KR20020014940A - Discard procedure for service data unit in radio link control - Google Patents

Abstract

PURPOSE: A discard procedure of a service data unit(SDU) in a radio link control(RLC) is provided, which can prevent a protocol error generation during an SDU discard procedure. CONSTITUTION: According to the discard procedure, a transmitter part receives information of an SDU to discard from an upper layer, and then a sequence number(SN_MRWi) and a VT(MS) of a corresponding PDU(Protocol Data Unit) are compared. As a result of the comparison, if the sequence number is larger than VT(MS), the corresponding SDU is not discarded and the comparison between the sequence number and the VT(MS) is repeated as increasing "i" value until there is no SDU to discard. And if there is SN_MRWi to transmit, then MRW is transmitted, and otherwise, the discard process of the transmitter part is ended as not transmitting MRW. In a receiver part receiving a discard command of SDU0-SDU2, SDU0-SDU2 are discarded and an acknowledge(ACK) response as to the SDU discard command is performed to the transmitter part as moving a receiver window downward. Then, VR(R)=2 and VR(MR)=9, and because VT(MS) of the transmitter part is 9, a discard command of SDU3 can be sent again.

Description

DISCARD PROCEDURE FOR SERVICE DATA UNIT IN RADIO LINK CONTROL} in the radio link control (RCL)

The present invention relates to a procedure for processing an SDU dcard in an RLC that can solve a protocol error problem that may occur when processing an SDU diskette currently used for flow control of an RLC layer.

More specifically, the present invention provides a protocol data unit including an end position of an SDU to be discarded when a sender sends a service data unit (SDU) diskette command in generating a PDU in RLC (Radio Link Control). ) Compares the sequence number of VT (MS) with the VT (MS) and does not send the SDU discard command for the SDU if it is larger than VT (MS), and sends the SDU discard command at the sending end and includes it in the SDU discard command at the receiving end. If there is an overlap part compared with its own window range with the updated information, it updates the VR (R) of the receiving end with this, so that the RDU can solve the protocol error that may occur during SDU disk processing. Discard processing method.

In light of the fact that there are many researches on communication technologies that allow time-space-free and unlimited access to multimedia, and many efforts for the visible results of the research, the development of digital data processing and transmission technology integrates wired and wireless communication. The implementation of a real-time global data communication system using satellites is on the horizon.

Also, thanks to the development of digital data processing and transmission technology, it is possible to freely access information anytime, anywhere, regardless of existing voice calls, real-time transmission of network-based still images, moving images and wired or wireless.

IMT-2000 will be one of them.

The RLC (Radio Link Control) layer referred to in the present invention is a protocol layer that controls the data link as a second layer of 3GPP.

This RLC layer is a UMD PDU (Unacknowldeged PDU) used when a receiver receives a Protocol Data Unit (PDU) after receiving a PDU, and an AMD Acknowledged PDU (PDU) used when a recognition signal is required. There are two types of PDUs, and various state variables and windows are used to control the flow of each PDU for data link control.

The PDU, which is a basic unit of transmission and reception in the RLC layer, is formed by attaching a header including a sequence number (SN) to an SDU descending from an upper layer. A PDU may be composed of several SDUs. It may be configured as part of one SDU.

1 conceptually illustrates an example of a method of constructing a PDU from an SDU. In FIG. 1, PDU0 is configured as SDU0, PDU1 is configured as part of SDU1 and SDU2, and PDU2 is configured as part of SDU2.

PDUs generated as shown in FIG. 1 are stored in the RLC buffer and then transmitted to the receiver according to the transmission window, and the receiver determines whether the sequence number (SN) of the received PDU is in the reception window or outside the reception window. It ignores PDUs outside the receive window and checks whether there is an error for each PDU only for the PDUs in the receive window and informs the transmitter whether it is recognized (ACK) or not recognized (NACK) for each PDU. Send the information. At this time, the reception window and the transmission window have the same size. The transmitting end receiving the status information retransmits the PDU that is not recognized (NACK) to the receiving end.

Various state variables are used for the transmission and reception of such PDUs. The state variables used for flow control of the transmitter include VT (S) as the transmission state variable, VT (MS) as the maximum transmission state variable, and VT (A as the recognition state variable. ) Is used, along with Tx_window_size, which indicates the transmission window size.

