KR100606099B1 - Method and apparatus for configuration of ack/nack channel in a frequency division multiplexing system - Google Patents

Abstract

The present invention relates to an efficient channel setting method and a transmission / reception apparatus of channels for transmitting an ACK / NACK response for supporting retransmission of packet data received in a wireless communication system using frequency division multiple access (FDM). will be. The present invention proposes a method and a transmitting / receiving apparatus for allocating channels for transmitting an ACK / NACK response to be mapped to a transmission channel of packet data composed of time-frequency resources. In the case of applying the present invention, the ACK / NACK transmitter selects and transmits an ACK / NACK channel to be transmitted using channel information of packet data received at each transmission point. Since the transmission resources of the ACK / NACK channel is preset for each packet data transmission channel as described above, it is not necessary to allocate an ACK / NACK channel for each terminal exclusively, so if a number of terminals increases in one base station, Since it is used for the NACK channel, it has an efficiency in resource usage.

OFDM, DFDM, IFDM, ACK / NACK channel transmission, channel mapping

Description

METHOD AND APPARATUS FOR CONFIGURATION OF ACK / NACK CHANNEL IN A FREQUENCY DIVISION MULTIPLEXING SYSTEM}

1 is a diagram illustrating a general frequency division multiple access scheme.

2 is a diagram illustrating a transmitter structure of a general OFDM based system.

3 illustrates a typical IFDM / LFDM transmitter.

4 is a diagram illustrating a process of mapping an ACK channel to another packet data subchannel in a preferred embodiment of the present invention.

5 is a flowchart illustrating a transmission procedure of an ACK / NACK transmitter according to a preferred embodiment of the present invention.

6 is a flowchart illustrating a receiving procedure of an ACK / NACK receiving end according to a preferred embodiment of the present invention.

7 is a diagram illustrating the structure of an ACK / NACK transmitter according to a first preferred embodiment of the present invention.

8 is a diagram showing the structure of an ACK / NACK receiver according to a first preferred embodiment of the present invention.

9 illustrates a structure of an ACK / NACK transmitter according to a second preferred embodiment of the present invention.

10 is a diagram showing the structure of an ACK / NACK receiver according to a second preferred embodiment of the present invention.

 The present invention relates to a mobile communication system, and more particularly, to a method and apparatus for setting a transmission resource of a channel for transmitting an ACK / NACK in a frequency division multiple access based wireless communication system.

First, frequency division multiplexing (FDM) will be described. FDM refers to a method of distinguishing transmission physical channels by allocating frequencies. In general, the total resource used (resource) is divided as shown in 101 in the frequency domain and time domain. The minimum block of the entire user source 101 is composed of one symbol in the time domain and one sub-carrier in the frequency domain, which is referred to as a time-frequency bin, It is called "TF bin" and is a unit in which one modulated symbol is transmitted during actual physical channel transmission. The total number of TF bins is determined by the total frequency bandwidth size of the system and the number of transmittable symbols within a transmission time interval (hereinafter referred to as "TTI").

In more detail, the FDM method means a method of allocating some different TF bins from the entire T-F bins to the channel and the terminal to be transmitted. In the basic FDM scheme, one TF bin cannot be shared among different channels or terminals, but a channel having a low data rate can be used for covering or spreading to obtain diversity in time-frequency space. When performing the same process, it is possible to share by using a code such as Code Division Multiplexing (CDM). However, in the case of transmission of packet data with high transmission rate, a method of purely dividing and assigning T-F bins is mainly used. The mapping of the transmission symbol and the T-F bin of data to be transmitted is performed through subcarrier mapping. Which T-F bin a particular channel uses is determined by pre-signaled or defined rules. In the case of transmission of packet data or signaling transmitted to each terminal among channels, the corresponding channel must be allocated to each terminal, and thus the TF-bin allocated to each channel is allocated to each terminal again. The TF bins that are allocated directly can be allocated for each UE, but in order to facilitate signaling, the TF bins allocated to a specific channel can be collected to form a logical channel again as shown in 103. channel). One subchannel consists of a plurality of T-F bins and the amount is determined in consideration of the characteristics of each channel.

