KR100539535B1 - method for managing transmission of data units in communication - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for processing data unit transmission, particularly in a mobile communication system, and further improves the transmission processing efficiency of traffic in an Abis interface section between a base station controller (BSC) and a base station (BTS). In particular, the present invention relates to a data unit transmission processing method of a communication system which guarantees a minimum length of a transmission data unit in a medium access control layer defined between a BSC and a BTS of a next generation mobile communication system.

Description

Method for managing transmission of data units in communication

The present invention relates to a communication system, and more particularly, to a transmission processing method of a data unit in a mobile communication system.

1x EV-DV (1x Evolution Data and Voice) system has a configuration as shown in FIG.

New physical channels added to the 1xEV-DV system include forward channels such as a packet data channel (hereinafter referred to as PDCH) and a packet data control channel (hereinafter referred to as PDCCH). And a reverse channel such as a channel quality indicator channel (hereinafter, abbreviated as CQICH) and an acknowledgment channel (hereinafter, abbreviated as ACKCH).

Here, the PDCH, which is a forward channel, transmits data at a maximum speed of 3.07 Mbps, and the PDCCH transmits information such as Walsh code, MAC ID (MAC_ID), and data length of the PDCH.

The CQICH, which is a reverse channel, is a channel that transmits channel quality of the forward channels at a period determined by the system, and the ACKCH is a cyclic redundancy check (CRC) of an encoder packet received through a PDCH. (Abbreviated as d)) This is a channel that notifies the acknowledgment (ACK) or non acknowledgment (NAK) depending on whether or not it passes.

As described above, an encoder packet is a packet format in which 16 bits for CRC are added to the information bits transmitted to the upper layer and six bits for the turbo encoder tail bits are added to the information bits received in the upper layer. In addition, the encoder packet is transmitted to the mobile terminal in the form of a sub-packet over the air.

The subpacket is a part of an encoder packet determined by a scheduler of a base transceiver system (hereinafter referred to as a BTS) based on a current radio state and a resource state. The subpacket will be described later. At least one 48-byte minimum service data unit (hereinafter, referred to as SDU) is created. In other words, a subpacket having a maximum of 1, 2, 4, 6, 8 or 10 minimum SDUs is transmitted to the mobile station. Therefore, the length of the encoder packet transmitted to the mobile station (EP_SIZE), which will be described later, refers to the length of a sub packet including the minimum number of SDUs and several tens.

FIG. 2 is a diagram showing the flow of traffic data, showing the flow of traffic data after call setup.

As shown in FIG. 2, the forward traffic received by the mobile station is transmitted from the packet data serving node (PDSN) 30 to the base station controller (hereinafter referred to as BSC) 20 through the BTS. Is passed to (10).

At this time, the A section between the BSC 20 and the BTS 10 is an Abis interface section, and the BSC 20 that receives data (forward traffic) from the PDSN 30 includes a radio link protocol; Hereinafter, referred to as RLP) data and a header of a multiplex sublayer are attached to the BTS 10. The Abis interface is an interface defined in the inter-operability specification between the BTS 20 and the BSC 30 in the 3rd generation partnership project 2 (3GPP2).

At this time, the packet format transmitted from the BSC 20 to the scheduler of the BTS 10 is in units of 48 bytes, which is a minimum SDU unit. The format of the minimum SDU is shown in FIG.

Subsequently, in the data transmitted through the PDCH (forward traffic), the protocol data unit (hereinafter, abbreviated as PDU) of the multiplex sublayer is a format of a fifth type mux PDU (hereinafter abbreviated as MuxPDU type 5). Has 3 is a diagram illustrating an example of a header format in a data unit of a multiplex layer, and particularly, a header thereof in a PDU of a multiplex sublayer having a format of MuxPDU type 5 (hereinafter, abbreviated as MuxPDU).

On the other hand, when there is not enough data in the BSC 20 to fill the length (48 bytes) of the minimum SDU format, i.e., when the length of the MuxPDU down from the upper layer does not become 48 bytes, the BSC 20 is shown in FIG. As shown, 48 bytes are filled by appending a supplemental MuxPDU (hereinafter, abbreviated as Fill MuxPDU) after the RLP data 44.

