KR100830496B1 - Method for Allocating Forward-Packet Data Control CHannel - Google Patents

Abstract

The present invention relates to a method for allocating a forward packet data control channel. When broadcasting Walsh space information through one forward packet data control channel, Walsh code information is transmitted to a terminal scheduled through the other forward packet data control channel. In order to improve the efficiency of the system by providing.

In addition, when a new terminal enters and schedules a corresponding Walsh space after broadcasting the Walsh space information, the corresponding terminal transmits the Walsh space information and the Walsh code information to the new terminal through two different forward packet data control channels. This is to ensure that the code available for the forward packet data channel is correctly recognized.

F-PDCCH, Walsh Space Mask Bitmap (WALSH_MASK)

Description

Method for Allocating Forward Packet Data Control Channel {Method for Allocating Forward-Packet Data Control CHannel}

1 is a diagram illustrating an application example of a general Walsh space mask bitmap (WALSH_MASK).

2 is a flowchart illustrating a method of allocating an F-PDCCH according to the present invention.

3 is a diagram illustrating an example in which the present invention is applied when F-PDCCH scheduling is performed.

The present invention relates to a mobile communication system, and more particularly, to a method for allocating a forward packet data control channel suitable for improving system efficiency.

1xEVDV, a system designed to simultaneously perform high-speed data transmission and voice communication, has the following features.

First, as a method of enabling high-speed data transmission while efficiently using a wireless channel in a wireless channel environment that changes with time, a method of adaptively determining a modulation scheme and a code rate according to a channel environment change is used.                         

Second, system efficiency can be improved by scheduling a terminal having an optimal channel environment in a wireless channel environment that changes with time.

Third, H-ARQ (Hybrid Automatic Repeat reQuest) method is used, which combines ARQ and Forward Error Correction (FEC) to improve data transmission reliability and system efficiency in a communication system. In this case, the ARQ is intended to improve reliability by requesting retransmission of the same information until the received information is received without error when an error occurs due to the channel environment, and the FEC provides an error correction code. The purpose is to correct errors caused by the channel environment.

Fourth, system efficiency is achieved by using CDM / TDM (Code Division Multiplexing / Time Division Multiplexing) method, which transmits data to other terminals using Walsh codes remaining after a Walsh code is allocated to one terminal in each frame section. Can increase.

In order to implement the CDM / TDM scheme, Walsh code information to be used should be informed to each scheduled terminal. A channel used for this purpose is a forward-packet data control channel (F-PDCCH).

Table 1 below shows information fields included in the F-PDCCH.

Field Length (bits) MAC Identifier (Inner CRC) 8 WALSH_MASK 0 or 13 ARQ channel identifier 0 or 2 Subpacket identifier 0 or 2 ARQ Channel Identifier Sequence Number 0 or 1 Encoder packet size 0 or 3 Last Walsh Code Intex 0 or 5 Sum 21

A MAC_ID (MAC_ID: Medium Access Control IDentifier) is a terminal identifier, and values except (00000000) ₂ indicate a terminal determined to transmit a current subpacket through a forward-packet data channel (F-PDCH).

If the MAC identifier is not (00000000) ₂ , the fields after the MAC identifier, the ARQ channel identifier, sub packet identifier, ARQ channel identifier sequence number, encoder packet size, and last Walsh code index should be transmitted, and Walsh space mask bits. The map WALSH_MASK must be omitted.

If the MAC identifier is (00000000) ₂ , it indicates that the current F-PDCCH is used to broadcast Walsh space information. The WALSH_MASK field, which is thereafter, must be transmitted, and an ARQ channel identifier, a sub packet identifier, and an ARQ channel identifier sequence number. The encoder packet size and last Walsh code index shall be omitted.

An ARQ Channel IDentifier indicates an Automatic ReQuest (ARQ) channel associated with a transmitted subpacket, and a SubPacket IDentifier indicates a selected subpacket.

