KR20030071310A - Method for Transmitting of Walsh code Information - Google Patents

Abstract

PURPOSE: A method for transmitting Walsh code information is provided to efficiently transmit high-speed data through a wireless channel. CONSTITUTION: Walsh code assignment information for at least one terminal is mapped to a bit sequence having the number of bits identical to Walsh code information to be transmitted to the terminal. The mapping is repeatedly performed according to the number of the bit sequence, and the mapping result is stored in a base station and the terminal. Walsh code information is broadcasted to serviced terminals. Broadcasted Walsh code information is compared with the bit sequence of the mapping result, and Walsh code assignment information of each terminal is obtained.

Description

Method for Transmitting of Walsh code Information

The present invention relates to wireless communication, and more particularly, to a method of transmitting Walsh information in a CDM / TDM for efficiently transmitting high-speed data through a wireless channel.

Since the wireless communication environment is a channel that changes according to the location and mobility of the terminal, there is a need for a method that can adapt to a changing channel.

As a method of enabling high-speed data transmission while efficiently using a wireless channel in a wireless channel environment that changes over time, a method of accommodating and adapting a channel to change a modulation scheme and a channel coding are changed. There is a way to.

In order to reduce the error rate by adding an extra amount of information data using channel coding, an increase in the amount of data transmitted on an actual wireless channel is essential.

Since the wireless communication environment is a channel that changes according to the location and mobility of the terminal, it is possible to increase the transmission speed by sending a lot of actual information data by using a high code rate coding, which reduces the amount of redundancy when the communication environment is good. In addition, when the wireless communication environment is bad, it is necessary to use a low code rate coding that gives a lot of redundancy so that it is resistant to errors, and thus, the transmission rate should be low.

On the other hand, in the modulation method, when a wireless communication environment is good, high-speed data transmission such as quadrature amplitude modulator (QAM) or phase shift keying (PSK), which transmits several information bits in one transmission symbol, is performed. When this possible transmission method is used, if the wireless communication environment is bad, a transmission method such as BPSK (Binary Phase Shift Keying), which is strong against interference noise but has a slow transmission speed, is selected.

The above modulation scheme should send information about the channel environment from the receiver for estimating the channel environment in order to adapt the environment of the channel to change the modulation method and the coding method.

In addition, a system requiring efficient high-speed data transmission uses a time division multiplexing (TDM) scheme for scheduling a terminal to transmit data in every transmission unit interval in consideration of channel environment information and amount of data to be transmitted.

Before describing the data transmission of the TDM scheme, the parameters discussed below will be described.

Walsh code is a generic name for codes that are orthogonal to each other used when transmitting physical channels.

The Walsh Code Space is a collection of Walsh codes currently available when the base station transmits packet data. The components change over time.

Packet Data CHannel (PDCH) (i) means the i-th PDCH when more than two PDCHs are available. In this case, each PDCH uses Walsh codes in Walsh code space separately.

PDCCH (i) is a generic name of a physical channel that contains control information transmitted by a base station to terminals in order to successfully receive PDCH (i) when more than one PDCH may exist.

Figure 1 shows an example of data transmission by the TDM method.

In FIG. 1, the transmission unit time length may be fixed or variable.

However, if only one terminal is transmitted in every transmission unit interval as in TDM, data is good, but if the amount of data to be transmitted is small, Walsh space remains, resulting in an inefficient system.

Accordingly, in the TDM packet data transmission system, CDM / TDM (Code) that transmits data to another terminal using Walsh remaining even after assigning Walsh to one terminal in each transmission unit interval for efficient use of resources. Division Multiplexing / Time Division Multiplexing) has been introduced.

2 shows an example of transmission by the CDM / TDM method.

As shown in FIG. 2, several CDM terminals may exist in one transmission unit section.

When the CDM / TDM method is used, when the number of CDM terminals is 3 or more, it is known that the performance of the entire system is not greatly improved. Therefore, the maximum number of CDM terminals is limited to two in the 1 × EVDV system.

