KR20010066281A - transport channel format management method in UMTS - Google Patents

Abstract

PURPOSE: A method for managing a transmission channel format of a universal mobile telecommunication system(UMTS) is provided to decrease a detection error of a transport format combination(TFC) and a transport format transmitted from a transmission side by expressing a transport block size, a transport block set, and the TFC as a simple constant-times combination on the basis of a TBN for indicating a constant times of a PTBS and omitting a previous setting process to a TFS(Transport Format Set), a TFI(Transport Format Indicator), a TFCS(Transport Format Combination Set), and a TFCI(Transport Format Combination Indicator). CONSTITUTION: A size of each transport block transmitted according to a transport time interval is limited to be a constant times of the number of reference bit. Transport format parameters in which a figure for indicating the constant times and the number of transport block included in a transport block set according to the transport time interval unit are combined are transmitted through each transport channel. The combined transport format parameters are combined as one transport format complex parameter, and the combined one transport format complex parameter is transmitted to an object side through one coded complex transport channel.

Description

Transport channel format management method in universal mobile communication system {transport channel format management method in UMTS}

The present invention relates to the next-generation mobile communication, in particular, the transmission between the MAC and the lowermost first layer (Physical Layer) which is a radio access standard protocol layer based on UMTS, which is being promoted R & D and standardization by the European Telecommunication Standardization Association (ETSI). It relates to a method of managing channel formats.

In general, the UMTS structure includes a user equipment (UE), a UTSRAN (UMTS Terrestrial Radio Access Network), and a core network (Core Network).

The air interface between these system components (UE and UTRAN) is basically layered from the upper layer to the upper layer, the third layer L3, the second layer L2, and the first layer L1.

Among these protocol layers, the second layer (L2) consists of two sublayers of a Radio Link Control sublayer (RLC) and a MAC, and the first layer (L1) is a physical layer. to be.

The first layer (L1), which is a physical layer, divides the radio spectrum into several physical channels and provides different transport channels to the MAC to map a transport channel and a physical channel through multiplexing or demultiplexing.

Hereinafter, a dedicated channel (hereinafter, referred to as DCH), which is one of transport channels, will be described.

1 is a diagram illustrating a process for mapping a transport channel (DCH) and a physical channel in a UMTS radio access standard protocol.

As shown in FIG. 1, data transmitted through multiple DCHs in a MAC in a conventional UMTS structure is coded composite transport channel (CCTrCH) coded through a coding and multiplexing block (CCTrCH). Down). This downlink data is again divided into multiple physical channels via a demultiplexing and splitting block (2).

In this process, there is a need to inform the original format structure of the corresponding DCH between the transmitting side and the receiving side.

The format structure of a transport block into which a DCH is input to the coding and multiplexing block 1 is known at a predetermined transmission interval. In this case, a transport format indicator (hereinafter, abbreviated as TFI) is used. The coded composite transport channel (CCTrCH) allocated after the coding and multiplexing block 1 informs the counterpart coding and multiplexing block (not shown) the TFI of each DCH.

Here, the TFI combination of each DCH is called a transport format combination (hereinafter, abbreviated as TFC), and this TFC is a member of a transport format combination set (hereinafter, abbreviated as TFCS).

In this case, a transport format combination indicator (hereinafter, abbreviated as TFCI) is used to inform a counterpart of a TFC, and this TFCI serves to select one of the TFCS already configured.

Next, a transport block, a transport block set having these transport blocks as a member, a transport format set (hereinafter referred to as TFS), TFCI, and TFI will be described.

The transport block is a minimum unit of data transmission through the transport channel between the first layer L1 and the MAC, and the size of the transport block is the number of bits constituting one transport block.

Also, a transport block set is a set of transport blocks to be simultaneously transmitted in the same time unit. The size of this transport block set is the number of bits constituting the transport block set.

FIG. 2 illustrates an example of a transport block and a transport block set. In FIG. 2, the transport block size of the first transmission time interval is 40 bits, and the size of the transport block set is 40 bits. The transport block size of the next second transmission time interval is 50 bits each, and the size of the transport block set is 100 bits, which is the sum of the bits of the two transport blocks.

At this time, the transmission format is a format of a transport block provided by the first layer L1 to the MAC or the MAC to the first layer L1.

