JP5175973B2 - Mobile communication system and radio base station - Google Patents

Description

  The present invention relates to a mobile communication system and a radio base station.

  In the LTE (Long Term Evolution) method, generally, during handover between radio base stations (Inter-eNB HO), the handover source radio base station eNB (Source-eNB) is transferred to the handover destination radio base station eNB (Target-eNB). ), The “serving-eNB” of the mobile station UE has been changed by the handover by transferring the data in which the ACK (acknowledgment information) from the mobile station UE could not be confirmed and the state variable related to the data. Even in this case, lossless communication can be realized.

  In the radio base station eNB, a PDCP (Packet Data Convergence Protocol) layer function is mainly related to data transfer processing.

  Specifically, the PDCP layer function mainly performs data concealment / decryption processing, header compression / de-compression processing, and data tampering detection (integrity protection) processing. It is configured as follows.

  The PDCP layer function manages HFN (Hyper Frame Number) and PDCP-SN (Sequence Number) as state variables, and performs the above-described concealment / decryption processing and header compression processing using such state variables as input values. It is configured.

  Here, between the mobile station UE and the radio base station eNB, if the consistency of the above-described HFN value cannot be maintained, normal decryption processing cannot be performed in the receiving side device, and transmitted data (For example, IP packet) cannot be extracted.

  Therefore, when performing the data transfer described above, it is necessary to carry out the handover procedure while maintaining the HFN consistency between the mobile station UE and the handover destination radio base station eNB.

  Hereinafter, transmission / reception processing in the PDCP layer function will be described in detail.

  The PDCP layer function (PDCP entity) of the transmission side device performs a concealment process (and header compression process) on the PDCP-SDU (Service Date Unit) using HFN in the transmission process, and assigns a PDCP-SN. Thus, a PDCP-PDU (Protocol Data Unit) is generated and transmitted to an RLC (Radio Link Control) layer function.

  Here, “PDCP-SN” is a sequence number that is incremented each time a PDCP-PDU is generated in the PDCP layer function, and takes a value in the range of “0” to “4095”.

  “HFN” is incremented every time PDCP-SN makes a round, and takes a value in the range of “0” to “1048576”.

  Further, the “COUNT value” is a value having HFN as the upper bits and PDCP-SN as the lower bits.

  The PDCP layer function (PDCP entity) of the receiving side apparatus is configured to manage “Rx_reordering_window (order correction window)” and HFN.

  Here, the size of “Rx_reordering_window” is a half value (for example, 2048) of the range that PDCP-SN can take.

  If the PDCP-DN (Received-SN) value assigned to the received PDCP-PDU is within “Rx_reordering_window”, the PDCP layer function of the receiving side device stores the PDCP-PDU in the reception buffer and stores the PDCP-PDU. If the PDCP-DN (Received-SN) value sent to the layer function and given to the received PDCP-PDU is outside “Rx_reordering_window”, the PDCP-PDU is discarded. (Order correction process).

  The value of PDCP-DN (Received-SN) assigned to the received PDCP-PDU is within “Rx_reordering_window”, and was last assigned to the PDCP-PDU sent to the upper layer function. If it is smaller than PDCP-SN (Last_submitted_SN), the PDCP layer function of the transmission side device assumes that the HFN has made a round, and the PDCP layer function of the reception side device increments the HFN and decodes it using the incremented HFN. It is configured to perform processing.

  Moreover, in the conventional data transfer control between the radio base stations eNB, for example, the handover source radio base station eNB applies “RLC-AM (Acknowledge Mode)” to the handover destination radio base station eNB. For all PDCP layer functions to which Data Radio Bearer is mapped, the following information is transferred.

-HFN and PDCP-SN that form the COUNT value to be used for processing the next DL-PDCP-SDU
-PDCP-PDU corresponding to a PDCP-PDU that has already been transmitted for the RLC layer function and for which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the PDCP-PDU.
-PDCP-SDUs corresponding to PDCP-PDUs that have already been processed for COUNT values and assigned PDCP-SN and have not yet been transmitted to the RLC layer function
-PDCP-SDU to which PDCP-SN has not yet been granted
Further, the handover source radio base station eNB is configured to notify the PDCP-SN already assigned to the PDCP-SDU to the handover destination radio base station eNB by the GTP header option.

  Similarly, in the reconnection procedure from the first cell (connection source cell) under the radio base station eNB of the mobile station UE to the second cell (connection destination cell), the first cell in the radio base station eNB is managed. The function is configured to transfer the above information to the function of managing the second cell in the radio base station eNB.

3GPP TS 29.060 3GPP TS36.300

  However, lossless communication is not always performed on the transmission path between the radio base stations eNB. For example, data may be lost on such a transmission line due to a router failure or the like.

  In particular, in a state where a bulk packet loss has occurred in such a transmission path, the handover destination radio base station eNB performs processing using a new HFN and grant of PDCP-SN to downlink data received from an upper node. If the transmission is performed after the transmission, the HFN mismatch occurs between the mobile station UE and the handover destination radio base station eNB, and the reception side apparatus cannot perform a normal decryption process. There is a problem in that normal data cannot be passed to the upper node, data discarding or erroneous reception occurs, and there is a concern that throughput in the downlink may decrease.

  Hereinafter, such a problem will be briefly described with reference to FIGS.

  First, as shown in FIG. 7, in the handover source radio base station eNB # 1, the PDLC-PDU processed using “HFN: 0” and “PDCP-SN: 4095” is used in the RLC layer function. In a state where the delivery confirmation has been made, a handover procedure is started from the cell under the handover source radio base station eNB # 1 of the mobile station UE to the cell under the handover destination radio base station eNB # 2.