The ARQ Identifier Sequence Number is used to distinguish whether the corresponding subpacket is the first subpacket sent or the subpacket sent for retransmission. Encoder Packet Size indicates the size of the encoder packet, and the Last Walsh Code Index indicates the last Walsh code assigned to each terminal.

The Walsh space mask bitmap (WALSH_MASK) is used to broadcast Walsh space information and indicates that each corresponding Walsh code is used by another channel and thus cannot be used for the F-PDCH.

The reason for broadcasting Walsh spatial information through WALSH_MASK is because the F-SCH using the 16-ary or higher (8-ary, 4-ary) Walsh code is allocated to the available Walsh space for the F-PDCH. That's because fragmentation occurs or the start point must be different.

1 illustrates an example of applying the Walsh space mask bitmap WALSH_MASK.

Since the maximum number of Walsh codes that can be allocated to the terminal is 28, and WALSH_MASK is 13 bits, WALSH_MASK may indicate whether 13 16-ary Walsh codes, that is, 26 32-ary Walsh codes are used. , The other two Walsh codes are not specified.

Using the above information, each terminal can be assigned a Walsh code used for the F-PDCH. The maximum number of terminals that can be scheduled is two.

When one terminal is scheduled, one forward packet data control channel F-PDCCH0 is allocated to provide control information, that is, Walsh code information, used to decode the allocated F-PDCH to the corresponding terminal. When scheduled at the same time, two forward packet data control channels F-PDCCH0 and F-PDCCH1 are allocated to provide Walsh code information to each terminal.

In addition, when the Walsh space information is changed as other channels such as F-SCH, F-FCH, F-DCCH are newly allocated or released, the Walsh space information should be broadcast. As shown, one forward packet data control channel F-PDCCH0 is allocated to inform the terminal whether 13 16-ary Walsh codes are available for the F-PDCH.

However, when the conventional F-PDCCH allocation method is used, scheduling cannot be performed to the terminal at the corresponding time when the Walsh space information is broadcast.

Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and when it is necessary to broadcast the Walsh space information, the Walsh space information is broadcasted through one F-PDCCH (F-PDCCH0). If there is a terminal to be scheduled at the same time, the remaining one F-PDCCH (F-PDCCH1) is to provide a method for allocating a forward packet data control channel that can be used to schedule the terminal to improve the system efficiency.

According to a feature of the invention, determining whether it is necessary to broadcast the Walsh space information, if it is necessary to broadcast the Walsh space information, determining whether there is a terminal to be scheduled in the corresponding Walsh space, and the terminal to be scheduled If at least one is present, broadcasting the Walsh space information through the first forward packet data control channel, and providing control information to the scheduled terminal of the terminal through the second forward packet data control channel It is characterized by.

In more detail, the terminal having the highest priority among the terminals to be scheduled in the corresponding Walsh space is scheduled.

In more detail, the transmit power strength of the first forward packet data control channel may be such that the transmit power strength can be transmitted to the scheduled terminal.

More specifically, the Walsh space information obtained from the first forward packet data control channel at the moment is used when determining the Walsh code to be used by the scheduled terminal.

In more detail, when it is not necessary to broadcast the Walsh space information, the UE allocates a forward packet data control channel for each scheduled terminal and provides Walsh code information to each terminal through a forward packet data control channel allocated for each terminal. It is characterized by.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.                     

A method of allocating the F-PDCCH according to the present invention will be described with reference to FIG. 2.

First, it is determined whether Walsh space information needs to be broadcast (S11).

As a result of the determination, when it is not necessary to broadcast Walsh space information, F-PDCCHs are allocated by the number of terminals to be scheduled (maximum 2).

That is, when it is not necessary to broadcast Walsh space information, it is determined whether there is a terminal to be scheduled (S21). If there is no terminal to be scheduled, the terminal is not assigned to the F-PDCCH (S41). In step S31, it is determined whether one terminal is scheduled or two are scheduled.

In this case, when only one terminal is scheduled, F-PDCCH0 is allocated to transmit control information, that is, Walsh code information, used to decode the F-PDCH allocated to the scheduled terminal through the F-PDCCH0 (S42). .