 In the minimum SDU format of FIG. 4, SR_ID (40, 50) is a field of Service Reference ID, EI (41, 51) is a field of Extension Indicator, and LI (42, 52) Is a field of a length indicator, and LENs 43 and 53 are fields indicating a length value of the RLP data 44.

In FIG. 4, the MuxPDUs descended from the upper layer include valid RLP data 44, and the Fill MuxPDUs all contain invalid data having a value of "0".

That is, the SR_ID 50 is "111" in the Fill MuxPDU, and the RLP data 60 field is filled with a value of "0".

The BTS 20 receives a minimum SDU of 48 bytes and stores it in a transmission standby buffer. The BTS 20 stores parameters such as the current wireless status, the degree of traffic load, and the status of the transmission standby buffer (Queue). After determining the encoder packet length (EP_SIZE) corresponding to the minimum number of SDUs to several tens of lengths based on the parameter), it is transmitted over the air. Herein, the encoder packet length EP_SIZE is set to a length in which a minimum SDU of 48 bytes corresponds to a maximum of 1, 2, 4, 6, 8, or 10. As such, the encoder packet length EP_SIZE, which is the sum of several to several tens of minimum SDUs, is the length of the aforementioned subpacket. As a result, the length of the subpacket transmitted from the BTS 10 to the mobile station is determined based on parameters such as the current wireless state, the degree of traffic load, and the state of a transmission queue.

As described above, in the prior art, when there is not enough data to fill the length (48 bytes) of the minimum SDU format in the BSC, the BSC 20 additionally inserts a Fill MuxPDU to fill the 48 bytes before transferring the data to the BTS. . As described above, the BSC, which receives the data (forward traffic) from the PDSN in bursts, inserts and transfers unnecessary Fill MuxPDUs over the air, thereby reducing the efficiency of the forward traffic load. It also adversely affects the processing capacity of forward traffic.

Also, in order to insert a Fill MuxPDU, a field corresponding to the length of the Fill MuxPDU is required. Therefore, when inserting a Fill MuxPDU, always leave the length of its header at 48 bytes. This adds to the processing hassle for forward traffic.

In addition, the BTS is required to compare the length of the current SDU and the length of the PDU to determine whether to insert the Fill MuxPDU.

DISCLOSURE OF THE INVENTION An object of the present invention is to provide a data unit transmission processing method of a communication system suitable for further improving the transmission processing efficiency of traffic in the Abis interface section between BSC and BTS. .

Another object of the present invention is to provide a data unit transmission processing method of a communication system which guarantees a minimum length of a transmission data unit in a medium access control layer defined between a BSC and a BTS of a next generation mobile communication system. .

A feature of the data unit transmission processing method of the communication system according to the present invention for achieving the above objects is that the base station controller (BSC) generates a protocol data unit (MuxPDU) of the multiplex sublayer from the data of the received traffic to the base station Transmitting to the BTS, storing, by the base station, the received protocol data unit (MuxPDU) in a transmission standby buffer, determining a length of a sub packet to be transmitted to a specific mobile terminal, and the base station transmitting the sub packet Determining the number of the protocol data units (MuxPDUs) to be included in the base station, the base station sums the predetermined number of protocol data units (MuxPDUs) to correspond to the determined length of the subpacket, and adds a supplementary MuxPDU And inserting the packet into a packet and transmitting the same to the mobile station.

Preferably, the protocol data unit (MuxPDU) of the multiplex sublayer is composed of radio link protocol (RPP) data and a header of the multiplex sublayer.

The base station controller (BSC) further includes a length field in the protocol data unit (MuxPDU) of the multiplex sublayer, and the value of the length field is a protocol of the multiplex sublayer. The length of the header constituting the data unit (MuxPDU) and the value of the field indicating the length of the Radio Link Protocol (RLP) data in the header are set together.

The length of the subpacket is determined by a scheduler of the base station, and the scheduler is configured based on at least one of a state of the radio between the base station and the mobile station, a degree of the traffic load, and a state of the transmission standby buffer. Determine the length of. The length of the subpacket is a length of an encoder packet including at least one minimum service data unit (SDU) of 48 bytes.

Other objects, features and advantages of the invention will become apparent from the following detailed description of embodiments taken in conjunction with the accompanying drawings.