  In such a handover procedure, the handover source radio base station eNB # 1 transfers the following information to the handover destination radio base station eNB # 2.

-HFN and PDCP-SN ("HFN: 1" and "PDCP-SN: 2048") that form the COUNT value that will be used to process the next DL-PDCP-SDU
-PDCP-PDU corresponding to a PDCP-PDU that has already been transmitted for the RLC layer function and for which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the PDCP-PDU. (“HFN: 1” and “PDCP-SN: 0/1”)
-PDCP-SDUs corresponding to PDCP-PDUs ("HFN: 1" and "" that have already been processed using the COUNT value and assigned PDCP-SN and have not yet been transmitted to the RLC layer function. PDCP-SN: 2-2047 ")
-PDCP-SDU to which PDCP-SN has not yet been granted (“HFN: 1” and “PDCP-SN: 2048-”)
In addition, the handover source radio base station eNB # 1 notifies the handover destination radio base station eNB # 2 of “PDCP-SN: 0 to 2047” already assigned to the PDCP-SDU by the GTP header option. It is configured as follows.

  Secondly, as shown in FIG. 8, in the transmission path between the handover source radio base station eNB # 1 and the handover destination radio base station eNB # 2, “HFN: 1” and “PDCP-SN: 0 to 2047”. All of the PDCP-PDUs processed using "

  Third, as illustrated in FIG. 9, the handover destination radio base station eNB # 2 transmits to the mobile station UE from the PDCP-PDU processed using “HFN: 1” and “PDCP-SN: 2048”. Is configured to start.

  Here, even if the mobile station UE receives PDCP-PDUs processed using “HFN: 1” and “PDCP-SN: 2048-4095”, the PDCP- attached to these PDCP-PDUs Since the SN is outside “Rx_reordering_window”, these PDCP-PDUs are configured to be discarded.

  The mobile station UE cannot update the “Rx_reordering_window” until it receives the PDCP-PDU to which the PDCP-SN in the “Rx_reordering_window” is assigned. That is, the mobile station UE cannot update the HFN in accordance with the handover destination radio base station eNB # 2. Cannot be incremented.

  Even if the PDCP-PDU is discarded in the mobile station UE, the handover destination radio base station eNB # 2 continues to transmit the PDCP-PDU and increments the HFN if the PDCP-SN makes a round.

  After that, when the mobile station UE receives the PDCP-PDU processed using “HFN: 2” and “PDCP-SN: 0 to 2047”, the PDCP- to be decrypted using “HFN: 2” Since the decryption process is performed on the PDU using “HFN: 1”, a mismatch in HFN occurs between the handover destination radio base station eNB # 2 and the mobile station UE. was there.

  Similarly, in the reconnection procedure from the first cell (connection source cell) under the radio base station eNB of the mobile station UE to the second cell (connection destination cell), the function of managing the first cell inside the radio base station eNB And a function for managing the second cell in a state where a bulk packet loss has occurred in the transmission path between the first node and the function for managing the second cell, a new HFN is received for the downlink data received from the upper node. When transmission is performed after the used processing and PDCP-SN are assigned, an HFN mismatch occurs between the mobile station UE and the function of managing the second cell. As a result of not being able to perform normal decryption processing, normal data cannot be passed to the upper node, data discarding or erroneous reception may occur, and there is a concern that throughput in the downlink may decrease. There was a problem.

  Therefore, the present invention has been made in view of the above-described problems, and even when a bulk packet loss occurs in a transmission path between a handover source radio base station and a handover destination radio base station, An object of the present invention is to provide a mobile communication system and a radio base station that can avoid occurrence of HFN mismatch between the destination radio base station eNB # 2 and the mobile station UE.

  Further, the present invention provides a reconnection destination cell and a mobile station even when a bulk packet loss occurs in a transmission path between the function of managing the reconnection source cell and the function of managing the reconnection destination cell. An object of the present invention is to provide a mobile communication system and a radio base station that can avoid occurrence of HFN mismatch with a UE.

  A first feature of the present invention is a mobile communication system capable of performing a handover procedure from a cell under a first radio base station of a mobile station to a cell under a second radio base station, wherein the first radio base station The PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and granting the PDCP-SN to the PDCP-SDU received from the upper layer function, and for the RLC layer function. In the mobile station, the PDCP layer function discards the PDCP-PDU when the PDCP-SN assigned to the received PDCP-PDU is a value outside the order correction window. And the first PDCP-PDU has already been transmitted to the RLC layer function, and the first PDCP -A PDCP-PDU in which RLC-ACK for all RLC-PDUs corresponding to the PDU has not been confirmed, and the second PDCP-PDU has already been processed using the COUNT value and assigned with the PDCP-SN, And the PDCP-PDU that has not yet been transmitted to the RLC layer function, and the COUNT value to be used for the next PDCP-SDU processing is the COUNT value used for the processing of the first PDCP-PDU. When larger than the sum of the oldest value and the predetermined value, the first radio base station, for the second radio base station, forms a PDCP- that forms a COUNT value to be used for processing the next PDCP-SDU. Instead of SN, transfer is performed for the PDCP-SN forming the sum, and is used for processing the first PDCP-SDU and the second PDCP-SDU. For PDCP-SN to form a COUNT value of more than the sum of the COUNT value is configured to not forward, the predetermined value is summarized in that a value smaller than the size of the reordering window.