Fields of the PDCCH (or SPDCCH: also called Secondary PDCCH) proposed in 1 × EVDV to implement CDM / TDM are shown in Table 1 below.

Field Length (bits) MAC Identifier (Inner CRC) 8 ARQ channel identifier 2 Subpacket identifier 2 Encoder packet size 3 Last Walsh Code Index 5 Sequence bits One Sum 21

In Table 1, the MAC identifier is a terminal identifier, and values except for (00000000) _{2 indicate} to which terminal information of the PDCCH being transmitted is transmitted.

The ARQ channel identifier and the sub packet identifier are binary information bits that inform the terminal whether to retransmit information on the PDCH corresponding to the PDCCH. The encoder packet size tells the number of bits of data information transmitted on the PDCH.

The Last Walsh Code Index is a binary information bit indicating information on a Walsh code used by a corresponding PDCH (i) among codes on a Walsh code space. The last Walsh code index indicates information on a Walsh code assigned to each terminal. This is part of telling.

In addition, in order to indicate whether an error occurs when the information bits shown in Table 1 are transmitted through a physical channel, error detection coder bits such as a CRC code are added during transmission, or whether an error occurs in the MAC identifier. It adds a function to distinguish between them. Like the latter, since the MAC identifier is used to distinguish the occurrence of an error in the transmission, it is also called the inner CRC (Internal CRC).

For example, if there are two terminals to be CDM, the base station sends PDCCH1 to terminal 1 and PDCCH2 to terminal 2 to inform the PDCH information.

Terminal 1 receives the Last Walsh Code Index WCI1 of the PDCCH1, and reads the Walsh code assigned to it from the Walsh code list according to the WCI1.

The terminal 2 reads the last Walsh code index WCI1 of the PDCCH1 and the last Walsh code index WCI2 of the PDCCH2 to obtain Walsh code information allocated to the terminal from the Walsh code list.

Table 2 shows an example of the Walsh code list.

Last Walsh Code Index 32-ary Walsh Code Last Walsh Code Index 32-ary Walsh Code One 31 15 30 2 15 16 14 3 23 17 22 4 7 18 6 5 27 19 26 6 11 20 10 7 19 21 18 8 3 22 2 9 29 23 28 10 13 24 12 11 21 25 20 12 5 26 4 13 25 27 24 14 9 28 8

For example, if the last Walsh code index (WCI1) reads from the PDCCH1 by the terminal 1 is 5, and the last Walsh code index (WCI2) reads from the PDCCH2 by the terminal 2 is 8, the terminal 1 displays the Walsh code index of Table 2 above. Walsh is assigned from 1 to WCI1, that is, from 1 to 5 (31, 15, 23, 7, 27), and terminal 2 has WCI1 + 1 to WCI2, that is, from 6 to 8 (11, 19, 3). Walsh is assigned.

As described above, conventionally, the PDCCH field transmitted in parallel with the PDCH transmits a last Walsh code index including Walsh information.

However, when the change in the channel environment decreases, the change in the Walsh information allocated to each terminal is also less. Therefore, the last Walsh code index bits included in the PDCCH each time the PDCH is transmitted, the number of bits is increased without any role.

As a result, there is a problem that the decoding capability of the PDCCH field is degraded and the performance of the system is degraded.

Accordingly, the present invention has been made in view of the above-mentioned problems of the prior art, and is to provide a Walsh code information transmission method in CDM / TDM that is suitable for improving the performance of the system.

According to an aspect of the present invention for achieving the above object, in a mobile communication system using a code division scheme and a time division scheme, at least one terminal in a bit sequence consisting of the same number of bits as Walsh code information to be transmitted to the terminal Mapping the Walsh code assignment information for the network; repeating the mapping according to the number of bit sequences and storing the mapping result in the base station and the terminal; broadcasting the Walsh code information to serviced terminals; And comparing the broadcast Walsh code information with a bit sequence of the mapping result to obtain Walsh code assignment information of each terminal.