Hereinafter, a preferred embodiment of a data unit transfer processing method of a communication system according to the present invention will be described with reference to the accompanying drawings.

In the present invention, the BSC attaches the Fill MuxPDU in the BTS rather than additionally inserting the Fill MuxPDU.

More specifically, in a 1xEV-DV system, data (traffic) of a predetermined SDU needs to be transmitted. Therefore, when there is no data for a given SDU, a Fill MuxPDU is necessary to fill the SDU.

However, in the present invention, in order to minimize the size of a data unit transmitted in the Abis interface section between the BSC and the BTS, the Fill MuxPDU is processed to be inserted in the BTS.

As described above, in order for the BTS to insert a Fill MuxPDU, the BSC includes length information of all MuxPDUs transmitted to the BTS. The length is set within a range not exceeding 48 bytes, the length of the minimum SDU.

The BTS stores all MuxPDUs received from the BSC with their respective length information.

Then, when the length of the minimum SDU to be transmitted is determined by the scheduler of the BTS, the received MuxPDUs are summed so as not to exceed the determined minimum SDU length. Accordingly, the PDU length (the sum of at least one PDU received from the BSC) included in the SDU to be transmitted this time is determined.

If the length of the sum of several MuxPDUs is smaller than the minimum SDU length defined by the scheduler, the BTS inserts a Fill MuxPDU to supplement the minimum SDU length determined by the scheduler.

At this time, the value of the length indicator LI shown in FIG. 3 in the header of the Fill MuxPDU to be inserted is "00". Since a field indicating the length value of the RLP data is not required, the length of the insufficient SDU is filled while reducing two bytes in the header of the Fill MuxPDU.

5 is a diagram illustrating a transmission format of a data unit used between a BTS and a BSC according to the present invention.

In the present invention, the format of the data unit transmitted in the Abis interface section between the BSC and the BTS is used as shown in FIG. 5.

Accordingly, the BSC adds an 8-bit length field 70 indicating the length of the MuxPDU 80 to the MuxPDU 80 to be delivered to the BTS.

Prior to this, the BSC temporarily stores data (forward traffic) received from a packet interface processor (PIP) in a buffer, generates instantaneous RLP data, and also formats the MuxPDU 80 to FIG. 5. It sends to the BTS in the format including the length field 80 as shown.

In particular, the length field 70 of the PDU format transmitted from the BSC to the BTS is a sum of a value of a field LN indicating the length value of the RLP data of the MuxPDU 80 and 2 bytes of the header length of the MuxPDU 80. Set it.

Upon receiving the traffic having the format of FIG. 5, the BTS temporarily stores the received traffic (length field + MuxPDU) in a transmission queue.

Subsequently, the scheduler of the BTS checks the channel quality of the known forward channels through the reverse channel CQICH, the state of the CQICH, in particular, the state of the radio, the traffic load, and the state of the transmission queue. As a reference, the length of the minimum SDU of the data to be transmitted currently, that is, the encoder packet length (EP_SIZE) is determined.

Subsequently, the scheduler determines the number of MuxPDUs corresponding to the encoder packet length (EP_SIZE) determined by using the value of the length field in the traffic (length field + MuxPDU) temporarily stored in the transmission queue buffer. That is, the number of MuxPDUs smaller than the encoder packet length (EP_SIZE) is determined by adding the temporarily stored MuxPDUs. Accordingly, as shown in FIG. 6, the MuxPDUs 100 received from the BSC are summed so as not to exceed the encoder packet length EP_SIZE, which is the length of the minimum SDU.

As the length of the sum of the various MuxPDUs 100 received from the BSC is smaller than the predetermined encoder packet length EP_SIZE, the Fill MuxPDU 110 is inserted after the last MuxPDU as shown in FIG. 6.

6 is a diagram for describing a transmission processing procedure of a data unit according to one embodiment of the present invention.

Referring to FIG. 6, a BSC that receives data (forward traffic) from a PDSN generates a MuxPDU by attaching RLP data and a header of a multiplex sublayer.

The BSC sends forward traffic to the BTS in the format of FIG. 5 in which a length field is further inserted in each generated MuxPDU. Here, the interval between the BSC and the BTS is an Abis interface interval.