  The second feature of the present invention is that the mobile station can operate as the first radio base station in a mobile communication system capable of performing a handover procedure from a cell under the first radio base station to a cell under the second radio base station. A wireless base station comprising a PDCP layer function and a transfer unit, wherein the PDCP layer function performs processing using a COUNT value for PDCP-SDU received from an upper layer function and PDCP-SN Is configured to generate a PDCP-PDU and transmit it to the RLC layer function, the first PDCP-PDU has already been transmitted to the RLC layer function, and , A PDCP-PDU in which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the first PDCP-PDU, and the second PDC -The PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the PDCP-SN, and has not yet been transmitted to the RLC layer function, and the next PDCP-SDU processing When the COUNT value scheduled to be used for the first PDCP-PDU is greater than the sum of the oldest value and the predetermined value among the COUNT values used for processing the first PDCP-PDU, the first radio base station For the PDCP-SN that forms the sum, instead of the PDCP-SN that forms the COUNT value that is to be used for processing the next PDCP-SDU, the first PDCP-SDU and the second PDCP- Among the COUNT values used for SDU processing, PDCP-SN that forms a COUNT value greater than or equal to the sum is not transferred, Serial predetermined value is summarized in that a value smaller than the size of the reordering window used in the PDCP layer function of the mobile station.

  According to a third aspect of the present invention, there is provided a mobile communication system capable of performing a reconnection procedure from a first cell under a radio base station of a mobile station to a second cell. In the radio base station, a PDCP layer function is provided. Is configured to generate a PDCP-PDU and transmit it to the RLC layer function by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the upper layer function In the mobile station, the PDCP layer function discards the PDCP-PDU when the PDCP-SN forming the COUNT value assigned to the received PDCP-PDU is a value outside the order correction window. The first PDCP-PDU has already been transmitted to the RLC layer function, and the first PDCP-PDU A PDCP-PDU in which RLC-ACKs for all corresponding RLC-PDUs have not been confirmed, and the second PDCP-PDU has already been processed using the COUNT value and PDCP-SN has been assigned, and A PDCP-PDU that has not yet been transmitted to the RLC layer function, and the COUNT value to be used for the next PDCP-SDU processing is the oldest value among the COUNT values used for the processing of the first PDCP-PDU. And the function of managing the first cell of the radio base station is greater than the function of managing the second cell of the radio base station in the reconnection procedure. Instead of the PDCP-SN that forms the COUNT value to be used for processing the PDCP-SDU of A PDCP-SN that forms a COUNT value greater than or equal to the sum among the COUNT values used in the processing of one PDCP-SDU and the second PDCP-SDU is configured not to be transferred, and the predetermined value is the order correction The gist is that the value is smaller than the size of the window.

  A fourth feature of the present invention is a radio base station that manages the first cell and the second cell in a mobile communication system capable of performing a reconnection procedure from the first cell of the mobile station to the second cell. The PDCP layer function, the function of managing the first cell, and the function of managing the second cell, and the PDCP layer function counts the PDCP-SDU received from the upper layer function. It is configured to generate a PDCP-PDU by performing processing using a value and assigning a PDCP-SN, and transmit the generated PDCP-PDU to the RLC layer function. A PDCP-PDU that has already been transmitted and for which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the first PDCP-PDU. The second PDCP-PDU is a PDCP-PDU that has been subjected to the processing using the COUNT value and the PDCP-SN has been added and has not yet been transmitted to the RLC layer function. When the COUNT value scheduled to be used for SDU processing is greater than the sum of the oldest value and the predetermined value among the COUNT values used for the processing of the first PDCP-PDU, the function of managing the first cell is In the reconnection procedure, for the function of managing the second cell, the PDCP-SN forming the sum instead of the PDCP-SN forming the COUNT value to be used for the next PDCP-SDU processing Transfer and form a COUNT value greater than or equal to the sum among the COUNT values used for processing the first PDCP-SDU and the second PDCP-SDU. For DCP-SN is configured to not forward, the predetermined value is summarized in that a value smaller than the size of the reordering window used in the PDCP layer function of the mobile station.

  A fifth feature of the present invention is a mobile communication system capable of performing a handover procedure from a first cell under a radio base station of a mobile station to a second cell. In the radio base station, the PDCP layer function is The PDCP-SDU received from the upper layer function is configured to generate a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN, and transmit the PDCP-PDU to the RLC layer function. In the mobile station, the PDCP layer function discards the PDCP-PDU when the PDCP-SN forming the COUNT value assigned to the received PDCP-PDU is a value outside the order correction window. The first PDCP-PDU has already been transmitted to the RLC layer function, and the first PDCP- It is a PDCP-PDU in which RLC-ACK for all RLC-PDUs corresponding to the DU has not been confirmed, and the second PDCP-PDU has already been subjected to processing using the COUNT value and PDCP-SN. A PDCP-PDU that has not yet been transmitted to the RLC layer function, and the COUNT value scheduled to be used for the next PDCP-SDU processing is the largest among the COUNT values used for the processing of the first PDCP-PDU. When the sum of the old value and the predetermined value is larger, the function of managing the first cell of the radio base station is the function of managing the second cell of the radio base station in the handover procedure. PDCP-SN that forms the sum, instead of PDCP-SN that forms the COUNT value that is to be used for processing the next PDCP-SDU The PDCP-SN that forms a COUNT value equal to or greater than the sum among the COUNT values used for processing the first PDCP-SDU and the second PDCP-SDU is configured to not transfer the predetermined value. Is a value smaller than the size of the order correction window.

