JP4336792B2 - Packet transmission method and radio access network - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a packet communication technique, and more particularly to a technique for enhancing packet error resistance.
[0002]
[Prior art]
If an error occurs during packet transmission and the checksum calculation result performed in the upper layer on the receiving side becomes an error, the packet is discarded and the service quality deteriorates. Particularly in data transmission / reception using UDP (User Datagram Protocol) without retransmission control, degradation of service quality due to packet discard becomes a serious problem.
[0003]
Therefore, conventionally, the following techniques have been proposed in order to enhance the error tolerance of the packet and reduce the probability of the packet being discarded.
[0004]
A packet to be transmitted is segmented to generate a plurality of packet segments. Thereafter, an error correction code to be applied to each packet segment is selected from a plurality of error correction methods (error correction codes) prepared in advance according to a predetermined standard. Then, the selected error correction code is added to each packet segment and transmitted to the network (see, for example, Patent Document 1).
[0005]
[Patent Document 1]
JP-A-2000-78197 [0006]
[Problems to be solved by the invention]
According to the conventional technique described above, it is possible to enhance the error tolerance of a packet. However, since an error correction code must be added to each packet segment, there is a problem that the amount of data transmission increases.
[0007]
Accordingly, an object of the present invention is to enhance packet error resistance without increasing the amount of data transmission.
[0008]
[Means for Solving the Problems]
In order to achieve the above object, a first packet transmission method according to the present invention provides:
A first step in which the PDCP generates a transmission unit PDCP PDU by compressing the IP header part of the data unit PDCP SDU received from the upper layer;
When the PDCP transmits the transmission unit PDCP PDU as it is to the RLC, padding to be filled in the RLC so as to segment the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size. A second step for determining the size of
The PDCP is a plurality of types of error correction schemes different in error correction capability supported by the own PDCP, and includes an error correction scheme for correcting an error generated in the data by adding an error correction code to the data. From the error correction methods in which the size of the error correction code generated for the transmission unit PDCP PDU is equal to or less than the size of the padding to be filled, the size of the error correction code to be generated is the largest in the padding size. A third step of selecting the closest one ;
A fourth step in which the PDCP generates an error correction code for the transmission unit PDCP PDU using the selected error correction method;
The PDCP adds the type information indicating the type of the error correction method selected in the third step and the error correction code generated in the fourth step to the transmission unit PDCP PDU and transmits it to the RLC. 5 steps,
The RLC segments the transmission unit PDCP PDU added with the error correction code and type information received from the PDCP into a plurality of transmission units RLC PDUs of the predetermined size by filling padding as necessary, And transmitting each segmented transmission unit RLC PDU to the network.
[0010]
A second packet transmission method according to the present invention is the first packet transmission method,
Seventh step of receiving side RLC restoring transmission unit PDCP PDU before segmentation based on each transmission unit RLC PDU sent from RLC, and sending the restored transmission unit PDCP PDU to receiving side PDCP When,
When the receiving side PDCP expands the compressed IP header part in the transmission unit PDCP PDU received from the receiving side RLC, and the error correction code and type information are included in the transmission unit PDCP PDU, An error check is performed on the part excluding the error correction code and type information of the transmission unit PDCP PDU in which the IP header is expanded, and if there is an error, the error correction code is used to correct the error. And 8 steps.
[0011]
A first radio access network according to the present invention is:
With PDCP and RLC,
The PDCP generates a transmission unit PDCP PDU by compressing the IP header part of the data unit PDCP SDU received from an upper layer, and when the transmission unit PDCP PDU is transmitted to the RLC as it is, the RLC A structure for obtaining the size of padding to be filled in order to segment a transmission unit PDCP PDU into a plurality of transmission unit RLC PDUs of a predetermined size, and a plurality of types having different error correction capabilities supported by the own PDCP Among the error correction methods for correcting an error generated in the data by adding an error correction code to the data, the size of the error correction code generated for the transmission unit PDCP PDU is the error correction code. among the error correction method to be less than or equal to the size of padding to be filled, most size of the generated error correction code to the size of the padding Types shown configurations and selecting the close, and configured to generate an error correction code for said transmitting unit PDCP PDU using the error correction method described above selected, the transmission unit PDCP PDU, the type of error correction method described above selected The information and the generated error correction code is added and transmitted to the RLC, and
The RLC segments the transmission unit PDCP PDU added with the error correction code and type information received from the PDCP into a plurality of transmission units RLC PDUs of the predetermined size by filling padding as necessary, The segmented transmission unit RLC PDU is transmitted to the network.