In the example shown in FIG. 2, the transmission format of the transport block corresponding to the first transmission time interval is (40,40), and the transmission format of the transport block corresponding to the second transmission time interval is (50,100).

The next TFS is a set of transport formats, and since there are multiple transport channels in the first layer L1, there are TFSs for each transport channel.

Therefore, a combination of transport formats is possible by TFS for each transport channel, and each combination is TFC.

TFCS is a collection of these TFCs, and MAC selects a TFC to use among the TFCS.

In particular, a parameter indicating a specific transmission format in TFS is TFI, and a parameter indicating a specific TFC in TFCS is TFCI.

Based on the above description, the transmission of the existing transport channel is performed by the following procedure.

First, the transmitting MAC sends a parameter TFI indicating a specific transmission format among TFSs when transmitting a transport block set through a transport channel.

The first layer L1 collects the TFIs transmitted through the various transport channels from the MAC to configure the TFC, and transmits the corresponding parameter TFCI to the receiver.

The first layer (L1) of the receiving side can find out the TFC by using the received TFCI, extract the TFI of each DCH therefrom, and use this to perform data transmission through each transport channel.

However, in the prior art described so far, the transmitting side and the receiving side must have the same TFCS and TFS, and the correspondence relationship between the TFCS and TFCI and the correspondence relationship between the TFS and TFI must be set identically. Therefore, before data transmission and reception occur, both sides need an additional procedure to ensure that their correspondences match.

Also, conventionally, if any one of the correspondence between TFCS, TFS, TFCI and TFCS and the correspondence between TFS and TFI is changed, a procedure for notifying the change is further required.

As a result, prior to data transmission and reception, such a preset procedure takes an important weight, and data transmission and reception are impossible without this preset procedure. In addition, since only the TFS and the TFCS can be used, there is a problem that the data rate and the flexibility of the transmission method are deteriorated when data transmission and reception occur.

The object of the present invention was devised in view of the above, and in particular, in the UMTS radio access standard protocol, eliminating unnecessary pre-interaction between a transmitting side and a receiving side, and increasing flexibility in using a transmission channel when transmitting and receiving data. A method of more efficiently managing a transport channel format between a first layer and a MAC is provided.

A feature of the transport channel format management method of UMTS for achieving the above object is to limit the size of each transport block to an integer multiple of a predetermined number of reference bits for the transport block to be transmitted at each transmission time interval, the reference bit For each transport block size of the transmission time interval unit, which is an integer multiple of a number, a transport format parameter in which a number representing the integer multiple and the number of transport blocks belonging to a transport block set for each transmission time interval unit are combined. And combines the transmitted transport format parameters of the transport channels into one transport format complex parameter, and then transmits the multiple transport channels to a counterpart in a coded complex transport channel that is coded and multiplexed. .

Thereafter, the other party extracts transport format parameters of its own transport channel from the received transport format complex parameter, and then transmits data through each transport channel using the extracted transport format parameter.

1 is a diagram illustrating a process for mapping a transport channel (DCH) and a physical channel in a UMTS radio access standard protocol;

2 shows an example of a transport block and a transport block set;

3 is a view showing a configuration example of a transmission channel according to the present invention.

* Description of the symbols for the main parts of the drawings *

1: coding and multiplexing block

2: demultiplexing and splitting block

Hereinafter, a preferred embodiment of a transport channel format management method of UMTS according to the present invention will be described with reference to the accompanying drawings.

In the present invention, in order to eliminate unnecessary prior interaction between the transmitting side and the receiving side in the UMTS radio access standard protocol, when transmitting a transmission block at every transmission time interval, the size of the transmission block is limited to a predetermined number of bits in advance. The size is defined to be an integer multiple of a predetermined reference number of bits.

In the present invention, the predetermined number of reference bits is called a primary transport block size (hereinafter, abbreviated as PTBS), and a number representing an integer multiple of the PTBS is a transport block number (hereinafter referred to as TBN). Abbreviated).

In addition, in the present invention, a transport block set having transport blocks as a member is represented by an integer multiple of the transport block, which is called a transport block set number (hereinafter, referred to as TBSN). define.