  A sixth feature of the present invention is a radio base station that manages the first cell and the second cell in a mobile communication system capable of performing a handover procedure from the first cell to the second cell of the mobile station, A PDCP layer function, a function for managing the first cell, and a function for managing the second cell. The PDCP layer function is configured to receive a COUNT value for a PDCP-SDU received from an upper layer function. Is configured to generate a PDCP-PDU and transmit it to the RLC layer function by performing the process using and the provision of the PDCP-SN. The first PDCP-PDU is configured to transmit the RCP layer function to the RLC layer function. PDCP-PD that has already been transmitted and RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the first PDCP-PDU. The second PDCP-PDU is a PDCP-PDU that has already been subjected to processing using the COUNT value and PDCP-SN, and has not yet been transmitted to the RLC layer function. When the COUNT value scheduled to be used for the PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, the function of managing the first cell is as follows: In the handover procedure, for the function of managing the second cell, the PDCP-SN that forms the sum instead of the PDCP-SN that forms the COUNT value to be used for the processing of the next PDCP-SDU Of the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. The PDCP-SN forming the network is configured not to transfer, and the predetermined value is smaller than the size of the order correction window used in the PDCP layer function of the mobile station. .

  As described above, according to the present invention, even when a bulk packet loss occurs in the transmission path between the handover source radio base station and the handover destination radio base station, the handover destination radio base station eNB # 2 and a mobile base station can avoid the occurrence of HFN mismatch between the mobile station UE and the mobile station UE.

  Further, according to the present invention, even when a bulk packet loss occurs in the transmission path between the function of managing the reconnection source cell and the function of managing the reconnection destination cell, It is possible to provide a mobile communication system and a radio base station that can avoid the occurrence of HFN mismatch with the mobile station UE.

1 is an overall configuration diagram of a mobile communication system according to a first embodiment of the present invention. FIG. 3 is a functional block diagram of a radio base station according to the first embodiment of the present invention. 5 is a flowchart showing an operation of the radio base station according to the first embodiment of the present invention. It is a figure for demonstrating operation | movement of the mobile communication system which concerns on the 1st Embodiment of this invention. It is a figure for demonstrating operation | movement of the mobile communication system which concerns on the 1st Embodiment of this invention. It is a figure for demonstrating operation | movement of the mobile communication system which concerns on the 1st Embodiment of this invention. It is a figure for demonstrating operation | movement of the conventional mobile communication system. It is a figure for demonstrating operation | movement of the conventional mobile communication system. It is a figure for demonstrating operation | movement of the conventional mobile communication system.

(Mobile communication system according to the first embodiment of the present invention)
With reference to FIG. 1 thru | or FIG. 6, the mobile communication system which concerns on the 1st Embodiment of this invention is demonstrated. In the present embodiment, an LTE mobile communication system will be described as an example of the mobile communication system according to the present embodiment, but the present invention is also applicable to mobile communication systems other than the LTE system.

  As shown in FIG. 1, the mobile communication system according to the present embodiment includes a radio base station eNB # 1 that manages a cell # 1 and a radio base station eNB # 2 that manages a cell # 2.

  In the present embodiment, as illustrated in FIG. 1, a case where the mobile station UE performs handover from the cell # 1 to the cell # 2 will be described as an example.

  As illustrated in FIG. 2, the radio base station eNB # 1 that is the handover source radio base station eNB includes a PDCP layer function 11, an RLC layer function 12, a transmission unit 13, and a transfer unit 14.

  The PDCP layer function 11 serves as a PDCP layer, and performs processing using the COUNT value as an input value for the PDCP-SDU received from the higher layer function and assigning the PDCP-SN, thereby providing PDCP-SN. -It is configured to generate a PDU and send it to the RLC layer function 12.

  The RLC layer function 12 generates an RLC-PDU based on the PDCP-PDU (RLC-SDU) received from the PDCP layer function 11, and transmits the RLC-PDU to the mobile station UE via the transmission unit 13. It is configured.

  The RLC layer function 12 is configured to transmit delivery confirmation information (RLC-ACK / NACK) for the RLC-PDU to the PDCP layer function 11.

  The transfer unit 14 is configured to transfer the following information to the radio base station eNB # 2 in the handover procedure.

-HFN and PDCP-SN forming the COUNT value (Y) to be used for processing the next PDCP-SDU
-PDCP-PDU that has already been transmitted for the RLC layer function, and for which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the PDCP-PDU (first PDCP-PDU) PDCP-SDU corresponding to the first PDCP-SDU
-PDCP-SDU (second PDCP-SDU) corresponding to a PDCP-PDU (second PDCP-PDU) to which PDCP-SN has already been assigned and has not yet been transmitted to the RLC layer function
-PDCP-SDU (third PDCP-SDU) corresponding to a PDCP-PDU (third PDCP-PDU) that has not yet been granted PDCP-SN and has not yet been transmitted to the RLC layer function
Further, the transfer unit 14 is assigned to the PDCP-SN and the second PDCP-SDU assigned to the first PDCP-SDU with respect to the radio base station eNB # 2 that is the handover destination radio base station eNB by the GTP header option. It is configured to forward PDCP-SN.

  However, the COUNT value (Y) to be used for the next PDCP-SDU processing is the sum (X + Z) of the oldest value (X) and the predetermined value (Z) among the COUNT values used for the processing of the first PDCP-PDU. Is greater than), the transfer unit 14 uses this sum (instead of the PDCP-SN that forms the COUNT value (Y) to be used for the next PDCP-SDU processing to the radio base station eNB # 2. X + Z) is configured to forward for PDCP-SN.