Here, VT (S) corresponds to the sequence number (SN) of the first PDU excluding the retransmission PDU among the RLC PDUs to be transmitted next, and VT (MS) corresponds to the sequence number of the first PDU among the RLC PDUs not to be transmitted next. SN) (i.e., the receiver is only allowed to receive up to VT (MS) -1), and VT (A) corresponds to the sequence number SN of the first PDU among PDUs to be acknowledged next.

And Tx_window_size is the maximum value of the number of PDUs that can be sent at one time without receiving an acknowledgment (ACK). Since VT (A) forms a lower limit and VT (MS) forms an upper limit, VT (MS) = VT (A) + There is a relationship of Tx_window_size.

The initial value of VT (S) is '0' and increases by 1 for every PDU that is not retransmitted. Since the transmitted PDU is only allowed to be within Tx_window_size, the minimum value of the sequence number SN is VT (A ) And the maximum value is VT (MS) -1.

On the other hand, the receiving end checks the reception status of each PDU and sends the ACK / NACK information to the sender to the status PDU to request retransmission.

At this time, the sequence number (SN) of the first PDU among the PDUs to be transmitted or retransmitted next time is called a reception state variable VR (R), and the sequence number (SN) of the first PDU among the PDUs that should not be transmitted or retransmitted next. ) Is called VR (MR), which is the maximum reception state variable, and each of them forms a lower limit and an upper limit of the reception window, and thus has a relationship of VR (MR) = VR (R) + Rx_window_size.

Here, Rx_window_size is a size of a reception window, and generally has a value equal to the size of the transmission window (Tx_window_size). The receiving end to receive the transmitted PDU updates the VR (R) with the sequence number SN of the first PDU in error, and uses the relationship of VR (MR) = VR (R) + Rx_window_size to determine the VR (R). MR) is updated. The highest expected state variable VR (H) is set to VR (H) = SN + 1 each time a new PDU is received with VR (H) <SN <VR (MR).

The transmitting end receiving the status PDU carrying the ACK / NACK information for each PDU updates the value of VT (A) to VR (R), and the value of VT (MS) is also VT (MS) = VT (A) + Tx_window_size. The PDU required by the receiving side is retransmitted accordingly.

In the process of transmitting / receiving SDUs forming a PDU, if a PDU including an SDU remains in the transmission buffer for too long or an error is found in the SDU itself, all PDUs containing the corresponding SDU are discarded. Increasing the efficiency of buffers and the efficiency of limited radio resources. FIG. 2 shows a Move Receiving Window (MRW) field in a status PDU used for SDU discard processing, and FIG. 3 shows an MRW_ACK field of a status PDU used when performing recognition (ACK) on an MRW.

In FIG. 2, the length field LENGTH indicates the number of SN_MRWi following, and SN_MRWi indicates the sequence number of the PDU including the end portion of each SDU to be discarded (Length Indicator (LI) of the i-th discarded SDU). (SN)).

Since LI is a field included in the head of the PDU to indicate the end of the SDU when there is an end of the SDU in each PDU, SN_MRWi is the sequence number of the PDU including the end position of the SDU that is eventually discarded. SN).

The N _LENGTH field indicates to what extent LI is for the discarded SDUs in the PDU containing the end position of the last SDU to be discarded.

3 illustrates an MRW_ACK field of a status PDU used when performing an acknowledgment (ACK) on an MRW as described above.

On the other hand, Figure 4 shows an example in which the SDU discard processing is performed in the case of Figure 1, in Figure 4, the transmitter is VT (A) = 0, VT (S) = 5, VT (MS) = 6 is transmitted Since the window size Tx_window_size = 6 and PDU0 to PDU4 are transmitted, and the receiving end is VR (R) = 0 and VR (MR) = 6, the receiving window size Rx_window_size = 6, PDU0 to PDU3 are received, and PDU4 is It has not arrived at the receiving end yet.

In this case, consider the case where SDU0 to SDU2 are discarded.