In case of two scheduled terminals, F-PDCCH0 and F-PDCCH1 are allocated to F-PDCH0 and F-PDCH1 allocated to two terminals scheduled through F-PDCCH0 and F-PDCCH1. Transmit control information used to decrypt the data (S43).

As a result of determining whether the Walsh space information needs to be broadcast, it is determined whether there is a terminal to be scheduled even when it is necessary to broadcast Walsh space information (S22).

If there is no terminal to be scheduled, F-PDCCH0 is allocated and the Walsh space information available for the F-PDCH is broadcast to all terminals in the corresponding Walsh space (S45).

On the other hand, if there is a terminal to be scheduled, F-PDCCH0 is allocated to broadcast Walsh space information available for the F-PDCH to all terminals in the Walsh space, and the maximum priority among the terminals to be scheduled in the Walsh space is allocated. The F-PDCCH1 is allocated to provide the control information, that is, the Walsh code information, to be used for scheduling to the mobile station and decoding the F-PDCH assigned to the mobile station (S44).

3 shows an example of broadcasting Walsh space information on F-PDCCH0 and transmitting control information used to decode the F-PDCH allocated to the scheduled terminal on F-PDCCH1.

In FIG. 3, since the WALSH_MASK of F-PDCCH0 is (0100100011111) ₂ and the last Walsh code index of F-PDCCH1 is 14, the Walsh code index is 2, 3, or 8 among the available Walsh codes (Wash code index = 0 to 14). In this case, the Walsh code must be excluded.

That is, when determining the Walsh code to be used by the scheduled terminal, the Walsh space information obtained from the F-PDCCH0 is used.

Therefore, Walsh codes assigned to the F-PDCH are {31, 15, 27, 11, 19, 3, 22, 6, 26, 10, 18}.

When the new terminal enters the base station after the Walsh space information is broadcasted and is scheduled, the new terminal cannot know the Walsh space information and cannot accurately determine the Walsh code to use.                     

In this case, Walsh space information is transmitted to the new terminal through F-PDCCH0, and control information used to decode the F-PDCH allocated to the scheduled terminal is transmitted to F-PDCCH1.

In this case, since the Walsh space information is not transmitted to all the terminals in the Walsh space, only the currently scheduled terminal is transmitted. Thus, the transmission signal of the F-PDCCH0 may have a power level that can be received by the corresponding terminal. Have it.

The forward packet data control channel allocation method of the present invention as described above has the following effects.

First, when it is necessary to broadcast the Walsh space information, the efficiency of the system can be improved by allocating one F-PDCCH1 to the terminal by allocating the other F-PDCCH1 in addition to the F-PDCCH0 for broadcasting the Walsh space information.

Second, if a new terminal coming into the base station after the last Walsh space information is scheduled, the Walsh space information and Walsh code information can be transmitted to the corresponding terminal to correctly recognize the Walsh code available for the F-PDCH.

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 examples, but should be defined by the claims.

Claims (5)

In the mobile communication system that supports high-speed data and voice communication at the same time, Determining whether it is necessary to broadcast Walsh spatial information; If it is necessary to broadcast the Walsh space information, determining whether a terminal to be scheduled exists in the corresponding Walsh space; And Broadcasting Walsh space information through a first forward packet data control channel when at least one terminal to be scheduled exists, and providing control information to one of the terminals scheduled through the second forward packet data control channel. The forward packet data control channel allocation method comprising a. The method of claim 1, The method according to claim 1, wherein the terminal having the highest priority among the terminals to be scheduled in the corresponding Walsh space is scheduled. The method of claim 1, The transmit power strength of the first forward packet data control channel is And a power strength to be transmitted to the scheduled terminal. The method of claim 1, And the Walsh spatial information obtained from the first forward packet data control channel at the moment when determining the Walsh code to be used by the scheduled terminal. The method of claim 1, When the Walsh space information does not need to be broadcast, the forward packet data control channel is allocated to each scheduled terminal and the Walsh code information is provided to each terminal through the forward packet data control channel assigned to each terminal. Packet data control channel allocation method.

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