In other words, in the case of a packet data channel, the number of T-F bins in one subchannel is determined in consideration of the minimum data rate of the packet data and a signaling overhead such as information on the scheduled subchannel when the scheduling is performed. In the case of the control channel, the T-F bin of the control subchannel may be determined according to the number of transmission bits per TTI of the control channel. Which subchannel to use for a particular UE is scheduled for every TTI or configured through higher signaling. 1 illustrates an example in which subchannel # 1 is allocated to UE # 1. In step 105, the packet data symbol of the terminal 1 is mapped to the channel # 1 of the packet data channel through the subchannel mapping process 104 of 104, and then to the actual TF-bin through the subcarrier mapping process. When subcarrier mapping, depending on frequency diversity or TF bin allocation algorithm, when subchannels are mapped to actual TF-bins, they may be mapped to TF-bins spread like 106 blue blocks or 103 red. It may be mapped to adjacent TF bins like a block. Since the subchannel is a channel having a logical meaning, when only transmitting a subchannel allocated to the terminal, such as a terminal, only submap mapping is performed since only an operation of mapping a corresponding transmission symbol to a predefined or allocated TF bin is performed. It may not be. In addition, in the case of ACK / NACK having 1-bit information as shown in 109 in FIG. 1, since the corresponding TF bin is one subchannel, the subchannel mapping is directly connected to the TF bin, which is also directly connected to the TF bin without subchannel mapping. Sometimes mapped.

In the above-mentioned method using FDM, orthogonal frequency division multiplexing (OFDM) transmission technology has been widely applied as a technology of broadcasting and mobile communication systems. The OFDM technology eliminates interference between multipath signal components commonly present in a wireless communication channel, guarantees orthogonality among multiple access users, and enables efficient use of frequency resources. Therefore, it is useful for high speed data transmission and wideband system compared to the existing code division multiple access technology.

2 is a diagram illustrating a transmitter structure of a general OFDM based system.

First, the packet data channel generator 203 and the signaling channel generators 204 and 213 exist as blocks for generating data to be transmitted for each channel. Receives data to be transmitted to each channel in the block and generates a symbol through a coding scheme and a modulation scheme that are predefined or set according to each channel. Next, there are subchannel mapping blocks 205 and 214 to perform the operation of mapping the generated symbols to subchannels. The subcarrier mapping process 208 may be performed immediately without subchannel mapping as shown in 212. Generally, when an ACK / NACK or a power control bit is mapped to 1 TF bin, the subcarrier mapping process may operate without the subchannel mapping process as described above. . Next, in the multiplxing block 208, a process of mapping a transmission symbol mapped to a logically allocated subchannel to an actual T-F bin is performed. Alternatively, through step 212, all channels to be transmitted can be regarded as multiplexed. The multiplexed frequency domain signals are converted into a signal in the time domain through an Inverse Fast Fourier Transform (IFFT) 209 operation and transmitted.

However, the OFDM technique described above is a multi-carrier transmission technique, and transmits data in parallel by dividing the transmission data into several subcarriers so that the peak-to-average power ratio of a transmission signal is hereinafter. There is a problem of increasing the 'PAPR'. Large PAPR causes distortion of the output signal in the transmitter's Radio Frequency (RF) power amplifier, so the transmitter requires a power back-off that reduces the amplifier input power to avoid the problem. do. Therefore, when the OFDM technology is applied to the uplink of the mobile communication system, the terminal needs to perform power backoff on the transmitted signal, resulting in a decrease in cell coverage.

Recently, research on IFlea (Interleaved Frequency Division Multiple Access) has been actively conducted as a technique for reducing the PAPR problem of OFDM technology. Like OFDM, IFDM guarantees orthogonality among multiple access users, and also has the advantage that PAPR of a transmission signal is very low as a technology based on single carrier transmission. Therefore, the cell coverage reduction problem due to PAPR is reduced when applied to a mobile communication system.

3 is a diagram illustrating a transmission structure of an IFDM or LFDM based system.

Compared to the OFDM of FIG. 2, the difference is that IFFT 307 is performed after fast Fourier transform (FFT) operations 304, 309, and 314 so that data is not transmitted in parallel at various frequencies. Send it through. Since the symbols transmitted in the time domain do not overlap several frequencies through the above process, PAPR can be reduced. Differences between IFDM and LFDM are distinguished in mapping data of the corresponding subchannel to subcarriers in the multiplex 306 block. In other words, the case of transmitting using the subcarriers scattered at equal intervals may be regarded as an IFDM scheme, and the case of mapping to a localized subcarrier may be regarded as an LFDM scheme.

