration Complete to the target base station D-ENB.

  FIG. 5 is a flowchart of an X2 handover in which a full configuration is notified to the source side by an uplink data processing message according to an embodiment of the present invention. As shown in FIG. The flow for notifying the source side that the full configuration has been started and delivering the uplink data directly is as follows.

(1) The source-side base station S-ENB transmits a handover request handover request to the target-side base station D-ENB and notifies the target-side base station D-ENB to prepare for handover.
(2) The target-side base station D-ENB finds that the version of the source-side base station S-ENB is higher than the version of the base station, and activates the full configuration setting option.
(3) The target-side base station D-ENB transmits one special instruction message (that is, full configuration indication message) to the source-side base station S-ENB, and the target-side base station D-ENB The source side base station S-ENB is notified that the full configuration setting option has already been activated.
(4) The target-side base station D-ENB transmits a handover request response handover request acknowledge to the source-side base station and includes an RRC Connection Reconfiguration setting message including a full configuration identifier. Used to implement station handover.
(5) The source side base station S-ENB analyzes the received special instruction message from the target side base station D-ENB, so that the target side base station has already activated the full configuration setting option. After acquiring the RRC Connection Reconfiguration configuration message including the full configuration identifier to the UE, it is necessary to deliver the uplink data directly to the service gateway SGW and to reverse the uplink data and create the uplink reverse tunnel Absent.
(6) The UE completes the configuration based on the received RRC Connection Reconfiguration configuration message and realizes contention access, and the UE is the most preferential UE in the current priority, and the target side base station D- ENB resources are allocated and RRC Connection Reconfiguration settings are completed, and handover between base stations can be realized. The UE can also realize non-contention random access, and the UE is the current randomly selected UE, and the resources of the target base station D-ENB are allocated to complete the RRC Connection Reconfiguration setting. Thus, handover between base stations can be realized.
(7) The UE transmits RRC connection reconfiguration completion information RRC Connection Reconfiguration Complete to the target-side base station D-ENB.

  FIG. 6 is a handover flowchart for identifying the full configuration of the S1 handover request for uplink data processing according to an embodiment of the present invention. As shown in FIG. 6, the handover request confirmation handover request ack is performed for the S1 interface handover. The flow of transmitting the uplink data directly while including the full configuration in FIG.

(1) The source-side base station S-ENB transmits a handover request handover required to a mobility management entity (MME), and the MME sends a handover request handover request to the target-side base station based on the handover request handover required Transmit to D-ENB and notify target base station D-ENB to prepare for handover. Among them, during the S1 handover process, the handover request transmitted from the source base station S-ENB to the MME is indicated as handover required, and the handover request received by the target base station D-ENB is indicated as handover request.
(2) The target-side base station D-ENB finds that the version of the source-side S-ENB is higher than the version of the base station, and activates the full configuration setting option.
(3) The target-side base station D-ENB transmits a handover request response handover request acknowledge and transmits it to the MME including the full configuration identifier. The MME sends a handover command handover command based on the handover request response handover request acknowledge. It is constructed and transmitted to the source side base station S-ENB including the full configuration identifier.
(4) After receiving the handover command handover command, the source-side base station S-ENB performs analysis, and if it finds that the target-side base station D-ENB has already activated the full configuration setting option, the source-side base station S-ENB sets the full configuration identifier. An RRC Connection Reconfiguration setting message is transmitted to the UE, and uplink data is directly delivered to the service gateway SGW, so that it is not necessary to reverse uplink data and create an uplink reverse tunnel.
(5) The UE completes the configuration based on the received RRC Connection Reconfiguration configuration message and realizes contention access. The UE is the most preferential UE in the current priority, and the target side base station D- ENB resources are allocated and RRC Connection Reconfiguration settings are completed, and handover between base stations can be realized. The UE can also realize non-contention random access, and the UE is the current randomly selected UE, and the resources of the target base station D-ENB are allocated to complete the RRC Connection Reconfiguration setting. Thus, handover between base stations can be realized.
(6) The UE transmits RRC connection reconfiguration completion information RRC Connection Reconfiguration Complete to the target base station D-ENB.

