KR100788897B1 - Method for Transmitting of Acknowledgements to Hybrid ARQ Packets in OFDMA System and Transmitter/Receiver therefor - Google Patents

Abstract

The present invention relates to a method for transmitting a response (Acknowledgement) to the hybrid ARQ packet transmitted in the downlink in the OFDMA system in the uplink and a transmitting and receiving device for the same.

To this end, the present invention is divided into a plurality of code axes based on different scrambling codes, and includes an ACK channel and a plurality of ACK channels multiplexed with a code axis on which a response signal for a successful reception or error of a downlink HARQ packet is mounted. An ACK channel region; HARQ packet using a feedback channel region carrying feedback information, which is channel quality information that can be transmitted together when transmitting a response to the HARQ packet to the base station, and a data region including data transmitted from the mobile terminal to the base station Provided are a method for transmitting a response signal to a mobile terminal and a base station therefor.

According to the present invention, a response signal can be transmitted using all radio resources, and when the number of mobile terminals is small, it is possible to expect an effect of improving reliability of an uplink signal due to a reduction in interference generated. Further, by predicting the number of mobile terminals not to transmit a response in advance, the mobile terminal may be additionally accommodated, so that a statistical multiplexing gain effect can be expected.

OFDMA, Hybrid ARQ, HARQ, Response Signal, ARQ Response, Uplink Frame

Description

Method for Transmitting of Acknowledgements to Hybrid ARQ Packets in OFDMA System and Transmitter / Receiver therefor}

1 is a diagram schematically illustrating an OFDMA system for transmitting a response to a HARQ packet;

2 is a view schematically showing an uplink frame structure of a typical OFDMA system;

3 is a diagram schematically illustrating a structure of an uplink frame in which an ACK channel region is divided into a plurality of ACK channels based on a code axis, according to a first embodiment of the present invention;

FIG. 4 schematically illustrates a structure of an uplink frame in which an ACK channel region and a feedback channel region exist in the same region and are divided into a plurality of ACK channel regions and a feedback channel region based on a code axis according to the second embodiment of the present invention. Drawing,

5 is a block diagram schematically illustrating an internal configuration of a mobile terminal for transmitting a response to a HARQ packet transmitted from a base station in an OFDMA system according to an embodiment of the present invention;

6 is a block diagram schematically illustrating an internal configuration of a base station for transmitting a HARQ packet to a mobile terminal through a downlink frame and receiving a response transmitted from the mobile terminal through an uplink frame according to an embodiment of the present invention. to be.

The present invention relates to a method for transmitting a response to a hybrid ARQ packet in an OFDMA system, and a transmitting and receiving device therefor. More specifically, in the OFDMA system, a response to packet reception (ACK) through uplink with respect to hybrid ARQ (HARQ) packets received by the mobile station through the downlink to the base station (HARQ) The present invention relates to a method for transmitting an acknowledgment and a transmitting and receiving device therefor.

In the 4th generation mobile communication system requiring large data transmission such as WLAN, wireless broadcasting, and DMB, Orthogonal Frequency Division Multiplex Access (OFDMA) for transmitting broadband high speed data is referred to as 'OFDMA'. ) Method is used.

In a mobile communication system using an OFDMA scheme (hereinafter, referred to as an "OFDMA system"), a base station transmits a data packet to a mobile terminal is called downlink or downlink, and the data packet transmitted from the base station is called a downlink packet. do.

When the downlink packet is transmitted from the base station to the mobile terminal, the mobile terminal should check whether the received downlink packet is an error. If an error is detected, the base station requests retransmission of the downlink packet. This method is called an automatic retransmission request and is called an 'ARQ (Automatic Repeat reQuest)'.

That is, the base station transmits a downlink packet to the mobile terminal by applying an ARQ method for requesting a response to the error. As such, the downlink packet to which the ARQ scheme transmitted from the base station to the mobile terminal is applied is called an 'ARQ packet'.

Recently, in order to improve throughput in an OFDMA system, HARQ technology, which controls errors by combining retransmission requests based on ARQ and forward error correction requests made in a physical layer, has been introduced. . HARQ is a slight variation of the existing ARQ, and shows good performance in wireless networks. The downlink packet to which the HARQ scheme transmitted from the base station to the mobile terminal is applied is called a 'HARQ packet'.

1 is a diagram schematically illustrating an OFDMA system for transmitting a response to a HARQ packet.

In an OFDMA system, a base station transmits downlink packets to a plurality of mobile terminals located in a cell in charge. At this time, the base station of the OFDMA system to which the HARQ scheme is applied transmits the HARQ packet as a downlink packet.