Next, HARQ will be described. In the case of packet data, in order to ensure reliable transmission, the receiver transmits an ACK when the receiver receives normal data through the CRC check of the packet data, and transmits a NACK when the CRC check does not pass. When the transmitting end receives the ACK, the transmitting end transmits new packet data at the next transmission point, and when receiving the NACK, retransmits the transmitted data. In retransmission, the same symbol may be transmitted according to a retransmission scheme, or may be transmitted by modulating different parity bits. After receiving the NACK, the receiving side may soft combine the received symbols with the previously received symbols and perform demodulation again to increase reliability of data transmission with low power.

The following describes a conventional transmission method of the ACK / NACK response. As a method of transmitting ACK / NACK information indicating whether the receiving side has normally received packet data, a method of exclusively setting a channel for each terminal has been mainly used. In environments where channels are non-orthogonal, such as CDMA, the code can be used on a per-device basis because the total amount of available resources is not directly related to the number of codes, but is limited by the transmit power or the received interference level. Even if they were allocated one by one, it was not a big problem in terms of resource utilization unless used by the sender. However, since the T-F resources in the FDM system have orthogonal characteristics, the amount of T-F resources directly affects the amount of available resources. Therefore, if the T-F resource allocated to the ACK channel is not used, it may be a waste in terms of resource utilization. In particular, the problem becomes more serious when the number of terminals connected in one base station increases.

Accordingly, an object of the present invention, which is designed to solve the problems of the prior art operating as described above, is to dedicate a transmission resource of a channel for transmitting ACK / NACK for each terminal in a frequency division multiple access based wireless communication system. The present invention provides a method for efficiently allocating without allocating and an apparatus for transmitting and receiving an ACK channel.

Another object of the present invention is to provide a method and apparatus for mapping a transmission resource of an ACK channel to a time-frequency resource of a channel through which actually transmitted packet data is transmitted in establishing an ACK channel in a frequency division multiple access based wireless communication system. To provide.

Another object of the present invention is to provide a method and apparatus for setting ACK channels mapped to a subchannel through which packet data is transmitted in setting an ACK channel.

It is still another object of the present invention to check the channel information of a received packet data channel at the time when the ACK / NACK transmitter receives the packet data and transmits the ACK / NACK, and then ACK / NACK using the ACK channel mapped to the channel. A method and apparatus for transmitting a response are provided.

Another object of the present invention is to check the channel information of the packet data channel transmitted at the time after the ACK / NACK receiver transmits the packet data to receive the ACK / NACK response through the ACK channel mapped to the channel It is to provide a method and a receiving device.

An embodiment of the present invention, which is designed to achieve the above object, in the apparatus for setting and transmitting a positive and negative response channel in a frequency division multiple access system, the packet data received through the sub-channel is normally received An acknowledgment generator for generating a response symbol indicating whether a response symbol is generated, and the transmission resource of the response channel mapped to each subchannel by using the response channel time-frequency time-frequency resource information and predefined mapping information of the packet data subchannel. A response channel time-frequency resource determiner for selecting and determining a time-frequency time-frequency resource of the selected response channel, a multiplexing block for mapping the generated response symbol to the determined time-frequency resource, from the multiplexing block; Receive the response symbol mapped to the time-frequency resource It characterized by configured to inverse fast Fourier transform block and transmitting the converted to.