[0013]
A second radio access network according to the present invention is the first radio access network,
Receiving side RLC and receiving side PDCP,
The reception side RLC restores the transmission unit PDCP PDU before segmentation based on each transmission unit RLC PDU sent from the RLC, and transmits the restored transmission unit PDCP PDU to the reception side PDCP. Have
The receiving side PDCP expands the compressed IP header part in the transmission unit PDCP PDU received from the receiving side RLC, and when the transmission unit PDCP PDU includes an error correction code and type information, A configuration in which an error check is performed on a portion excluding the error correction code and type information of the transmission unit PDCP PDU in which the IP header is expanded, and if there is an error, the error correction code is used to correct the error. It is characterized by having.
[0016]
[Action]
The PDCP determines whether or not the error tolerance enhancement information can be added to the transmission unit PDCP PDU generated by compressing the IP header portion of the data unit PDCP SDU received from the upper layer. This determination is performed when the transmission unit PDCP PDU in which the IP header part is compressed is transmitted to the RLC as it is, so that the transmission unit PDCP PDU is segmented into a plurality of transmission unit RLC PDUs of a predetermined size in the RLC. Based on the padding size. For example, if an error correction code is used as the error resilience enhancement information, it is determined that the error resilience enhancement information can be added if the padding size to be filled is equal to or larger than the error correction code size. Also, for example, if a part of the data in the transmission unit PDCP PDU is used as the error resilience enhancement information, it is determined that the error resilience enhancement information can be added when padding is filled. If it is determined that the error resilience enhancement information can be added, the error resilience enhancement information is added to the transmission unit PDCP PDU and transmitted to the RLC. Accordingly, the RLC generates a plurality of transmission unit RLC PDUs by segmenting the transmission unit PDCP PDU including the error resilience enhancement information. Here, when the transmission unit PDCP PDU is transmitted to the RLC as it is, the error resilience enhancement information is added to the portion where the padding is filled, so that the amount of transmission data does not increase.
[0017]
DETAILED DESCRIPTION OF THE INVENTION
Next, embodiments of the present invention will be described in detail with reference to the drawings.
[0018]
FIG. 1 is a block diagram illustrating a configuration example of a mobile communication system to which the present invention is applied, and includes a core network CN, a radio access network RAN, and a mobile UE.
[0019]
The radio access network RAN is composed of a radio network controller RNC and a node B, and is connected to a core network CN, which is an exchange network, via an interface Iu.
[0020]
The radio network controller RNC performs radio resource management, node B control, and the like. The node B is a logical node that performs radio transmission / reception, and is specifically a radio base station apparatus. Node B and the radio network controller RNC are connected via an interface Iub. Node B is connected to mobile device UE via a radio interface. Further, the radio network controllers RNC are connected by a logical interface Iur.
[0021]
FIG. 2 shows a protocol architecture on the radio access network RAN side, and FIG. 3 shows a protocol architecture on the mobile station UE side.
[0022]
As shown in FIG. 2, the radio access network RAN side has a layer (PDCP: Packet Data Convergence Protocol) 21 having a processing function of an IP header part of a packet and a layer (RLC: Radio Link Control) 22 that supports data transmission. And a layer (RRC; Radio Resource Control) 23 having a physical resource management function, and control information is passed from RRC 23 to both PDCP 21 and RLC 22.
[0023]
PDCP21 supports multiple IP header compression methods (RFC 3095 ROHC and other compression methods), and data units PDCP received from higher layers using the compression method indicated by the control information from RRC23. The IP header part in the SDU is compressed to generate a transmission unit PDCP PDU. The upper layer on the transmitting side negotiates with the upper layer on the receiving side via RRC23 and RRC33, thereby determining the compression method for the IP header part, and instructs the determined compression method to PDCP21.
[0024]
In addition, when the generated transmission unit PDCP PDU is transmitted to the RLC 22 as it is, the PDCP 21 performs a padding of a size (Le + Lf) or more in order to segment the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size L in the RLC 22 Has a function of determining whether or not a transmission unit RLC PDU filled with is to be generated. Note that Le is the size of error resilience enhancement information, and Lf is the size of information indicating that error resilience enhancement information is included.