According to another aspect of the present invention for achieving the above object, in a mobile communication system using a code division scheme and a time division scheme, the number of Walsh codes allocated to at least one terminal by using the fields of the packet data control channel Storing a predetermined Walsh code assignment information table, receiving a Walsh code information by broadcasting a specific field of the packet data control channel to a predetermined random value, and transmitting the Walsh code assignment information according to the Walsh code information. And assigning the number of Walsh codes corresponding to the table to the corresponding terminal.

In more detail, the Walsh code information may be broadcast using a Packet Data Control Channel (PDCCH).

More specifically, the method further comprises the step of assigning a Walsh code for each terminal according to the Walsh code assignment information of each terminal.

More specifically, in the case of mapping Walsh code assignment information for two terminals to the bit sequence, the value of Walsh code assignment information allocated to one terminal is greater than the value of Walsh code assignment information allocated to another terminal. Or to be equal.

In more detail, the Walsh code information may be broadcast using the remaining bits except for the terminal identifier in the packet data control channel when the terminal identifier of the packet data control channel is '00000000'.

In more detail, the terminal identifier uses a MAC identifier.

1 is a diagram showing an example of data transmission by a TDM scheme.

2 is a diagram showing an example of data transmission by the CDM / TDM scheme.

3 is a diagram illustrating possible Walsh codes when the maximum CDM terminal is 2;

Hereinafter, the configuration and operation according to an embodiment of the present invention will be described with reference to the accompanying drawings.

The present invention proposes a Walsh code information transmission method for improving system performance in a CDM / TDM packet data transmission system.

Table 3 below shows fields of the PDCCH used in the present invention.

Field Length (bits) MAC Identifier (Inner CRC) 8 ARQ channel identifier 2 Subpacket identifier 2 Encoder packet size 3 Sequence bits One Sum 16

In the PDCCH used in the present invention, as shown in Table 3, the last Walsh code index has been deleted compared to the prior art, thereby reducing 5 bits. Other types of information bits other than the information bits shown in Table 3 may be added, which is irrelevant to what the present invention intends to achieve.

In Table 3, the ARQ channel identifier and the sub packet identifier are binary information bits that inform the terminal whether to retransmit information on the PDCH corresponding to the PDCCH.

In detail, the ARQ channel identifier is for identifying each encoder packet when a plurality of encoder packets are transmitted in parallel to one terminal, and the sub packet identifier is a number of sub packets in one encoder packet. Information about whether a symbol encoded from one information stream is repeated and divided into predetermined subpackets.

The encoder packet size is a binary information bit that tells the number of data information bits to be transmitted on the PDCH.

The MAC identifier is a terminal identifier and indicates to which terminal the information of the PDCCH being transmitted is transmitted in values except for (00000000) ₂ .

As shown in the field structure of the PDCCH of Table 3, the PDCCH of the present invention has no bit structure for transmitting Walsh information. Therefore, in the present invention, Walsh information is not transmitted when PDCH and PDCCH are transmitted.

In the present invention, the Walsh code assignment information for at least one terminal is mapped to a bit sequence consisting of predetermined bits prior to service, and the mapping table is configured by repeating the mapping corresponding to the number of bit sequences. And save it to the terminal.

In this case, the number of bits of the bit sequence is 8 bits, that is, the number of bits of Walsh information to be transmitted to the terminal of the terminal, that is, the number of bits other than the MAC identifier in the PDCCH.

The Walsh information is broadcasted to all terminals when the MAC identifier of the PDCCH has a specific bit value.

For example, when the MAC identifier is a bit that does not have a terminal identification function, such as (00000000) ₂ , the Walsh information is updated by broadcasting Walsh information in the remaining 8 bits except the MAC identifier of the PDCCH.

In this case, if the change of the channel environment is large and the change of Walsh information allocated to each terminal is large, increase the number of times of broadcasting the Walsh information. If the change of channel is small, the Walsh information is broadcast. Reduce the number of times

That is, since the use of bits for Walsh information transmission can be reduced when the channel change is small, the present invention can be particularly useful when the channel environment changes little.