Another embodiment of the present invention is a device for receiving a response signal through a positive and negative response channel in a frequency division multiple access system, the time domain signal including a response signal for the packet data transmitted through the sub-channel By using a receiving unit receiving through the response channel, a fast Fourier transform block for converting the received response signal into a frequency domain signal, predefined mapping information of the response channel time-frequency resource information and the packet data subchannel, A response channel time-frequency resource determiner for selecting a response channel corresponding to each sub-channel and determining a time-frequency resource of the selected response channel, and the determined time-frequency resource from the frequency domain signal output from the fast Fourier transform block; A demultiplexing block for detecting a response symbol mapped to the; And a positive channel decoder for outputting positive and negative response bit information by decoding the ball. [0013] Another embodiment of the present invention provides an apparatus for setting and transmitting positive and negative response channels in a frequency division multiple access system. A Walsh code determiner configured to select a response channel mapped to a specific subchannel and determine a Walsh code of the selected response channel by using mapping information of an orthogonal code assigned to a response channel and a packet data subchannel; A Walsh covering block for Walsh covering a response bit indicating whether an error of the packet data received through the specific subchannel using a Walsh code; and the selected response based on the mapping information of the Walsh covered symbol. A subchannel mapping unit for mapping to a subchannel for a channel, and the mapped subchannel Characterized by configured to inverse fast Fourier transform block for transmitting and converting the multiplex block, the multiplexed information, for multiplexing with the other sub-channel to a time domain signal.

Another embodiment of the present invention is a device for receiving a response signal through a positive and negative response channel in a frequency division multiple access system, comprising: a time domain including a response signal for packet data transmitted using a subchannel A receiver for receiving a signal through the response channel, a fast Fourier transform block for converting the received response signal into a frequency domain signal, a demultiplexing block for demultiplexing the frequency domain signal and outputting a plurality of subchannel signals; And a subchannel demapping unit for performing subchannel demapping of the Walsh covered signal of the response channel corresponding to the subchannel based on the subchannel information from the demultiplexed subchannel signal, Walsh code information and a packet. The Walsh code of the response channel corresponding to the subchannel is received by receiving data subchannel information. And a Walsh Decovering block that selects a code determiner and selects a Walsh decovered signal by Walsh decovering the Walsh covered signal with the selected code.

Another embodiment of the present invention is a method for setting and transmitting a positive and negative response channel in a frequency division multiple access scheme system, the method comprising: receiving packet data through a subchannel, and including the received packet data Obtaining the information of the subchannel, selecting a response channel corresponding to the information of the subchannel using mapping information mapping the information of the predefined subchannel and the response channel, and Generating a response signal and transmitting the response signal through the response channel.

Another embodiment of the present invention provides a method for receiving a response signal through a positive and negative response channel in a frequency division multiple access scheme system, the method comprising the steps of: transmitting packet data through a subchannel; Obtaining the information of the subchannel included; selecting a response channel corresponding to the information of the subchannel by using mapping information for mapping the information of the predefined subchannel and the response channel; and transmitting the transmitted packet. And receiving a response signal of data through the response channel.

Hereinafter, the operating principle of the present invention will be described in detail with reference to the accompanying drawings. In the following description of the present invention, when it is determined that detailed descriptions of related known functions or configurations may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. Terms to be described later are terms defined in consideration of functions in the present invention, and may be changed according to intentions or customs of users or operators. Therefore, the definition should be made based on the contents throughout the specification.

The reason for allocating transmission resources of the ACK channel for each terminal is that the number of terminals connected to the base station per base station is currently viewed up to 400 persons based on the 10 MHz bandwidth (BW). If 1 TF bin is allocated to each UE exclusively for ACK / NACK bit transmission, 400 TF bins should be allocated in advance and the number of valid TF bins at 10MHz is 500 ~ 600, which is quite inefficient. . Of course, if packet transmission occurs between the connected terminals and the base station at every transmission time, setting by the terminal becomes a meaningful method. However, in the frequency domain division multiplexing system, since only terminals allocated with time-frequency resources transmit packet data, it can be predicted that as many ACK / NACK information as the number of terminals are transmitted. The maximum number of packet data that can be transmitted at the time of transmission is related to the maximum number of resources allocated to the packet data to transmit different packet data.

However, as mentioned above, the allocation of the transmission resources of the ACK channel to the terminals for each TF bin, which is the minimum unit of the packet data resource, is generally inefficient in terms of signaling overhead and scheduling efficiency of the control channel. TF bins are grouped to form one subchannel and packet data is transmitted for each subchannel. In other words, it is possible to transmit and receive different packet data by the maximum number of subchannels in one cell, and the ACK / NACK is required.