[0025]
Further, when the PDCP 21 determines that a transmission unit RLC PDU filled with padding of size (Le + Lf) or more is to be generated, the error resistance enhancement information and the error tolerance enhancement information are included in the transmission unit PDCP PDU. If the transmission unit RLC PDU filled with padding of size (Le + Lf) or more is determined not to be generated, the transmission unit PDCP PDU is used as it is. It has a function to transmit to RLC22.
[0026]
Here, the error resilience enhancement information is information for enhancing the error resilience of the packet, and in this embodiment, an error correction code generated by a predetermined error correction method is used as the error resilience enhancement information. The predetermined size L is the size of the transmission unit RLC PDU set in the RLC 22 by the RRC 23 using the control information. When the RRC 23 sets the size of the transmission unit RLC PDU in the RLC 22, the size ( Processing for notifying the predetermined size L) is also performed.
[0027]
The RLC 22 segments the transmission unit PDCP PDU received from the PDCP 21 (with or without error tolerance enhancement information) into a plurality of transmission units RLC PDUs of a predetermined size L, It has a function of transmitting each segmented transmission unit RLC PDU to the network. Here, when a transmission unit RLC PDU less than the predetermined size L is generated, padding is filled, and the size of the transmission unit RLC PDU is set to the predetermined size L.
[0028]
On the other hand, as shown in FIG. 3, the mobile device UE side includes a PDCP 31, an RLC 32, an RRC 33, and an upper layer (IP layer) 34.
[0029]
The RLC 32 has a function of restoring the original transmission unit PDCP PDU from a plurality of segmented transmission units RLC PDUs received via the network and transmitting them to the PDCP 31.
[0030]
PDCP31 expands the compressed IP header part for the part excluding error tolerance enhancement information of the transmission unit PDCP PDU received from RLC32, and transmits the original data unit PDCP SDU (the upper layer on the transmission side is PDCP21). (Data unit transmitted to the network) is restored. When decompressing the IP header portion, the IP header portion is decompressed by a decompression method corresponding to the compression method notified from the RRC 33. That is, the RRC 33 notifies the PDCP 31 of the compression method for the IP header portion determined by negotiation between the upper layer on the transmission side and the reception side.
[0031]
Furthermore, the PDCP 31 transmits the data unit PDCP SDU to the upper layer 34 when the checksum calculation function for the restored data unit PDCP SDU and the checksum calculation result for the data unit PDCP SDU are normal. In the case of an error, it has a function of performing error correction on the restored data unit PDCP SDU using the error resilience enhancement information and a function of transmitting the error corrected data unit PDCP SDU to the upper layer 34. .
[0032]
[Description of operation of embodiment]
Next, the operation of this embodiment will be described in detail with reference to the drawings.
[0033]
When receiving the data unit PDCP SDU from the upper layer 24, the PDCP 21 on the transmission side generates a transmission unit PDCP PDU by compressing the IP header portion of the data unit PDCP SDU according to the compression method instructed by the RRC 23 ( (S40, S41 in FIG. 4). The data unit PDCP SDU includes a checksum added by the upper layer 24. Thereafter, the PDCP 21 performs error resilience enhancement information addition processing (S42). This error tolerance enhancement information addition processing will be described with reference to the flowchart of FIG.
[0034]
First, when the transmission unit PDCP PDU generated in step S41 is transmitted to the RLC 22 as it is, in order to segment the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size L in the RLC 22, the error tolerance enhancement information size Le + It is determined whether or not a transmission unit RLC PDU filled with padding equal to or larger than the size Lf) of information indicating that error resilience enhancement information is included (S50 in FIG. 5).
[0035]
This judgment is, for example,
(Size of transmission unit PDCP PDU generated in step S41) ÷ {(size L of transmission unit RLC PDU notified from RRC23) − (size of header part of transmission unit RLC PDU)}
By calculating whether or not the remainder (padding size Lp) is equal to or larger than (size Le of error resilience enhancement information + size Lf of information indicating that error resilience enhancement information is included). Do. That is, if the padding size Lp is equal to or greater than (Le + Lf), the determination result in step S50 is YES, otherwise the determination result in step S50 is NO.