  FIG. 7 is a flowchart of S1 handover in which a full configuration is notified to the source side by an uplink data processing message according to an embodiment of the present invention. As shown in FIG. 7, a specific message is used for S1 interface handover. The flow for notifying the source side that the full configuration has been started and delivering the uplink data directly is as follows.

(1) The source-side base station S-ENB transmits a handover request handover required to the MME, and the MME transmits a handover request hanover request to the target-side base station D-ENB based on the handover request handover required. Is notified to the target base station D-ENB.
(2) The target-side base station D-ENB finds that the version of the source-side S-ENB is higher than the version of the base station, and activates the full configuration setting option.
(3) The target-side base station D-ENB sends one special instruction message (that is, full configuration indication message full configuration indication) to the source-side base station S-ENB by the MME, and already has the full configuration setting option. The source side base station S-ENB is notified of the activation.
(4) The target-side base station D-ENB transmits a handover request response handover request acknowledge to the MME including the full configuration identifier, and the MME constructs a handover command handover command based on the handover request response handover request acknowledge. The full configuration identifier is transmitted to the source-side base station S-ENB.
(5) The source-side base station S-ENB analyzes the received special instruction message from the target-side base station D-ENB to obtain the full configuration identifier that the target-side base station has already activated the full configuration setting option. After acquisition, RRC Connection Reconfiguration configuration message including full configuration identifier is sent to the UE, uplink data is delivered directly to the service gateway SGW, and it is not necessary to reverse uplink data and create uplink reverse tunnel .
(6) The UE completes the configuration based on the received RRC Connection Reconfiguration configuration message and realizes contention access. The UE is the most preferential UE in the current priority, and the target base station D-ENB Resources are allocated to complete the RRC Connection Reconfiguration setting, and handover between base stations can be realized. The UE can also realize non-contention random access, and the UE is the current randomly selected UE, and the resources of the target base station D-ENB are allocated to complete the RRC Connection Reconfiguration setting. Thus, handover between base stations can be realized.
(7) The UE transmits RRC connection reconfiguration completion information RRC Connection Reconfiguration Complete to the target-side base station D-ENB.

  In summary, the embodiment of the present invention improves the utilization rate of X2 or S1 interface bandwidth by delivering uplink data directly on the source side without reversing to the target side, and wastes bandwidth. Has the technical effect of effectively reducing. In addition, the source side does not need to reverse the data and does not need to create a reverse tunnel, thereby simplifying the processing for the uplink data on the source side and the target side. Because the source side does not need to create an uplink reverse tunnel, it cannot reverse the uplink data, so the target side will not receive uplink reverse data, conserve memory resources, and source and target The side simplifies the processing flow for uplink data reverse, reduces the processing load on the system, and enhances the robustness of the system.

  As can be understood by those skilled in the art, all or part of the steps of the above embodiments can be realized by a computer program flow, and the computer program can be stored in a computer-readable storage medium. The program is executed on a corresponding hardware platform (eg, system, facility, apparatus, device, etc.) and includes one or a combination of steps of the method embodiments when executed.

  Alternatively, all or some of the steps of the above embodiments may be realized by an integrated circuit, each of which may be created in each integrated circuit module, or a plurality of modules or The steps may be realized by creating a single integrated circuit module. Thus, the present invention is not limited to any specific combination of hardware and software.

  Each device / functional module / functional unit in the above embodiment can be realized by a general-purpose computer device, which may be concentrated in a single computer device or distributed in a network composed of a plurality of computer devices. Also good.

  Each device / functional module / functional unit in the above embodiment is realized in the form of a software functional module and can be stored in a computer-readable storage medium when sold or used as an independent product. The computer-readable storage medium may be a read-only memory, a disk, an optical disk, or the like.

  Any variation or replacement readily figured out by any person skilled in the art within the technical scope disclosed by the present invention shall fall within the protection scope of the present invention. Therefore, the protection scope of the present invention should be based on the protection scope described in the claims.

  According to an uplink data processing method and apparatus according to an embodiment of the present invention, a target base station activates a full configuration setting option in a process in which a user terminal is handed over from a higher version base station to a lower version base station. By knowing this, the uplink data of the user terminal can be delivered directly to the service gateway at the source base station without reversing to the target side, improving the utilization rate of the X2 or S1 interface bandwidth, Occupation of the width can be effectively reduced, the processing on the uplink data is simplified on the source side and the target side, and the processing performance of the system is improved.