For the above reason, the present invention allows the transmission resource of the ACK channel to be mapped to the time-frequency resource of the channel through which actually transmitted packet data is transmitted in setting the ACK channel in a frequency division multiple access based wireless communication system. To this end, an ACK channel is allocated for each packet data subchannel allocated for packet data transmission, and an ACK channel to be used for transmitting an ACK / NACK response is obtained using an ACK channel mapped to a subchannel of the received packet data. Send it.

In the following description, a transmitter maps a packet data subchannel and an ACK channel, selects an ACK channel to be used based on channel information of a packet data channel received by the ACK / NACK transmitter, and transmits an ACK / NACK response based on the selected information. An ACK channel to be used is selected based on channel information of a packet data channel transmitted by the ACK / NACK receiver, and the receiver for receiving the ACK / NACK based on the selected information will be described.

4 is a diagram illustrating a process of mapping an ACK channel to another packet data subchannel in a preferred embodiment of the present invention.

First, as in 401, when configuring the minimum transmission rate and scheduling of the packet data actually transmitted for packet data transmission, it is configured in units of subchannels in consideration of the overhead of related control information signaling. The subchannel consists of a plurality of T-F bins. The subchannel may be regarded as a minimum physical channel unit for packet data transmission. In FIG. 4, the packet data channel is composed of eight subchannels. The present invention proposes to set the number of ACK channels necessary for packet data transmission to be equal to the number of subchannels. As can be seen in 402, it can be seen that ACKCH, which is a subchannel for eight ACK channels, is set. The following proposes that a packet data subchannel and an ACKCH have a specific mapping relationship. One-to-one mapping, as shown below, is an example of a mapping relationship.

Packet data channel # 1 => ACKCH1

Packet data channel # 2 => ACKCH2

… .

Packet data channel # 8 => ACKCH8
As described above, the mapping relationship between the packet data subchannel and the ACKCH may be defined in advance or may be set by higher signaling.

5 is a flowchart illustrating a transmission procedure of an ACK / NACK transmitter according to a preferred embodiment of the present invention.

As shown in FIG. 4, a transmission procedure in the case where the ACKCH is set is received. In step 501, packet data is received, and in step 502, a subchannel of the packet data channel to which the received packet data is transmitted is examined. Since the information of the subchannel is signaled through the control channel in the downlink and is allocated through the scheduling assignment channel in the uplink, both the information about the base station and the terminal can be known. After acquiring the information on the subchannel of the transmitted data, in step 503, the ACKCH mapped to the corresponding subchannel is selected. When ACKCH is mapped according to the above mapping rule, when packet data is transmitted to subchannel # 1, ACKCH # 1 is selected. If the ACKCH is determined, the ACK / NACK information is transmitted in step 504.

Here, as described in the related art, although one subchannel may be transmitted depending on the data rate of a packet to be transmitted, a case of transmitting using a plurality of packet data subchannels may occur. When data is received through a plurality of packet data subchannels, one ACK / NACK bit information is generated when the size of a transport block of demodulated data is one. In other words, according to the present invention, if there are several packet data subchannels, the number of usable ACKCHs is several, but the ACK / NACK bit information to be transmitted is one. In this case, one piece of ACK / NACK bit information may be simultaneously transmitted to a plurality of ACKCHs, or one ACKCH may be designated and transmitted according to a predefined rule. In the case of the former method, since transmission is performed using several subchannels, there is an advantage of increasing reliability of ACK / NACK or lowering transmission power of one subchannel. In the latter method, for example, when one packet data is received through three subchannels up to data subchannels # 1 to # 3, ACK / NACK is performed through ACKCH1 mapped to data subchannel # 1, which is the lowest subchannel. Send it.

6 is a flowchart illustrating a reception procedure of an ACK / NACK receiver according to an exemplary embodiment of the present invention.

In FIG. 6, the ACKCH mapped to the packet data subchannel is selected based on the information of the packet data subchannel to receive the ACK / NACK.

In detail, in step 601, the packet data is transmitted, the subchannel of the packet data channel to which the packet data transmitted in step 602 is transmitted is obtained, and subchannel information of the transmitted data is obtained. Selected ACKCH. When ACKCH is mapped according to the above mapping rule, when packet data is transmitted to subchannel # 1, ACKCH # 1 is selected. If the ACKCH is determined as described above, in step 504, ACK / NACK information is received.