[0036]
If the decision result in step S50 is YES, an error correction code corresponding to a predetermined error correction method is generated and used as error resilience enhancement information (S51). Thereafter, the transmission unit PDCP PDU is added with error resilience enhancement information and information indicating that the error resilience enhancement information is included, and transmitted to the RLC 22 (S52). On the other hand, if the determination result in step S50 is NO, the transmission unit PDCP PDU generated in step S41 of FIG. 4 is transmitted to the RLC 22 as it is (S53).
[0037]
Now, for example, if the transmission unit PDCP PDU generated in step S41 is the one shown in FIG. 6A, if the determination result in step S50 is YES, the error resilience enhancement information and When the transmission unit PDCP PDU shown in FIG. 6 (B) to which information indicating that it is included is added is transmitted to the RLC 22, and the determination result in step S50 is NO, FIG. 6 (A) The transmission unit PDCP PDU shown in FIG.
[0038]
When receiving the transmission unit PDCP PDU from the PDCP 21, the RLC 22 segments it into a plurality of transmission units RLC PDUs of a predetermined size L (S43 in FIG. 4). For example, assuming that the transmission unit PDCP PDU shown in FIG. 6B is received, the RLC 22 is segmented into two transmission units RLC PDU1 and RLC PDU2 shown in FIG. The first transmission unit RLC PDU1 includes an RLC header part, an IP header part, and a first half of data included in the transmission unit PDCP PDU, and the second transmission unit RLC PDU2 includes an RLC header part. And the latter half of the data included in the transmission unit PDCP PDU, error resilience enhancement information, information indicating that the resilience enhancement information is included, and padding. The sizes of the transmission units RLC PDU1 and RLC PDU2 are both “L”. In the example of FIG. 6C, the second transmission unit RLC PDU2 is filled with padding, but if the size is “L” without padding, The padding is not filled.
[0039]
Thereafter, the RLC 22 sends each segmented transmission unit RLC PDU to the network (S44).
[0040]
When the RLC 32 on the receiving side receives each segmented transmission unit RLC PDU from the RLC 22 on the transmitting side via the network, it restores the transmission unit PDCP PDU before being segmented based on them and transmits it to the PDCP 31. (S45).
[0041]
When the PDCP 31 receives the transmission unit PDCP PDU from the RLC 32, the error resistance enhancement information in the transmission unit, information indicating that the error tolerance enhancement information is included, and padding (the padding may not be included) The compressed IP header part is expanded for the part excluding, and the original data unit PDCP SDU (data unit received by the PDCP 21 on the transmission side from the upper layer 24) is restored (S46). After that, if error tolerance enhancement information is included in the transmission unit PDCP PDU, the PDCP 31 performs error detection and correction processing (S47). The error detection and correction process performed in step S47 will be described in detail with reference to FIG. If the error tolerance enhancement information is not included in the transmission unit PDCP PDU, the PDCP 31 transmits the original data unit PDCP SDU with the IP header portion expanded to the upper layer 34.
[0042]
First, checksum calculation is performed on the restored data unit PDCP SDU (S71 in FIG. 7). If the calculation result is normal (S72 is NO), the data unit PDCP SDU is transmitted to the upper layer 34 (S74). On the other hand, if the calculation result is an error (YES in S72), error correction for the data unit PDCP SDU is performed using the error resilience enhancement information (error correction code) included in the data unit PDCP SDU. Processing is performed (S73), and the error-corrected data unit PDCP SDU is transmitted to the upper layer 34 (S74).
[0043]
Upon receiving the data unit PDCP SDU from the PDCP 31, the upper layer 34 performs processing unique to the upper layer (S48). This process includes a process of calculating the checksum and discarding the data unit PDCP SDU (packet) when the calculation result is an error.
[0044]
Other Embodiments of the Invention
In the above-described embodiment, the error correction code generated by a predetermined error correction method is used as the error tolerance enhancement information. However, PDCP21 has N types (N is a plurality) of different error correction capabilities. An error correction method is supported, and an optimal error correction method is selected based on the padding size Lp and the error correction code sizes Le1 to LeN generated by each error correction method. The generated error correction code may be used as error tolerance enhancement information. As the selection method of the optimum error correction method, for example, the size Lej (1 ≦ j ≦ N) of the error correction code to be generated and the size of information indicating the type of the error correction method used when generating the error resilience enhancement information A method of selecting the total size with Lf ′ (Lej + Lf ′) or the padding size Lp or less and closest to the padding size Lp can be employed. In general, the larger the error correction code, the higher the error correction capability. By doing the above, select the error correction method with the highest error correction capability within the range that does not increase the amount of transmission data. Is possible.