The sender discards SDU0 through SDU2 from its own buffer and sends the status PDU with the information to discard all PDUs contained in the SDU, i.e. SDU0 to PDU0 and SDU1 to PDU1. Since SDU2 is contained in PDU1 and PDU2, a signal for eventually discarding PDU0 to PDU2 is transmitted.

When the receiving end receives this status PDU, it discards PDU0 to PDU2, and eventually discards SDU0 to SDU2.

5 shows an operating algorithm of the transmitting end in the prior art described above, and FIG. 6 shows an operating algorithm of the receiving end in the prior art.

As shown in Fig. 5, the transmitting end receives the information of the SDU to be discarded from the upper layer and transmits the MRW. The receiving end receives the MRW from the transmitting end as shown in Fig. 6, and SN_MRW _LEN and VR (R) are received. MRW is ignored or updated according to the result of the comparison, or VR (R) = SN_MRW _LEN , and then MWR_ACK is transmitted and terminated.

However, according to the conventional SDU discard processing method as described above, a protocol error may occur during SDU discard processing.

7 shows this.

7 illustrates an example in which a transmitting end sends a command to discard a SDU0 to SDU3 to a receiving end. In this case, the transmitting end sends a status PDU to discard the PDUs from PDU0 to PDU7 to discard the SDU0 to SDU3.

In this case, since the current VR (MR) value is 6, the receiving end may be treated as an error when receiving a PDU sequence number exceeding this value, or may malfunction due to overlapping with a sequence number of a previously received PDU. Will be.

In such a case, it is determined that there is no error at the transmitting end, but a problem of unexpected error is caused at the receiving end.

The present invention compares the sequence number of the PDU including the end position of the SDU to be discarded when the sender sends the SDU discard command to the VT (MS), or at the receiver with information included in the SDU discard command. By performing the SDU discard processing according to the result compared with the window range, the RLC proposes a SDU discard processing method to prevent the occurrence of a protocol error during the SDU discard processing.

The present invention compares the sequence number of the PDU with the VT (MS) at the transmitting end and prohibits the transmission of the SDU discard command for the SDU when the sequence number is larger than the VT (MS). We propose an SDU discard processing method in an RLC characterized by preventing an error.

The present invention compares the information contained in the SDU diskette command with its own window range at the receiving end. If there is an overlapping part, the present invention updates the VR (R) of the receiving end with this, thereby generating a protocol generated during the SDU discarding process. We propose an SDU discard processing method in an RLC characterized by preventing an error.

1 is a diagram illustrating a method of configuring a PDU from an SDU.

Fig. 2 shows the MRW field structure in the status PDU.

3 illustrates the structure of an MRW ACK field in a status PDU.

FIG. 4 is a view for explaining an example in which SDU discard processing is performed in the case of FIG.

FIG. 5 is a diagram for explaining an example in which an SDU disk processing causes an error in the prior art; FIG.

6 is a flowchart for explaining an operation algorithm of a transmitting end in the prior art.

7 is a flowchart illustrating an operation algorithm of a receiving end in the prior art.

8 is a flowchart for explaining a transmitter operation algorithm according to the first embodiment of the present invention.

9 is a flowchart for explaining a receiver operation algorithm according to a second embodiment of the present invention.

8 shows an operation algorithm in a transmitting end according to the first embodiment of the present invention.

The first embodiment of the present invention proposes an SDU discard processing method in an RLC which can prevent a protocol error from occurring in the SDU discard processing at a transmitting end.

9 illustrates an operation algorithm at a receiving end according to a second embodiment of the present invention.

The second embodiment of the present invention proposes a SDU discard processing method in an RLC which can prevent a protocol error occurrence of SDU discard processing at a receiving end.

First, the first embodiment of the present invention will be described with reference to FIG.

The first embodiment of the present invention compares the sequence number of the PDU including the end position of the SDU to be discarded and the VT (MS) when the sender sends an SDU discard command, when the sequence number is larger than VT (MS). This method prohibits the sending of a discard command to an SDU.

The transmitting end receives information of the SDU to be discarded from the upper layer.

When receiving information of the SDU to be discarded from the upper layer, the sequence number SN_MRWi of the corresponding PDU is compared with the VT (MS).