An apparatus for transmitting ACK / NACK information according to the present invention proposed as described above will be described through the following embodiments.

<< first embodiment >>

In the first embodiment, a method of transmitting ACK / NACK by allocating different T-F bins with ACKCH. In this case, the packet data subchannel is mapped to the T-F bin of the ACKCH. Although a plurality of TF-bins can be used for one ACKCH, it is assumed in this embodiment that one T-F bin is used for convenience of description.

Packet data channel # 1 => ACKCH1 = TF (1,1)

Packet data channel # 2 => ACKCH2 = TF (1,2)

… .

Packet data channel #m => ACKCHm = TF (1, m)

In the example of the resource allocation, TF (i, j) means the position in the time-frequency domain that is actually transmitted.

7 is a diagram illustrating a structure of an ACK / NACK transmitter according to a first embodiment of the present invention.

When transmitting the ACKCH as described above, the ACKCH T-F bin determiner block 701 selects the ACKCH mapped to the subchannel to generate T-F information 707 of the corresponding ACKCH. To this end, the ACKCH T-F bin determiner 701 needs all the information of the entire ACKCH T-F bin 706, which may be predefined or set through higher signaling. In addition, the currently received packet data subchannel information 702 is required, which is received by the packet data receiving part. Since the T-F bin of the ACKCH required for ACK / NACK transmission is determined by the block, ACK / NACK transmission is possible. An ACK symbol is generated through the ACKCH generator 703 for ACK / NACK transmission, and is mapped to the T-F bin to be transmitted through the multiplexing block 704. In order to know which T-F bin is transmitted to the ACKCH, the block receives information through the ACKCH T-F bin determiner 701. Next, the response symbol mapped to the time-frequency resource is converted into a time domain signal through an IFFT 705 operation and transmitted to the packet data transmitter.

8 is a diagram illustrating a structure of an ACK / NACK receiver according to a first embodiment of the present invention.

8 shows almost the same modules as the ACK / NACK transmitter of FIG. 7, and since the packet data subchannel information is actually known, no special controller is required.

In response to the IFFT 705 of the ACK / NACK transmitter illustrated in FIG. 7, a time-domain signal including a received signal input to the FFT 802, that is, a response signal for packet data transmitted through a subchannel, is frequencyd. The signal is converted into an area signal and transmitted to the demultiplexer 803. The ACKCH TF bin determiner 806 uses the entire ACKCH TF bin 805 information and the transmitted packet data subchannel information 801 in the same way as the ACK / NACK transmitter. 807). Demultiplex the response symbol mapped to the TF bin 807 of the determined ACKCH in the demultiplexer 803, and decode the positive and negative response symbols output from the demultiplexer 803 in the ACKCH decoder 804 to ACK / Obtain NACK bit information 808.

<< Second Embodiment >>

The second embodiment implements a method of transmitting ACK / NACK by covering (or spreading) a plurality of T-F bins using different codes in order to obtain diversity gain in the time-frequency domain. When the code is used as described above, a plurality of ACKCHs are transmitted to a plurality of T-F bins, and when different channels are multiplexed, orthogonal codes are used to minimize interference of other channels. Thus, the second embodiment will be described using the Walsh code which is the most widely known orthogonal code.

The packet data subchannels and Walsh codes may be mapped as follows.

Packet data channel # 1 => ACKCH1 = Walsh (1)

Packet data channel # 2 => ACKCH2 = Walsh (2)

… .

Packet data channel #m => ACKCHm = Walsh (m)
As described above, the mapping relationship between the packet data channel and the Walsh code may be predefined or set by higher signaling.
For example, in a system in which 10 packet data channels are fixed in advance, it is possible to set 10 ACKCHs in advance. However, if the total number of use of the packet data channels is different for each base station, it is set by higher signaling. Accordingly, the number of ACKCH set is wrong. However, the basic mapping relationship must be mutually defined in advance or by some formula.

9 is a diagram illustrating the structure of an ACK / NACK transmitter according to a second preferred embodiment of the present invention.