[0045]
The above-described embodiment can be realized by changing the processing of steps S50, S51, and S52 in the flowchart of FIG. 5 and the processing of step S73 in the flowchart of FIG. 7 as follows.
[0046]
Step S50: When the transmission unit PDCP PDU generated in step S41 is transmitted to the RLC 22 as it is, the RLC 22 segments the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size L. It is determined whether or not a transmission unit RLC PDU filled with padding of size Le + size of information indicating the type of error correction method used when generating the error resilience enhancement information Lf ′) or more is to be generated. To do.
[0047]
Step S51: One optimal error correction method is selected from the N types of error correction methods supported. An error correction code is generated by the selected error correction method and used as error tolerance enhancement information. As a method for selecting an optimal error correction method, for example, a method of selecting a method in which (Lej + Lf ′) is equal to or smaller than the padding size Lp and closest to the padding size Lp can be employed.
[0048]
Step S52: The error resistance enhancement information (error correction code) generated in step S51 and the information indicating the type of error correction method that generated the error tolerance enhancement information are added to the transmission unit PDCP PDU and transmitted to the RLC 22 .
[0049]
Step S73: An error correction process is performed on the data unit PDCP SDU using the error resilience enhancement information and information indicating the type of error correction method.
[0050]
In each of the above-described embodiments, an error correction code is used as the error resilience enhancement information. However, some data in the transmission unit PDCP PDU can be used as the error resilience enhancement information. In other words, error resilience can be enhanced by duplicating data. The embodiment in which error resilience is strengthened by duplicating this data can be realized by changing the processing of steps S50, S51, S52 of the flowchart of FIG. 5 and step S73 of the flowchart of FIG. 7 as follows.
[0051]
Step S50: When the transmission unit PDCP PDU generated in step S41 is transmitted as it is to the RLC 22, the data duplication portion is indicated in order to segment the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size L in the RLC 22 It is determined whether or not a transmission unit RLC PDU filled with padding larger than the size Lf ″ of information (duplicated partial display information) is to be generated.
[0052]
Step S51: Acquire data (padding size Lp−duplicate partial display information size Lf ”) from the transmission unit PDCP PDU and use it as error tolerance enhancement information. Which part of the data part of the transmission unit PDCP PDU However, in this embodiment, the data for the size is acquired from the beginning of the data portion, and in this embodiment, an error is detected from the beginning of the data portion. Since the robustness enhancement information is obtained and the duplicated portion of the data can be specified only by the size of the errorworthiness enhancement information, the size of the error tolerance enhancement information = (Lp-Lf ") is used as the duplicated portion display information. To do.
[0053]
Step S52: The error tolerance enhancement information and the duplicated partial display information are added to the transmission unit PDCP PDU and transmitted to the RLC 22.
[0054]
Step S73: An error correction process is performed on the data unit PDCP SDU based on the error resilience enhancement information and the duplicated partial display information. That is, error correction processing is performed by replacing the data specified by the duplicated partial display information in the data unit PDCP SDU with the error tolerance enhancement information.
[0055]
【The invention's effect】
As described above, according to the present invention, since error resilience enhancement information is transmitted using a portion that has been filled with padding in the past, packet error resilience can be improved without increasing the amount of transmission data. Can be strengthened.
[0056]
In addition, the present invention supports a plurality of error correction schemes having different error correction capabilities, and generates error tolerance enhancement information from a plurality of types of error correction schemes when adding error tolerance enhancement information to a transmission unit PDCP PDU. Select an error correction method whose error correction code size is equal to or smaller than the padding size to be filled and which is closest to the padding size, and transmit the error correction code generated by the selected error correction method to the transmission unit PDCP Since it is added to the PDU, it is possible to enhance the error tolerance of the packet as much as possible without increasing the amount of transmission data.
[Brief description of the drawings]
FIG. 1 is a block diagram showing a configuration example of a mobile communication system to which the present invention is applied.
FIG. 2 is a diagram showing a protocol architecture on the radio access network RAN side.
FIG. 3 is a diagram showing a protocol architecture on a mobile device UE side.
FIG. 4 is a flowchart showing an outline of the operation of the embodiment of the present invention.
FIG. 5 is a flowchart showing a detailed processing example of error resilience enhancement information addition processing performed by a PDCP 21 on the transmission side.