If the sequence number is larger than VT (MS), the comparison of the sequence number and VT (MS) is repeated while increasing the value of i until there are no more SDUs to discard.

If there is a SN_MRWi to be transmitted, the MRW is transmitted; otherwise, the discard process is terminated by not transmitting the MRW.

In this way, for example, in FIG. 5, the command to send SDU0 to SDU2 is sent, but the command to discard the SDU3 is not sent.

That is, the sequence number SN of the PDU7 including the end position of SDU3 is '7' because VT (MS) = 6.

Meanwhile, the receiving end receiving the discard command of the SDU0 to SDU2 performs the acknowledge (ACK) response to the SDU discard command to the transmitting end while discarding the SDU0 to SDU2 and moving the receiving window downward. Then, VR (R) = 2, VR (MR) = 9 and VT (MS) = 9 of the transmitting end, so that the discard command of SDU3 can be sent again.

This allows the discard function for the desired SDU to be performed while preventing errors at the receiving end.

9, a second embodiment of the present invention will be described.

According to the second embodiment of the present invention, when a transmitting end sends an SDU diskette command in the same manner as before, the receiving end has an information included in the SDU discarding command and overlaps it with its own window range. To update the VR (R).

That is, based on the SDU discard information sent from the transmitting end, the range of [sequence number of the first PDU of the first SDU to be discarded, sequence number of the last PDU of the last SDU to be discarded], and a reception window (Rx_window) If there are overlapping parts, this corresponds to the newly received SDU discard command, so set its VR (R) to the sequence number of the newly received PDU after the last SDU to be discarded.

That is, VR (R) = SN_MRW _LEN and MRW_ACK is sent to the transmitting end. At this time, the updated VR (R) value is inserted into the SN_ACK field of the MRW_ACK (see FIG. 2).

The receiving end moves the receiving window accordingly. In this way, even if the receiving end receives an SDU diskette command having a larger sequence number than VR (MR), it is possible to perform the discard function for the desired SDU without error.

According to the present invention, when a sender sends a discard command to a PDU sequence number that exceeds a VR (MR) value of a receiver in an SDU diskette command used in a conventional RLC, the present invention overlaps with a sequence number of a PDU that was previously received. The problem of malfunctioning has been solved.

Therefore, the problem that the transmitting side is treated as no error but the receiving side is an unexpected error is solved, and it is possible to prevent the occurrence of protocol error at the transmitting and receiving end, thereby improving the safety and reliability of the whole system.

Claims (5)

At the transmitting end when performing RDU discard processing of the PDU in the RLC; (a). Comparing the sequence number of the PDU including the end position of the SDU to be discarded with the VT (MS), (b). Prohibiting the transmission of the discard command for the SDU when the sequence number of the corresponding PDU is larger than the VT (MS), as a result of the comparison, in the radio link control (RLC) of the service data unit (SDU). How to handle the discard. The radio link control according to claim 1, wherein the next VARD (MS) of the transmitting end is updated by the receiving end response (ACK) to the result of performing the above step, so that the next diskette command can be transmitted again. Discard processing method of service data unit (SDU) in RLC. At the receiving end when performing SDU discard processing of the PDU in the RLC; (a). Comparing the window range of the receiving end based on the information contained in the SDU diskette command from the transmitting end, (b). When there is a portion where the ranges according to the two information overlap as a result of the comparison, the step of controlling the SDU diskette command having a sequence number larger than the VR (MR) by updating the VR (R) of the receiver. Discard processing method of service data unit (SDU) in link control (RLC). [4] The method according to claim 3, wherein the sequence number of the first PDU of the first SDU to be discarded and the sequence number of the last PDU of the last SDU to be discarded range from information included in the SDU discard command from the transmitter. And a reception window range are compared to a discard processing method of a service data unit (SDU) in a radio link control (RLC). 5. The method of claim 4, wherein if there is a portion where the sequence number of the first PDU of the SDU to be first discarded and the sequence number of the last PDU of the last SDU to be discarded overlaps with a reception window range, And updating the VR (R) of the service data unit (SDU) in the radio link control (RLC), wherein the VR (R) is updated with a sequence number of a newly received PDU after the last SDU to be discarded.