When the ACKCH is set by the above-described method, since the Walsh code of the ACKCH to be transmitted must be selected first, the Walsh code determiner 905 block exists. In the block, Walsh code information 907 is determined based on the orthogonal code 906 and the packet data subchannel information 904 assigned to the response channel. For example, when packet data is transmitted from the packet data subchannel # 2, the Walsh code (2) is selected. Next, a module for transmitting ACK / NACK. First, a Walsh covering block for Walsh covering a response bit indicating whether an error of packet data received through the specific subchannel is performed using a Walsh code having an ACK / NACK bit determined. ) Exists. After performing the Walsh covering, mapping 903 to a subchannel for ACKCH based on subchannel information 908 and then multiplexing the subchannel with other subchannels 902 to IFFT 901. Through the operation, the signal is converted into a signal in the time domain and transmitted to the packet data transmitter. Here, the subchannel information 908 or the T-F bin mapping information 909 for the subchannel mapping process and the subcarrier mapping process may be predefined or set through higher signaling.

10 is a diagram illustrating the structure of an ACK / NACK receiver according to a second preferred embodiment of the present invention.

The time domain signal received from the acknowledgment transmitter for the packet data transmitted through the subchannel is converted into the frequency domain signal through the FFT 1014 operation, and inversed using the converted signal and the TF bin mapping information 1012. The demultiplexer outputs a plurality of subchannel signals by demultiplexing in the neutralizer 1013, and the demultiplexed subchannel signals are based on the subchannel information 1010 in a subchannel demapper 1011. A covered signal of a response channel corresponding to a channel is output, and the demultiplexed subchannel signals correspond to the subchannel based on the subchannel information 1010 in a subchannel demapper 1011. Outputs a Walsh covered signal of a response channel, the Walsh covered signal being AC based on the selected Walsh code 1007 in the Walsh decovering 1009 The Walsh decovering 1009 or despreading process of demodulating the K / NACK information is performed. Thereafter, when the Walsh decovering process 1009 is completed, an ACK / NACK bit is obtained. Here, the Walsh code 1007 has the same Walsh code determiner block 1005 as the transmitter of FIG. 9, and the block receives the packet data subchannel information 1004 and the Walsh code information 1008 to the subchannel. The Walsh code 1007 of the corresponding response channel is selected.

In the detailed description of the present invention, specific embodiments have been described, but various modifications may be made without departing from the scope of the present invention. Therefore, the scope of the present invention should not be limited to the described embodiments, but should be defined not only by the scope of the following claims, but also by those equivalent to the scope of the claims.

In the present invention operating as described in detail above, the effects obtained by the representative ones of the disclosed inventions will be briefly described as follows.

In the present invention, in allocating channels for transmitting an ACK / NACK response, the packet data is configured to be mapped to a transmission channel of packet data composed of time-frequency resources, and the ACK / NACK transmitter receives the packet data received at every transmission time. The present invention proposes a method of selecting and transmitting an ACK / NACK channel to be transmitted using information on a channel. As described above, since the transmission resources of the ACK / NACK channel are preset for each packet data transmission channel, it is not necessary to allocate an ACK / NACK channel exclusively for each terminal, so that even if the number of terminals increases in one base station, a small amount of resources is acknowledged. Since it is used for the / NACK channel, it is possible to save the resources to be allocated for the ACK / NACK channel.

Claims (16)