In addition, the mobile terminal receiving the transmitted HARQ packet transmits a response indicating whether the HARQ packet is in error through the uplink. Typically, the mobile station transmits an ACK response indicating that there is no error to the base station when there is no error in the received HARQ packet, and transmits a NACK response when there is an error in the HARQ packet. In addition, a NACK signal indicating that an error has occurred only when an error is found from an HARQ packet received by the mobile terminal may be set to be transmitted to the base station, or may be set to transmit an ACK signal to the base station only when reception is successful without an error. .

The base station determines that an error has occurred in the transmitted HARQ packet and retransmits the HARQ packet when a response indicating that there is no error is transmitted from the mobile terminal or when a response indicating that an error has occurred is transmitted.

Here, the response indicating that there is no error transmitted from the mobile terminal to the base station is called 'ACK', the response indicating that an error is called 'NACK', and the uplink response transmitting a signal meaning ACK or NACK. The channel is called an ACK channel.

2 is a diagram schematically showing an uplink frame structure of a typical OFDMA system.

In an OFDMA system, an uplink frame structure transmitted by a mobile station to a base station includes a control region 110 for transmitting a response to whether an error occurs and channel quality information, and a data region including data transmitted from the mobile terminal to the base station. 120). The control region 110 includes a feedback channel region 112 for transmitting channel quality information including channel gain, channel interference, and the like, and an ACK channel region 114 for transmitting a response of 'ACK' or 'NACK'. And ranging region 116. Here, the control region 110 and the data region 120 may be separated based on a time symbol axis, or may be separated based on a frequency axis, that is, a subcarrier axis. In FIG. 2, the control region 110 and the data region 120 are separated based on a time symbol axis, and the control region 110 is a feedback channel region 112 and an ACK channel region based on a subcarrier axis. 114 and ranging region 116.

Here, the ACK channel region 114 is composed of a plurality of ACK channels 1140 and 1150 used by a plurality of mobile terminals located in a cell to transmit respective ACK or NACK signals.

When the base station transmits an HARQ packet, the base station transmits the location information of the ACK channels 1140 and 1150 allocated to each mobile terminal among the plurality of ACK channels.

After receiving the HARQ packet including the location information of the ACK channel 1140, 1150, the mobile terminal determines whether an error has occurred for the received HARQ packet, and then determines whether an ACK or NACK is assigned to the ACK channel 1140, 1150 allocated thereto. The response signal is mounted and transmitted in an uplink frame.

In this case, in an OFDMA system, typically, only one response signal of ACK or NACK may be mounted and transmitted for efficient use of resources. When the OFDMA system is configured to transmit only the response signal of the ACK, the ACK channel region 114 of the uplink frame is empty because the ACK channel 1140 is loaded with the ACK from the mobile terminal and the ACK is not loaded from the mobile terminal. ACK channel 1150.

The mobile terminal transmits the ACK channel region 114 including the ACK channel 1140 loaded with the ACK and the empty ACK channel 1150 through the uplink frame, thereby responding to the HARQ signal of the base station.

In the OFDMA system transmitting the uplink frame through the above method, the ACK channels 1140 and 1150 should be allocated to all mobile terminals located in the cell in order to transmit a response to the HARQ signal. However, in actually performing communication between the base station and the mobile terminal, the mobile terminal that receives the HARQ packet having an error does not respond to the ACK signal, so that an empty ACK channel 1150 is generated, and thus an empty ACK channel ( There is a problem that the radio resource allocated to 1150 is wasted.

In addition, although the base station estimates the number of mobile terminals in the cell and divides the ACK channel in advance, when the number of mobile terminals located in the cell is smaller than the number of divided ACK channels, some ACK channels are not used for ACK transmission and become empty. This wastes radio resources.

On the contrary, when a large number of mobile terminals are located in a cell in charge of a base station, and the HARQ packets are transmitted to more mobile terminals than a preset number of ACK channels, some mobile terminals transmit a response to the received HARQ packet. Unexpected problems also arise.

Accordingly, in the conventional OFDMA system, in order to secure a sufficient number of ACK channels in advance, many radio resources are allocated to the ACK channel region. However, as many radio resources are allocated to the ACK channel region, the feedback channel region 112 or the data region 120 may be reduced.

In order to solve the above problems, the present invention divides the ACK channel region into a code axis in an uplink of an OFDMA system, and a plurality of mobile terminals respectively respond to HARQ packets to a plurality of ACK channels separated by a code axis. When mounted, this method provides a response transmission method using all radio resources and a transmitting / receiving device therefor by scrambling and transmitting the same.