In this case, a parameter combining the TBN and the TBSN is defined as a transport format number (hereinafter, abbreviated as TFN).

In the present invention, when the data is transmitted and received through the transport channel between the first layer (L1) and the MAC, unlike the conventional transmission of the TFI with the data to the first layer (L1), the TFN is the first layer (L1) with the data Is delivered).

Thereafter, the coding and multiplexing block 1 of the first layer L1 is multiplexed with multiple transport channels and collected into a coded composite transport channel (CCTrCH) allocated after the block (1). In this case, all of the TFNs of each transport channel are combined and expressed as a single parameter. The combination of these TFNs is defined as a transport format composite number (hereinafter, abbreviated as TFCN).

When transmitting and receiving data to the other side, the TFCN is collected and configured TFC transmitted through each of the various transport channels, and according to the present invention, unlike the conventional transmission of the parameter TFCI to the receiving side TFCN is transmitted with the data.

3 is a diagram illustrating an example of a configuration of a transport channel according to the present invention, in which PTBS, which is a reference number of bits, is 20 bits.

Accordingly, when the size of the transport block transmitted through the transport channel between the first layer L1 and the MAC during one transmission time interval is an integer multiple of 20 bits, the number representing the integer multiple becomes TBN.

In the case of the first DCH1 in FIG. 3, since the size of a transport block for one transmission time interval is composed of one transport block having 40 bits, the TBN becomes 2 because the size of one transport block is twice the size of 20 bits. TBSN is 1 since there is one transport block in the transport block set.

In the case of the second DCH2, the TBN is 1 because the size of one transport block is 20 bits, and the TBN becomes 1 because the size of the transport block for one transmission time interval is 20 bits. TBSN is 2 because there are two transport blocks in the Transport Block Set).

In the case of the next DCH3, the TBN becomes 2 because the size of one transport block is twice the size of 20 bits because the size of the transport block is 40 bits in one transmission time interval. TBSN is 2 because there are two transport blocks in the Transport Block Set).

Based on the above description, the transmission of the transport channel of the present invention is performed through the following procedure.

First, in each case described above, the parameter TFN combining TBN and TBSN is (2,1), (1,2) or (2,2), respectively, and this TFN is a transport channel between the first layer L1 and the MAC. When transmitting and receiving data through the data, the data is transmitted to the first layer L1.

In other words, the sending MAC sends each of these TFNs together when transmitting the TFS through the transport channel.

The first layer (L1) is transmitted from the MAC through each of several transport channels when configuring multiple transport channels in one coding and multiplexing block (1) as one coded complex transport channel (CCTrCH) Combining three TFNs together, a parameter TFCN consisting of "[(2,1), (1,2), (2,2)]" is constructed and transmitted to the other side.

The first layer (L1) on the receiving side extracts the TFN of each transport channel using the TFCN received from the coded composite transport channel (CCTrCH), and transmits data through each transport channel by using the extracted TFN. can do.

In the present invention described above, all of a transport block size, a transport block set, and a TFC are expressed by a simple combination of integers, based on TBN, which represents an integer multiple of PTBS, which is a reference number of bits. The preset procedure for TFS, TFI, TFCS and TFCI is omitted.

As a result, the receiving side can reduce the detection error of the transmission format combination (TFC) and the transmission format transmitted from the transmitting side, and can transmit the transmission format freely without being limited to the predefined TFCS and TFS, thereby increasing the flexibility of data transmission and reception. It can increase.

Claims (2)

For transport blocks to be transmitted at every transmission time interval, the size of each transport block is limited to be an integer multiple of a predetermined number of reference bits, For a size of each transport block of the transmission time interval unit, which is an integer multiple of the reference number of bits, a transport format parameter in which a number representing the integer multiple and the number of transport blocks belonging to the transport block set for each transmission time interval unit are combined. Through each channel, UMTS, characterized in that the combined transport format parameters of the transmitted multiple transport channels are combined into one transport format complex parameter and then transmitted to the other side in one coded complex transport channel that is coded and multiplexed. Method of management of transport channel format. The method of claim 1, wherein the other party extracts the transport format parameters of its own transport channel from the received transport format complex parameter, and then transmits data through each transport channel by using the extracted transport format parameter. Method of managing a transport channel format of UMTS, characterized in that.