An apparatus for setting and transmitting a positive and negative response channel in a frequency division multiple access system, An acknowledgment generator for generating a response symbol indicating whether the packet data received through the subchannel has been normally received; Response channel for selecting a transmission resource of the response channel mapped to each subchannel and determining the time-frequency resource of the selected response channel by using the response channel time-frequency resource information and predefined mapping information of the packet data subchannel. A time-frequency resource determiner, A multiplexing block for mapping the generated response symbol to the determined time-frequency resource; And an inverse fast Fourier transform block receiving the response symbol mapped to the time-frequency resource from the multiplexing block, converting the response symbol into a time domain signal, and transmitting the positive and negative response channels. 2. The apparatus of claim 1, wherein the subchannel is composed of a plurality of time-frequency resources and is a minimum physical channel unit for packet data transmission. The method of claim 1, wherein the response channel time-frequency resource determiner checks the transmission subchannel of the received packet data every time the packet data is received and selects a transmission resource of the response channel based on the identified transmission subchannel. A device for setting and transmitting positive and negative response channels. An apparatus for receiving a response signal through a positive and negative response channel in a frequency division multiple access system, A receiving unit which receives a time domain signal including a response signal for packet data transmitted through a subchannel through the response channel; A fast Fourier transform block for converting the received response signal into a frequency domain signal; Response channel time-frequency for selecting a response channel corresponding to each sub-channel and determining time-frequency resources of the selected response channel by using response channel time-frequency resource information and predefined mapping information of the packet data subchannel. Resource determiner, A demultiplexing block for detecting a response symbol mapped to the determined time-frequency resource from the frequency domain signal output from the fast Fourier transform block; And a positive channel decoder configured to decode the output response symbol and output positive and negative response bit information. 5. The apparatus of claim 4, wherein the subchannel is configured of time-frequency resources and is a minimum physical channel unit for packet data transmission. 5. The method of claim 4, wherein the response channel time-frequency resource determiner checks the transmission subchannel of the transmitted packet data every packet data transmission and selects the received response channel based on the identified transmission subchannel. Receiving positive and negative channel signals. An apparatus for setting and transmitting a positive and negative response channel in a frequency division multiple access system, A Walsh code determiner that selects a response channel mapped to a specific subchannel and determines a Walsh code of the selected response channel by using mapping information of an orthogonal code assigned to the response channel and a packet data subchannel; A Walsh covering block for Walsh covering a response bit indicating whether or not an error of packet data received through the specific subchannel is performed using the determined Walsh code; A subchannel mapping unit for mapping the Walsh covered symbol to a subchannel for the selected response channel based on the mapping information; A multiplexing block for multiplexing the mapped subchannels with other subchannels; And an inverse fast Fourier transform block for converting the multiplexed information into a time-domain signal for transmission. 8. The apparatus of claim 7, wherein the subchannel is composed of a plurality of time-frequency resources and is a minimum physical channel unit for packet data transmission. An apparatus for receiving positive and negative channel signals in a frequency division multiple access system, A receiving unit which receives a time domain signal including a response signal for packet data transmitted using a subchannel through the response channel; A fast Fourier transform block for converting the received response signal into a frequency domain signal; A demultiplexing block for demultiplexing the frequency domain signal and outputting a plurality of subchannel signals; A subchannel demapping unit for performing subchannel demapping on a Walsh covered signal of a response channel corresponding to the subchannel based on subchannel information from the demultiplexed subchannel signal; A code determiner for receiving Walsh code information and packet data subchannel information and selecting the Walsh code of a response channel corresponding to the subchannel; And a Walsh decovering block configured to Walsh decover the Walsh covered signal with the selected code to output positive and negative response bits. 10. The apparatus of claim 9, wherein the subchannel is composed of a plurality of time-frequency resources and is a minimum physical channel unit for packet data transmission. In the frequency division multiple access system to set up and transmit a positive and negative response channel, Receiving packet data through a subchannel, Obtaining information of the subchannel included in the received packet data; Selecting a response channel corresponding to the information of the subchannel using mapping information for mapping the information of the predefined subchannel and the response channel; And generating a response signal of the received packet data and transmitting the response signal through the response channel. 12. The method of claim 11, wherein the subchannel includes a plurality of time-frequency resources and is a minimum physical channel unit for packet data transmission. 12. The method of claim 11, further comprising: checking a transmission subchannel of the received packet data every time the packet data is received and selecting a transmission resource of the response channel based on the identified transmission subchannel. And setting up and sending a negative response channel. A method for receiving a response signal through a positive and negative response channel in a frequency division multiple access system, Transmitting packet data through a subchannel; Obtaining information of the subchannel included in the transmitted packet data; Selecting a response channel corresponding to the information of the subchannel using mapping information for mapping the information of the predefined subchannel and the response channel; And receiving a response signal of the transmitted packet data through the response channel. 15. The method of claim 14, wherein the subchannel consists of a plurality of time-frequency resources and is a minimum physical channel unit for packet data transmission. 15. The method of claim 14, further comprising: checking a transmission subchannel of the transmitted packet data every time the packet data is transmitted and selecting a response channel received based on the identified transmission subchannel. A method of receiving a negative channel signal.

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