In the present invention, the maximum number of CDM terminals is not limited, but in general, when the number of CDM terminals is three or more in the CDM / TDM scheme, it is known that the performance of the entire system is not significantly improved compared to the complexity of the algorithm. Currently, two CDM maximum terminals are considered preferable. In fact, in the 1 × EVDV system, the maximum number of CDM terminals is limited to two.

Hereinafter, the present invention will be described in more detail by way of example when the maximum CDM terminal is two.

In an embodiment of the present invention, Walsh information should be informed to two terminals served using 8 bits other than 8 bits of the MAC identifier of the PDCCH.

Since the maximum number of Walsh codes that can be allocated to the terminal is 28, if the number of Walsh assigned to the terminal 1 is WSC1 and the number of Walsh assigned to the terminal 2 is WSC2, the terminal should be WSC1 + WSC2≤28. A total of 10 bits are required, 5 bits per piece.

Therefore, since 10 bits cannot be represented by 8 bits except the MAC identifier, the present embodiment proposes that WSC1 > WSC2. That is, Walsh is allocated to terminal 1 more than terminal 2.

In this case, as shown in Table 4 and FIG. 3, the total number of possible Walsh information is limited to 224, so that an 8-bit bit sequence can be represented.

Bit sequence WSC1 WSC2 00000000 One 0 00000001 One One 00000010 2 0 00000011 2 One 00000100 2 2 00000101 3 0 … … … 11011111 27 One 11100000 28 0

The bit sequence corresponds to a bit stream that Walsh information may have, and is equal to the number of bits except for the MAC identifier of the PDCCH, which is a transmission channel of Walsh information. That is 8 bits.

Subsequently, the Walsh information is broadcast in 8 bits except the MAC identifier.

At this time, each of the terminals (terminals 1 and 2) and the base station is previously stored in the mapping table of Table 4, the terminal 1, 2 has its own Walsh code number WSC1, according to the bit value contained in 8 bits except the MAC identifier Recognize each WSC2

Then, from Table 2, the terminal 1 can know the WSC1 Walsh codes from 1 to WSC1, the terminal 2 finds that the WSC2 Walsh codes from WSC1 + 1 to WSC1 + WSC2 are assigned to them.

By using the present invention as described above, since the Walsh information does not need to be transmitted for each PDCCH sent during the transmission of the PDCH, the number of bits of the PDCCH can be reduced and the PDCCH decoding capability can be improved, thereby improving system performance. It works.

In particular, the present invention is more effective in an environment in which the change of the channel environment is small and the change of Walsh information allocated to each terminal is small, that is, the frequency of updating the Walsh information is low.

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 (7)

In a mobile communication system using a code division method and a time division method, Mapping Walsh code assignment information for at least one terminal to a bit sequence having the same number of bits as Walsh code information to be transmitted to the terminal; Repeating the mapping according to the number of bit sequences and storing the mapping result in the base station and the terminal; Broadcasting Walsh code information to serviced terminals; And comparing the broadcasted Walsh code information with a bit sequence of the mapping result to obtain Walsh code assignment information of each terminal. The method of claim 1, wherein the Walsh code information is broadcasted using a Packet Data Control Channel (PDCCH). The method of claim 1, further comprising: assigning a Walsh code for each terminal according to Walsh code assignment information of each terminal. 2. The method of claim 1, wherein when mapping Walsh code assignment information for two terminals to the bit sequence, a value of Walsh code assignment information allocated to one terminal is greater than that of Walsh code assignment information allocated to another terminal. Walsh code information transmission method characterized in that it is equal to or greater than. The Walsh code information transmission according to claim 2, wherein the Walsh code information is broadcast using the remaining bits except for the terminal identifier in the packet data control channel when the terminal identifier of the packet data control channel is '00000000'. Way. 6. The method of claim 5, wherein the terminal identifier uses a MAC identifier. In a mobile communication system using a code division method and a time division method, Storing a Walsh code assignment information table for determining the number of Walsh codes allocated to at least one terminal by using fields of a packet data control channel; Receiving Walsh code information by broadcasting a specific field of the packet data control channel to a predetermined random value; And assigning the number of Walsh codes corresponding to the Walsh code assignment information table to the corresponding terminal according to the Walsh code information.