  Further, in such a case, the transfer unit 14 does not transfer the PDCP-SN that forms a COUNT value equal to or greater than the sum (X + Z) among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. It is configured.

  The predetermined value (Z) is a value smaller than the size (2048) of “Rx_reordering_window” used in the PDCP layer function of the mobile station UE.

  For example, the predetermined value (Z) may be “2047” which is smaller by “1” than the size (2048) of “Rx_reordering_window”.

  Hereinafter, the operation of the radio base station eNB # 1 according to the present embodiment will be described with reference to FIG.

  As shown in FIG. 3, in step S101, the radio base station eNB # 1 determines that the COUNT value (Y) scheduled to be used for the next PDCP-SDU processing is the first PDCP-PDU processing in the above handover procedure. It is determined whether or not it is larger than the sum (X + Z) of the oldest value (X) and the predetermined value (Z) among the used COUNT values.

  If “YES”, the operation proceeds to step S104, and if “NO”, the operation proceeds to step S102.

  In step S102, the radio base station eNB # 1 transfers the first PDCP-SDU, the second PDCP-SDU, and the third PDCP-SDU to the radio base station eNb # 2, and also uses the GTP header option to transfer the first PDCP-SDU. And the PDCP-SN assigned to all of the second PDCP-SDUs.

  In step S103, the radio base station eNB # 1 transfers the HFN and PDCP-SN that form the COUNT value (Y) scheduled to be used for the next PDCP-SDU processing to the radio base station eNb # 2.

  On the other hand, in step S104, the radio base station eNB # 1 transfers the first PDCP-SDU, the second PDCP-SDU, and the third PDCP-SDU to the radio base station eNb # 2.

  In addition, the radio base station eNB # 1 uses the GTP header option to the radio base station eNb # 2, and among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU, the sum (X + Z Only transfer PDCP-SNs that form COUNT values less than).

  That is, even if the radio base station eNB # 1 is the COUNT value used for the processing of the first PDCP-SDU and the second PDCP-SDU, the PDCP-SN that forms the COUNT value equal to or greater than the above sum (X + Z) The data is not transferred to the radio base station eNb # 2.

  In step S105, the radio base station eNB # 1 transfers the HFN and PDCP-SN that form the COUNT value (X + Z) corresponding to the above-described sum to the radio base station eNb # 2.

  Hereinafter, the operation of the mobile communication system according to the present embodiment will be described with reference to FIGS. 4 to 6.

  First, as shown in FIG. 4, in the radio base station # 1, until the PDCP-PDU processed by using “HFN: 0” and “PDCP-SN: 4095”, the delivery confirmation in the RLC layer function is not performed. In this state, the handover procedure from the cell # 1 to the cell # 2 of the mobile station UE starts.

  In such a handover procedure, the radio base station eNB # 1 transfers the following information to the radio base station eNB # 2.

-HFN and PDCP-SN “HFN: 1” and “PDCP-SN: 2047” that form the COUNT value that will be used to process the next DL-PDCP-SDU
-The first PDCP corresponding to the first PDCP-PDU that is already transmitted for the RLC layer function and for which RLC-ACK has not been confirmed for all the RLC-PDUs corresponding to the PDCP-PDU. -SDU ("HFN: 1" and "PDCP-SN: 0/1")
A second PDCP-SDU (“HFN: 1” and “PDCP-SN: 2-2047” corresponding to a second PDCP-PDU to which the PDCP-SN has already been assigned and has not yet been transmitted to the RLC layer function; ")
A third PDCP-SDU (“HFN: 1” and “PDCP-SN: 2048−”) corresponding to a third PDCP-PDU that has not yet been granted a PDCP-SN and has not yet been transmitted to the RLC layer function; ")
Here, the radio base station eNB # 1 is used for processing the first PDCP-PDU among the COUNT values used for PDCP-SDU processing with respect to the radio base station eNB # 2 by the GTP header option. The COUNT value less than the sum of the oldest values (“HFN: 1” and “PDCP-SN: 0”) and the predetermined value (2047) (“HFN: 1” and “PDCP-SN: 2047”) among the COUNT values. “PDCP-SN: 0 to 2046” to be formed is notified.

  That is, the radio base station eNB # 1 is configured not to notify “PDCP-SN: 2047” to the radio base station eNB # 2 by the GTP header option.

  Secondly, as shown in FIG. 5, in the transmission path between the radio base station eNB # 1 and the radio base station eNB # 2, “HFN: 1” and “PDCP-SN: 0-2046” are used. PDCP-SDUs corresponding to the processed PDCP-PDUs and PDCP-SDUs scheduled to be processed using “HFN: 1” and “PDCP-SN: 2047” are all lost due to bulk packet loss.

  Thirdly, as shown in FIG. 6, the radio base station eNB # 2 starts transmission to the mobile station UE from the PDCP-PDU processed using “HFN: 1” and “PDCP-SN: 2047”. Is configured to do.

  Here, the mobile station UE can receive the PDCP-PDU processed using “HFN: 1” and “PDCP-SN: 2047” within “Rx_reordering_window”.

  Therefore, the mobile station UE can update “Rx_reordering_window”, that is, can increment the HFN in accordance with the radio base station eNB # 2.

  Therefore, according to the mobile communication system according to the present embodiment, even when a bulk packet loss occurs in the transmission path between the radio base station eNB # 1 and the radio base station eNB # 2, the radio base station Occurrence of inconsistency of HFN between eNB # 2 and mobile station UE can be avoided.