Claims (12)

  In the process of handover of the user equipment UE, after the source side base station knows that the target side base station has already activated the full configuration setting option, the uplink data transmitted by the user equipment UE is directly transmitted to the service gateway. A method of processing uplink data including delivering.   The source-side base station knows that the target-side base station has already activated the full configuration setting option by a handover request response message including a full configuration identifier or a full configuration instruction message transmitted by the target-side base station. Item 2. The method according to Item 1. The source-side base station knows that the target-side base station has already activated the full configuration configuration option by a handover request response message including a full configuration identifier transmitted by the target-side base station,
For X2 handover, the source-side base station receives a handover request response message including a full configuration identifier from the target-side base station, and analyzes the handover request response message to obtain the full configuration identifier. Obtaining and knowing that the target base station has already activated the full configuration configuration option;
For S1 handover, the source side base station includes a full configuration identifier constructed based on a handover request response message including the full configuration identifier transmitted from the target base station from the mobility management entity MME. Receiving a command and analyzing the handover command to obtain the full configuration identifier, thereby knowing that the target base station has already activated the full configuration configuration option. The method described. The source-side base station knows that the target-side base station has already activated the full configuration setting option by the full configuration instruction message transmitted by the target-side base station,
For X2 handover, the source-side base station receives the full configuration instruction message from the target-side base station, and analyzes the instruction message, so that the target-side base station has already activated the full configuration setting option. Knowing what you did,
For S1 handover, the target side base station sends a full configuration instruction message to the MME, the MME sends the full configuration instruction message to the source side base station, and the source side base station sends the instruction message to the MME. 3. The method of claim 2, comprising knowing by analysis that the target base station has already activated the full configuration configuration option.   Delivering the uplink data transmitted by the user terminal directly to the service gateway includes directly sending the uplink data from the user terminal to the service gateway, including an uplink message with consecutive numbers and an uplink message with discontinuous numbers. The method of claim 1, which refers to delivering.   In the process of handover of the user equipment UE, the source side base station delivers the uplink data transmitted by the user equipment UE directly to the service gateway after knowing that the target side base station has already activated the full configuration setting option. Uplink data processing device including a delivery unit configured to do. The delivery unit is
The source-side base station knows that the target-side base station has already activated the full configuration setting option by a handover request response message or a full configuration instruction message including a full configuration identifier transmitted from the target-side base station. The apparatus of claim 6, comprising a learning module set to: The learning module is
For X2 handover, the source-side base station receives a handover request response message including a full configuration identifier from the target-side base station, and analyzes the handover request response message to obtain the full configuration identifier. An X2 response analysis submodule configured to obtain and thereby know that the target base station has already activated the full configuration configuration option;
For S1 handover, the source side base station sends a handover command including a full configuration identifier constructed based on a handover request response message including a full configuration identifier transmitted from the target side base station from the mobility management entity MME. An S1 command analysis submodule configured to receive and analyze the handover command to obtain the full configuration identifier and thereby know that the target base station has already activated the full configuration configuration option; The apparatus of claim 7 comprising: The learning module further includes
For X2 handover, the source-side base station receives the full configuration instruction message from the target-side base station, and analyzes the instruction message, so that the target-side base station has already activated the full configuration setting option. An X2 instruction analysis submodule configured to know
For S1 handover, the target side base station sends a full configuration instruction message to the MME, the MME sends the full configuration instruction message to the source side base station, and the source side base station sends the instruction message to the MME. The apparatus according to claim 7, comprising: an S1 indication analysis submodule configured to know by analysis that the target base station has already activated the full configuration configuration option. The delivery unit further comprises:
7. The apparatus of claim 6, comprising a message delivery module configured to deliver directly to the service gateway, including uplink messages with consecutive numbers and uplink messages with non-continuous numbers, from the user terminal.   The computer program which can perform the method as described in any one of Claims 1-5 when a program instruction | command is included and this program instruction | command is performed by the source side base station apparatus.   A medium for storing the computer program according to claim 11.

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