KR100438558B1 - Protocol data unit generation method for mobile communication system - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for generating a state protocol data unit of a mobile communication system suitable for transmitting high-speed data when an error reception rate is high in an air space. A first step of calculating a normally received PDU (N (Y)) and an unreceived PDU (N (N)) within a reception window size; Comparing a size of the normally received PDU (N (Y)) with an unreceived PDU (N (N)); A third step of generating a STATUS PDU by extracting only a sequence number SN of an unreceived PDU when the number of normally received PDUs is equal to or greater than the number of unreceived PDUs (N (Y)> = N (N)) Wow; A fourth step of generating a STATUS PDU by extracting only the sequence number SN of the normally received PDU when the number of normally received PDUs is smaller than the number of unreceived PDUs (N (Y) <N (N)) It is possible to achieve this, and there is an effect of enabling high-speed data transmission even when the error reception rate is high.

Description

PROTOCOL DATA UNIT GENERATION METHOD FOR MOBILE COMMUNICATION SYSTEM}

The present invention relates to a method for generating a state protocol data unit of a mobile communication system, and more particularly, to a method for generating a state protocol data unit of a mobile communication system suitable for transmitting high-speed data when an error reception rate is high in an air space. It is about.

In general, SUFI (LIST, RLIST, BITMAP) presented in the 3GPP TS25.322 standard is a method for coding an unreceived sequence number (SN) within a reception window size.

When a bearer is opened for high-speed traffic, the reception window size (Rx_Window_Size) also increases in proportion to the transmission rate. When the bit error rate (BER) is high for a traffic channel, the RLC (Radio link Control) protocol data unit (PDU) The reception rate will also drop.

Since the conventional method of coding a STATUS PDU (Status Protocol Data Unit) is a method of coding a sequence number (SN) of an unreceived PDU, it is inefficient if the number of unreceived PDUs is larger than the number of received PDUs in the reception window size. There is a problem that causes coding.

Accordingly, the present invention has been made to solve the above-mentioned conventional problems, and generates a state protocol data unit of a mobile communication system suitable for transmitting high-speed data when the error reception rate is high in the air space. The purpose is to provide a method.

The present invention for achieving the above object, in generating a status protocol data unit (STATUS PDU), the PDU (N (Y)) and the non-received PDU (N (N)) received normally within the reception window size Calculating a first step; Comparing a size of the normally received PDU (N (Y)) with an unreceived PDU (N (N)); A third step of generating a STATUS PDU by extracting only a sequence number SN of an unreceived PDU when the number of normally received PDUs is equal to or greater than the number of unreceived PDUs (N (Y)> = N (N)) Wow; A fourth step of generating a STATUS PDU by extracting only the sequence number SN of the normally received PDU when the number of normally received PDUs is smaller than the number of unreceived PDUs (N (Y) <N (N)) Characterized in that consisting of.

1 is a flowchart illustrating a method of generating a state protocol data unit in a mobile communication system according to the present invention.

The present invention relates to a method for generating an efficient state protocol data unit (STATUS PDU) in a Universal Mobile Telecommunication System (UMTS) radio link control (RLC). The present invention relates to a state protocol data unit (STATUS PDU) proposed in the conventional 3GPP TS25.322 standard. ) Is a feature that enables high-speed data transmission by adding a suitable SUFI (Super-Field) when the error reception rate is high on the air space.

The present invention is characterized by a simple encoding of a status protocol data unit (STATUS PDU) at the RLC receiving end and a decoding at the RLC transmitting end to reduce the load of the RLC burden every trigger (10 ms).

That is, if the conventional method was to code the sequence number (SN) of the unreceived PDU, in the present invention, when the number of unreceived PDUs is larger than the number of the received PDU, the sequence number (SN) of the received PDU is determined. It relates to SUFI (Super-Field) coding, which encodes a state protocol data unit (STATUS PDU) and uses it to decode when received by a peer RLC. Can be reduced.

In other words, in the prior art, only the sequence number of an unreceived PDU within the reception window size is extracted, and a STATUS PDU is generated using SUFI (LIST, RLIST, BITMAP) presented in 3GPP TS25.322 based on this. In the present invention, the number of received PDUs and the number of unreceived PDUs are compared. If the number of unreceived PDUs is large, a STATUS PDU is generated using SUFI according to the present invention.