  Moreover, even if the processing using the COUNT value and the assignment of the PDCP-SN have already been performed, the PDCP-SDU may be discarded in the radio base station eNB # 1, and the discarded PDCP-SDU is transferred to the RLC. -When it is regarded as a PDCP-SDU whose ACK has not been confirmed, the above-described control may be performed based on an inappropriate COUNT value.

  Therefore, it can be considered that the PDCP-SDU discarded by the radio base station eNB # 1 has been confirmed as RLC ACK.

  Further, regarding the condition that the RLC-ACK can be confirmed for the discarded PDCP-SDU, the RLC-ACK was confirmed for all of at least one of the PDCP-PDUs subsequent to the discarded PDCP-SDU. In this case, it may be considered that RLC-ACK has been confirmed for the discarded PDCP-SDU.

  The characteristics of the present embodiment described above may be expressed as follows.

  The first feature of the present embodiment is that cell # 1 subordinate to radio base station eNB # 2 (second radio base station) to cell # 1 subordinate to radio base station eNB # 1 (first radio base station) of mobile station UE In the radio base station eNB # 1, the PDCP layer function 11 performs processing using the COUNT value for PDCP-SDU received from the higher layer function and PDCP -It is configured to generate a PDCP-PDU by transmitting an SN and transmit the PDCP-PDU to the RLC layer function 12. In the mobile station UE, the PDCP layer function 11 receives the received PDCP- When the PDCP-SN attached to the PDU is a value outside the order correction window, the PDCP-PDU is configured to be discarded. One PDCP-PDU is a PDCP-PDU that has already been transmitted to the RLC layer function 12 and RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed. The PDU is a PDCP-PDU that has already been subjected to processing using the COUNT value and PDCP-SN and has not yet been transmitted to the RLC layer function 12, and is used for processing of the next PDCP-SDU. When the COUNT value (Y) to be used is larger than the sum of the oldest value (X) and the predetermined value (Z) among the COUNT values used for the processing of the first PDCP-PDU, the radio base station eNB # 1 In the handover procedure described above, the wireless base station eNB # 2 is provided with the COUNT value (Y) scheduled to be used for the next PDCP-SDU processing. In place of the PDCP-SN to be formed, the PDCP-SN that transfers such a sum is transferred, and the PDCP that forms a COUNT value equal to or greater than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. -SN is configured not to be transferred, and the predetermined value (Z) is smaller than the size of the order correction window.

  The second feature of the present embodiment is that the radio in the mobile communication system is capable of performing a handover procedure from the cell # 1 under the radio base station eNB # 1 of the mobile station UE to the cell # 2 under the radio base station eNB # 2. The base station eNB # 1 includes a PDCP layer function 11 and a transfer unit 14. The PDCP layer function 11 performs processing using the COUNT value for the PDCP-SDU received from the higher layer function, and The PDCP-PDU is configured to be generated and transmitted to the RLC layer function 12 by providing the PDCP-SN, and the first PDCP-PDU is already transmitted to the RLC layer function 12. PDCP- that has been transmitted and RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the first PDCP-PDU The second PDCP-PDU is a DU that has already been subjected to processing using the COUNT value and PDCP-SN, and has not yet been transmitted to the RLC layer function 12. When the COUNT value (Y) scheduled to be used for processing the PDCP-SDU is greater than the sum of the oldest value (X) and the predetermined value (Z) among the COUNT values used for processing the first PDCP-PDU, In the handover procedure described above, the transfer unit 14 forms such a sum for the radio base station eNB # 2 instead of the PDCP-SN that forms the COUNT value (Y) used for the next PDCP-SDU processing. Transfer the PDCP-SN, and form a COUNT value greater than or equal to the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. For PDCP-SN is configured to not forward a predetermined value (Z) is summarized in that a value smaller than the size of the reordering window used in the PDCP layer function of the mobile station UE.

(Example of change)
Although the present invention has been described in detail using the above-described embodiments, it is obvious to those skilled in the art that the present invention is not limited to the embodiments described in this specification.

  For example, in the present embodiment, the case where data transfer associated with a handover between different radio base stations eNB # 1 and eNB # 2 has been described as an example. The present invention may be applied to a case where handover or reconnection processing is performed in a radio base station.

  That is, in the case of performing a handover or reconnection procedure from the first cell under the radio base station eNB of the mobile station to the second cell, the above-described handover source radio base station eNB # 1 is the first cell of the radio base station eNB. It is assumed that the handover destination radio base station eNB # 2 corresponds to a function of managing the second cell of the radio base station eNB.

  The characteristics of the modified example may be expressed as follows.

  A first feature of the present modification is a mobile communication system capable of performing a reconnection procedure (or a handover procedure) from the first cell under the radio base station eNB of the mobile station UE to the second cell, In the base station eNB, the PDCP layer function 11 generates a PDCP-PDU by performing processing using the COUNT value and granting the PDCP-SN to the PDCP-SDU received from the higher layer function, When the mobile station UE is configured to transmit to the RLC layer function 12, the PDCP layer function 11 indicates that the PDCP-SN assigned to the received PDCP-PDU is a value outside the order correction window. The PDCP-PDU is configured to be discarded, and the first PDCP-PDU is transmitted to the RLC layer function 12. It is a PDCP-PDU that has already been transmitted and for which RLC-ACK has not been confirmed for all RLC-PDUs corresponding to the first PDCP-PDU, and the second PDCP-PDU includes processing using the COUNT value and PDCP-PDU. An SN is already assigned and is a PDCP-PDU that has not been transmitted to the RLC layer function 12, and the COUNT value (Y) to be used for the next PDCP-SDU processing is the first PDCP. -The function of managing the first cell of the radio base station eNB when it is larger than the sum of the oldest value (X) and the predetermined value (Z) among the COUNT values used for PDU processing is the reconnection procedure described above (Or handover procedure) In the function of managing the second cell of the radio base station eNB, the COUNT scheduled to be used for the next PDCP-SDU processing Instead of the PDCP-SN forming the value (Y), transfer is performed for the PDCP-SN forming the sum, and the COUNT value equal to or larger than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. The PDCP-SN that forms the value is configured not to be transferred, and the gist is that the predetermined value (Z) is a value smaller than the size of the order correction window.