FIG. 6 is a diagram for explaining the operation of PDCP 21 and RLC 22 on the transmitting side.
FIG. 7 is a flowchart showing a detailed processing example of error detection and correction processing performed by PDCP 31 on the receiving side.
[Explanation of symbols]
CN ... Core network
RAN ... Radio access network
RNC ... Radio control device
B ... Node
UE ... mobile
21 ... PDCP
22… RLC
23… RRC
24… Upper layer
31 ... PDCP
32… RLC
33… RRC
34 ... upper layer

Claims (4)

A first step in which the PDCP generates a transmission unit PDCP PDU by compressing the IP header part of the data unit PDCP SDU received from the upper layer;
When the PDCP transmits the transmission unit PDCP PDU as it is to the RLC, padding to be filled in the RLC so as to segment the transmission unit PDCP PDU into a plurality of transmission units RLC PDUs of a predetermined size. A second step for determining the size of
The PDCP is a plurality of types of error correction schemes different in error correction capability supported by the own PDCP, and includes an error correction scheme for correcting an error generated in the data by adding an error correction code to the data. From the error correction methods in which the size of the error correction code generated for the transmission unit PDCP PDU is equal to or less than the size of the padding to be filled, the size of the error correction code to be generated is the largest in the padding size. A third step of selecting the closest one ;
A fourth step in which the PDCP generates an error correction code for the transmission unit PDCP PDU using the selected error correction method;
The PDCP adds the type information indicating the type of the error correction method selected in the third step and the error correction code generated in the fourth step to the transmission unit PDCP PDU and transmits it to the RLC. 5 steps,
The RLC segments the transmission unit PDCP PDU added with the error correction code and type information received from the PDCP into a plurality of transmission units RLC PDUs of the predetermined size by filling padding as necessary, And a sixth step of transmitting each segmented transmission unit RLC PDU to the network. The packet transmission method according to claim 1 ,
Seventh step of receiving side RLC restoring transmission unit PDCP PDU before segmentation based on each transmission unit RLC PDU sent from RLC, and sending the restored transmission unit PDCP PDU to receiving side PDCP When,
When the receiving side PDCP expands the compressed IP header part in the transmission unit PDCP PDU received from the receiving side RLC, and the error correction code and type information are included in the transmission unit PDCP PDU, An error check is performed on the part excluding the error correction code and type information of the transmission unit PDCP PDU in which the IP header is expanded, and if there is an error, the error correction code is used to correct the error. And a step of transmitting packets. With PDCP and RLC,
The PDCP generates a transmission unit PDCP PDU by compressing the IP header part of the data unit PDCP SDU received from an upper layer, and when the transmission unit PDCP PDU is transmitted to the RLC as it is, the RLC A structure for obtaining the size of padding to be filled in order to segment a transmission unit PDCP PDU into a plurality of transmission unit RLC PDUs of a predetermined size, and a plurality of types having different error correction capabilities supported by the own PDCP Among the error correction methods for correcting an error generated in the data by adding an error correction code to the data, the size of the error correction code generated for the transmission unit PDCP PDU is the error correction code. among the error correction method to be less than or equal to the size of padding to be filled, most size of the generated error correction code to the size of the padding Types shown configurations and selecting the close, and configured to generate an error correction code for said transmitting unit PDCP PDU using the error correction method described above selected, the transmission unit PDCP PDU, the type of error correction method described above selected The information and the generated error correction code is added and transmitted to the RLC, and
The RLC segments the transmission unit PDCP PDU added with the error correction code and type information received from the PDCP into a plurality of transmission units RLC PDUs of the predetermined size by filling padding as necessary, A radio access network having a configuration for transmitting each segmented transmission unit RLC PDU to a network. The radio access network according to claim 3 ,
Receiving side RLC and receiving side PDCP,
The reception side RLC restores the transmission unit PDCP PDU before segmentation based on each transmission unit RLC PDU sent from the RLC, and transmits the restored transmission unit PDCP PDU to the reception side PDCP. Have
The receiving side PDCP expands the compressed IP header part in the transmission unit PDCP PDU received from the receiving side RLC, and when the transmission unit PDCP PDU includes an error correction code and type information, A configuration in which an error check is performed on a portion excluding the error correction code and type information of the transmission unit PDCP PDU in which the IP header is expanded, and if there is an error, the error correction code is used to correct the error. A wireless access network comprising:

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