The BTS temporarily stores forward traffic (multiple MuxPDUs) received from the BSC and information of the length field included in each MuxPDU together in a transmission queue buffer.

Subsequently, the scheduler of the BTS determines the length of the minimum SDU of the data to be transmitted, that is, the encoder packet length (EP_SIZE), based on the state of the radio, the degree of traffic load, and the state of the transmission queue. For example, in FIG. 6, the encoder packet length EP_SIZE is determined to be 8. This is a case where a sub packet format including at least eight SDUs in units of 48 bytes is used in an Abis interface section.

Accordingly, the scheduler of the BTS determines the number of MuxPDUs included in the subpacket using the value of the length field in the traffic (length field + MuxPDU) temporarily stored in the transmission wait buffer. That is, the number of MuxPDUs whose sum of temporarily stored MuxPDUs is smaller than the encoder packet length (EP_SIZE) is determined.

At this time, if the sum length of the MuxPDUs is smaller than the predetermined encoder packet length (EP_SIZE), the BTS inserts a Fill MuxPDU at the end of the subpacket. Eventually, when the sub packet is completed, the BTS transmits it to the mobile terminal.

 According to the present invention described above, by reducing the unnecessary Fill MuxPDU significantly compared to the existing 1xEV-DV system, the processing capacity of the forward traffic is effective.

In addition, since the BSC does not need to perform the header processing of the complicated Fill MuxPDU and inserts the Fill MuxPDU in the BTS, traffic transmission efficiency of the traffic is improved in the Abis interface section between the BSC and the BTS. That is, since the BSC does not require the process of inserting a Fill MuxPDU to match the minimum SDU length, the length of the data unit transmitted between the BSC and the BTS is minimized.

Those skilled in the art will appreciate that various changes and modifications can be made without departing from the spirit of the present invention.

Therefore, the technical scope of the present invention should not be limited to the contents described in the embodiments, but should be defined by the claims.

1 is a view showing the overall configuration of the 1x EV-DV system.

2 is a diagram illustrating a flow of traffic data.

3 illustrates an example of a header format in a data unit of a multiplex layer.

4 illustrates an example of a format of a minimum service data unit (SDU).

5 illustrates a transmission format of a data unit used between a BTS and a BSC according to the present invention.

6 is a view for explaining a transmission processing procedure of a data unit according to an embodiment of the present invention.

Claims (7)

A base station controller (BSC) generating a protocol data unit (MuxPDU) of the multiplex sublayer from the data of the received traffic and transmitting it to the base station (BTS); Storing, by the base station, the received protocol data unit (MuxPDU) in a transmission standby buffer and determining a length of a sub packet to be transmitted to a specific mobile terminal; Determining, by the base station, the number of protocol data units (MuxPDUs) to be included in the subpacket; Adding, by the base station, the predetermined number of protocol data units (MuxPDUs) to correspond to the determined length of the subpacket, and inserting a supplemental MuxPDU into the subpacket and transmitting the supplementary MuxPDU to the mobile station. A data unit transfer processing method of a communication system characterized by the above-mentioned. The protocol data unit (MuxPDU) of the multiplex sublayer is a radio link protocol (RLP) data and a header of the multiplex sublayer. A data unit transmission processing method of a communication system, characterized in that. The data unit of claim 1, wherein the base station controller (BSC) further includes a length field in a protocol data unit (MuxPDU) of the multiplex sublayer to transmit to the base station. Transmission handling method. 4. The method of claim 3, wherein the value of the length field is a length of a header constituting a protocol data unit (MuxPDU) of the multiplex sublayer, and radio link protocol (RLP) data in the header. The unit transmission processing method of the communication system, characterized in that the value is set to the sum of the values of the field indicating the length of. The method of claim 1, wherein the length of the subpacket is determined by a scheduler of the base station. 6. The communication method of claim 5, wherein the scheduler determines the length of the subpacket based on at least one of a state of the radio between the base station and the mobile station, a degree of the traffic load, and a state of the transmission standby buffer. How to handle data unit transfers in the system. 7. The method of claim 6, wherein the length of the sub packet is a length of an encoder packet including at least one minimum service data unit (SDU) of 48 bytes.