  The second feature of the present modification is that the first cell and the second cell in the mobile communication system capable of performing a reconnection procedure (or a handover procedure) from the first cell to the second cell of the mobile station UE. The radio base station eNB to be managed has a PDCP layer function 11, a function for managing the first cell, and a function for managing the second cell. The PDCP layer function 11 receives from the upper layer function. The PDCP-SDU is configured to generate a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN, and transmit the PDCP-PDU to the RLC layer function 12. The first PDCP-PDU has already been transmitted to the RLC layer function 12, and the R for all RLC-PDUs corresponding to the first PDCP-PDU. The PDCP-PDU in which C-ACK has not been confirmed, the second PDCP-PDU has already been processed using the COUNT value and the PDCP-SN has been added, and is still transmitted to the RLC layer function 12 The COUNT value (Y) to be used for the next PDCP-SDU is the oldest value (X) and the predetermined value among the COUNT values used for the first PDCP-PDU processing. When the sum is larger than the sum of (Z), the function of managing the first cell is the next PDCP-SDU processing for the function of managing the second cell in the reconnection procedure (or handover procedure) described above. Instead of the PDCP-SN forming the COUNT value (Y) used for the transfer, the PDCP-SN forming the sum is transferred, and the first PDCP-SDU and the second PDCP-SN are transferred. The PDCP-SN that forms a COUNT value equal to or greater than the sum among the COUNT values used for processing of the DU is configured not to be transferred, and the predetermined value (Z) is used in the PDCP layer function of the mobile station UE. The gist is that the value is smaller than the size of the order correction window.

  Here, the first cell and the second cell may be different cells or the same cell. That is, the present invention can also be applied to intra-cell handover.

  Further, for example, the present invention has been described using “the oldest value (X) among the COUNT values used for the processing of the first PDCP-PDU”, but “of the PDCP-PDUs in which RLC-ACK was confirmed” The COUNT value used for processing the PDCP-PDU with the youngest COUNT value ”may be used. In this case, Z takes a value equal to or smaller than the size of the order correction window.

  Note that the operations of the radio base stations eNB # 1 / eNB # 2 and the mobile station UE described above may be implemented by hardware, may be implemented by a software module executed by a processor, or a combination of both May be implemented.

  The software module includes a RAM (Random Access Memory), a flash memory, a ROM (Read Only Memory), an EPROM (Erasable Programmable ROM), an EEPROM (Electronically Erasable and Programmable ROM, a hard disk, a registerable ROM, a hard disk). Alternatively, it may be provided in a storage medium of an arbitrary format such as a CD-ROM.

  Such a storage medium is connected to the processor so that the processor can read and write information from and to the storage medium. Further, such a storage medium may be integrated in the processor. Such a storage medium and processor may be provided in the ASIC. Such an ASIC may be provided in the radio base station eNB # 1 / eNB # 2 or the mobile station UE. Further, the storage medium and the processor may be provided in the radio base station eNB # 1 / eNB # 2 or the mobile station UE as a discrete component.

  The present invention can be implemented as modified and changed modes without departing from the spirit and scope of the present invention defined by the description of the scope of claims. Therefore, the description of the present specification is for illustrative purposes and does not have any limiting meaning to the present invention.

eNB # 1, eNB # 2 ... radio base station UE ... mobile station 11 ... PDCP layer function 12 ... RLC layer function 13 ... transmitting unit 14 ... forwarding unit

Claims (14)