Accordingly, even when a high bit error rate occurs when performing high-speed traffic, the STATUS PDU is efficiently encoded and decoded, thereby reducing the load on the weighted RLC stage.

For reference, SUFI (LIST, RLIST, BITMAP) presented in 3GPP TS25.322 are the VR (R) (sequence number to be received in Rx side RLC) and VR (H) (maximum sequence number). Techniques for coding a sequence number (SN) of a PDU that is not properly received between the STATUS PDUs.

However, the above technique is effective when the condition of air space is good and low BER (Bit Error Ratio) is low. However, if the air space is not good and you want to transmit high-speed traffic when data loss is high. Inevitably, significant coding loss is caused between the UE and the RLC peer.

In order to solve the above problem, when the number of properly received PDUs in the reception window size is N (Y) and the number of unreceived PDUs is N (N), as shown in FIG. Similarly, when receiving or generating a STATUS PDU request from a peer RLC, N (Y) and N (N) in the reception window size are calculated (S101), and the number of normally received PDUs is equal to or greater than the number of unreceived PDUs. If (N (Y)> = N (N)) (S102), a STATUS PDU is generated using SUFI (LIST, RLIST, BITMAP) according to the prior art standard (TS25.322) (S103).

However, when the number of normally received PDUs is smaller than the number of PDUs that have not been received (N (Y) <N (N)), a STATUS PDU is generated by the method according to the present invention (S104).

When N (Y) <N (N), the configuration of SUFI (list_OK, RLIST_OK) according to the present invention is shown in Tables 1 and 2 below.

Type = LIST_OK LENGTH SN ₁ L ₁ SN ₂ L ₂ .... SN _LENGTH L _LENGTH

Here, the length LENGTH is 4 bits, SN _i (12 bits) is a properly received sequence number SN, and L _i (4 bits) is a number of successively correctly received sequence numbers SN in addition to Sn _i .

If the number of (SN _i , L _i ) -pairs in the LIST_OK SUFI is zero, the STATUS PDU is discarded.

Type = RLIST_OK LENGTH FSN CW ₁ CW ₂ .... CW _LENGTH

Where LENGTH (4bits) is the total number of code words (CW),

FSN (12bits) is the first SN received correctly by RLIST_R (if only LENTH is 0, there is only FSN in SUFI),

If CW (4bits) is 0001, it is 'no error indicator'. If CW _n is 'no error indicator', CW _{n + 1} is the number of consecutive error-free PDUs.

As described above, the method for generating a state protocol data unit of the mobile communication system according to the present invention is suitable for the type of the state protocol data unit (STATUS PDU) proposed in the 3GPP TS25.322 standard when the error reception rate is high in the air space. By adding (Super-Field), there is an effect that high-speed data can be transmitted even when the error reception rate is high.

Claims (4)

In creating a STATUS PDU, Calculating a normally received PDU (N (Y)) and an unreceived PDU (N (N)) within a reception window size; Comparing a size of the normally received PDU (N (Y)) with an unreceived PDU (N (N)); A third step of generating a STATUS PDU by extracting only a sequence number SN of an unreceived PDU when the number of normally received PDUs is equal to or greater than the number of unreceived PDUs (N (Y)> = N (N)) Wow; A fourth step of generating a STATUS PDU by extracting only the sequence number SN of the normally received PDU when the number of normally received PDUs is smaller than the number of unreceived PDUs (N (Y) <N (N)) Method for generating a state protocol data unit of a mobile communication system, characterized in that consisting of. The state protocol of the mobile communication system according to claim 1, wherein a separate SUFI (Super-Field) (LIST_OK, RLIST_OK) for generating a STATUS PDU by the sequence number (SN) of the normally received PDU is configured. How to create a data unit. The method of claim 2, wherein the SUFI (LIST_OK) is a type information, a length (LENGTH) information, a properly received sequence number (SN) information, and the number of successively correctly received sequence number (SN) in addition to the sequence number Method for generating a state protocol data unit of a mobile communication system, characterized in that it comprises information about. The method of claim 2, wherein the SUFI (RLIST_OK) is the type information, the length (LENGTH) information of the code word (CW), the first sequence number (SN) properly received in the RLIST_OK, and the code word (CW) information (offset) Information) is included in the mobile communication system.