A mobile communication system capable of performing a handover procedure from a cell under a first radio base station of a mobile station to a cell under a second radio base station,
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
In the first radio base station, the PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and granting the PDCP-SN to the PDCP-SDU received from the higher layer function, Configured to transmit to the RLC layer function,
In the mobile station, the PDCP layer function is configured to discard the PDCP-PDU when the PDCP-SN forming the COUNT value assigned to the received PDCP-PDU is a value outside the order correction window. And
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
If the COUNT value to be used for the next PDCP-SDU processing is greater than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, the first radio base station In the handover procedure, the PDCP-SN that forms the sum is transferred to the second radio base station instead of the PDCP-SN that forms the COUNT value to be used for the next PDCP-SDU processing. The PDCP-SN that forms the COUNT value equal to or greater than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU is configured not to be transferred.
Wherein the predetermined value, Ri smaller der than the size of the reordering window,
The reordering window, the mobile communication system characterized that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station . A radio base station operable as the first radio base station in a mobile communication system capable of performing a handover procedure from a cell under the first radio base station of the mobile station to a cell under the second radio base station,
PDCP layer function,
And a transfer unit,
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
The PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the upper layer function, and transmits the PDCP-PDU to the RLC layer function Is configured to
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
When the COUNT value scheduled to be used for the next PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the processing of the first PDCP-PDU, the transfer unit performs the handover In the procedure, instead of the PDCP-SN forming the COUNT value scheduled to be used for the next PDCP-SDU processing, the PDCP-SN forming the sum is transferred to the second radio base station, Among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU, the PDCP-SN forming the COUNT value equal to or greater than the sum is not transferred.
The predetermined value is a value smaller than the size of the order correction window used in the PDCP layer function of the mobile station,
The reordering window, the radio base station, wherein that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station . A mobile communication system capable of performing a reconnection procedure from a first cell to a second cell under a radio base station of a mobile station,
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
In the radio base station, the PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the higher layer function, and generates an RLC layer. Configured to send to the feature,
In the mobile station, the PDCP layer function is configured to discard the PDCP-PDU when the PDCP-SN forming the COUNT value assigned to the received PDCP-PDU is a value outside the order correction window. And
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
When the COUNT value scheduled to be used for the next PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, In the reconnection procedure, the function of managing one cell is a PDCP− that forms a COUNT value to be used for processing of the next PDCP-SDU with respect to the function of managing the second cell of the radio base station. Instead of the SN, the PDCP-SN forming the sum is transferred, and the PDCP-SN forming the COUNT value equal to or larger than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. Is configured not to forward,
Wherein the predetermined value, Ri smaller der than the size of the reordering window,
The reordering window, the mobile communication system characterized that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station .   The mobile communication system according to claim 3, wherein the first cell and the second cell are the same cell.   The mobile communication system according to any one of claims 1 to 3, wherein the PDCP-SN is notified by a GTP header option. A radio base station that manages the first cell and the second cell in a mobile communication system capable of performing a reconnection procedure from the first cell of the mobile station to the second cell,
PDCP layer function,
A function of managing the first cell;
A function of managing the second cell;
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
The PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the upper layer function, and transmits the PDCP-PDU to the RLC layer function Is configured to
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
If the COUNT value scheduled to be used for the next PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, the first cell is managed. In the reconnection procedure, the function forms the sum instead of the PDCP-SN that forms the COUNT value to be used for processing the next PDCP-SDU for the function of managing the second cell. It is configured to transfer the PDCP-SN and not to transfer the PDCP-SN forming the COUNT value equal to or greater than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU. ,
Wherein the predetermined value, Ri smaller der than the size of the reordering window used in the PDCP layer function of the mobile station,
The reordering window, the radio base station, wherein that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station .   The radio base station according to claim 6, wherein the first cell and the second cell are the same cell.   The radio base station according to claim 6, wherein the PDCP-SN is notified by a GTP header option. A mobile communication system capable of performing a handover procedure from a first cell under a radio base station of a mobile station to a second cell,
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
In the radio base station, the PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the higher layer function, and generates an RLC layer. Configured to send to the feature,
In the mobile station, the PDCP layer function is configured to discard the PDCP-PDU when the PDCP-SN forming the COUNT value assigned to the received PDCP-PDU is a value outside the order correction window. And
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
When the COUNT value scheduled to be used for the next PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, The function of managing one cell is a PDCP-SN that forms a COUNT value to be used for processing of the next PDCP-SDU in the handover procedure with respect to the function of managing the second cell of the radio base station. Instead of the PDCP-SN that forms the sum, and the PDCP-SN that forms the COUNT value greater than or equal to the sum among the COUNT values used in the processing of the first PDCP-SDU and the second PDCP-SDU. Is configured to not forward,
Wherein the predetermined value, Ri smaller der than the size of the reordering window,
The reordering window, the mobile communication system characterized that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station .   The mobile communication system according to claim 9, wherein the first cell and the second cell are the same cell.   The mobile communication system according to claim 9, wherein the PDCP-SN is notified by a GTP header option. A radio base station that manages the first cell and the second cell in a mobile communication system capable of performing a handover procedure from the first cell of the mobile station to the second cell,
PDCP layer function,
A function of managing the first cell;
A function of managing the second cell;
The COUNT value is a value having HFN as the upper bits and PDCP-SN as the lower bits,
The HFN is configured to be incremented each time the PDCP-SN makes a round,
The PDCP-SN is configured to be incremented every time a PDCP-PDU is generated in the PDCP layer function,
The PDCP layer function generates a PDCP-PDU by performing processing using the COUNT value and assigning the PDCP-SN to the PDCP-SDU received from the upper layer function, and transmits the PDCP-PDU to the RLC layer function Is configured to
The first PDCP-PDU is a PDCP-PDU that has already been transmitted for the RLC layer function and the RLC-ACK for all the RLC-PDUs corresponding to the first PDCP-PDU has not been confirmed.
The second PDCP-PDU is a PDCP-PDU that has already been subjected to the processing using the COUNT value and the addition of the PDCP-SN and has not yet been transmitted to the RLC layer function,
If the COUNT value scheduled to be used for the next PDCP-SDU processing is larger than the sum of the oldest value and the predetermined value among the COUNT values used for the first PDCP-PDU processing, the first cell is managed. For the function of managing the second cell in the handover procedure, the function is the PDCP that forms the sum instead of the PDCP-SN that forms the COUNT value to be used for processing the next PDCP-SDU. -SN is transferred, and PDCP-SN that forms a COUNT value equal to or greater than the sum among the COUNT values used for the processing of the first PDCP-SDU and the second PDCP-SDU is configured not to transfer,
Wherein the predetermined value, Ri smaller der than the size of the reordering window used in the PDCP layer function of the mobile station,
The reordering window, the radio base station, wherein that you have been configured PDCP-PDU to PDCP-SN in the reordering window is applied is updated when it is received at the mobile station .   The radio base station according to claim 12, wherein the first cell and the second cell are the same cell.   The radio base station according to claim 12, wherein the PDCP-SN is notified by a GTP header option.

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