In order to achieve the above technical problem, a method for transmitting a response to a HARQ packet according to a first embodiment of the present invention, the method of transmitting a response signal for a HARQ packet by a mobile terminal of the OFDMA system, (a) received from the base station Generating a response signal for the HARQ packet; (b) identifying, via the received HARQ packet, an ACK channel assigned to the mobile terminal, wherein the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; (c) mounting a response signal on the identified ACK channel; And (d) transmitting an ACK channel equipped with a response signal to the base station using uplink.

In addition, HARQ packet transmission method according to a second embodiment of the present invention, the HARQ packet transmission method for the base station of the OFDMA system receives a response signal from a plurality of mobile terminals located in the cell, (a) a plurality of cells located in the cell Generating a HARQ packet to be transmitted to the mobile terminal of the; (b) assigning each of the plurality of mobile terminals an ACK channel, where the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; And (c) transmitting the location information of the ACK channel to the plurality of mobile terminals located in the cell together with the HARQ packet.

In addition, as a mobile terminal according to a third embodiment of the present invention, in a mobile terminal that transmits a response signal to a HARQ packet received from a base station in an OFDMA system, error checking for checking whether an HARQ packet transmitted from the base station is in error module; An ACK response generating module for generating a response signal to be transmitted to the base station according to the error checking result by the error checking module; Acknowledge the ACK channel allocated to the mobile terminal transmitted with the HARQ packet, where the ACK channel is one of a plurality of ACK channels in which the ACK channel region is divided on the basis of the code axis, and receives the response signal generated by the ACK response generation module. An ACK channel positioning module mounted on the ACK channel; And an uplink packet transmission module for transmitting the ACK channel on which the response signal is mounted to the base station through an uplink frame.

In addition, as a base station of an OFDMA system according to a fourth embodiment of the present invention, a base station that performs HARQ packet retransmission through a response signal of a mobile terminal transmitted through an uplink frame in an OFDMA system, includes: HARQ packet generation module for generating a HARQ packet to be transmitted to the terminal; An ACK channel allocation module for allocating an ACK channel to the plurality of mobile terminals, wherein the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; A downlink packet transmission module for transmitting location information of an ACK channel allocated to each mobile terminal to a plurality of mobile terminals located in a cell together with HARQ packets; An uplink packet receiving module configured to receive a response signal indicating whether an error of an HARQ packet transmitted from a mobile terminal occurs through uplink; And an acknowledgment module for confirming whether an error of the HARQ packet occurs through the response signal and requesting retransmission of the HARQ packet when an error of the HARQ packet is confirmed.

In addition, as a mobile terminal according to a fifth embodiment of the present invention, in a mobile terminal transmitting a response signal for a HARQ packet received from a base station in an OFDMA system, an ACK channel divided into a plurality of channels based on a code axis, wherein the ACK channel is used. A channel is an ACK channel region including a channel on which a response signal for an error of an HARQ packet transmitted by a base station is mounted; A feedback channel region carrying feedback information enclosed when transmitting a response to the HARQ packet to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And a response signal for the HARQ packet to the base station using an uplink frame including a data region including data transmitted from the mobile terminal to the base station.

In addition, as a base station of an OFDM system according to a sixth embodiment of the present invention, a base station that performs HARQ packet retransmission through a response signal of a mobile station transmitted through an uplink frame in an OFDMA system, based on a code axis, An ACK channel region including a divided ACK channel, wherein the ACK channel is a region in which a response signal for an error of an HARQ packet delivered by a base station is mounted; A feedback channel region carrying feedback information enclosed when transmitting a response to the HARQ packet to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And a response signal for an HARQ packet transmitted from the mobile terminal using an uplink frame including a data region including data transmitted from the mobile terminal to the base station.

In addition, as an uplink frame according to the seventh embodiment of the present invention, in an uplink frame in which a mobile station transmits a response signal for a HARQ packet transmitted from a base station in an OFDMA system, an ACK divided into a plurality of codes based on a code axis A ACK channel region comprising a channel, where the ACK channel is a channel on which a response signal for an error of an HARQ packet delivered by a base station is mounted; A feedback channel region carrying feedback information enclosed when transmitting a response to the HARQ packet to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And a data area including data transmitted from the mobile terminal to the base station.

DETAILED DESCRIPTION Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art may easily implement the present invention. As those skilled in the art would realize, the described embodiments may be modified in various different ways, all without departing from the spirit or scope of the present invention. In the drawings, parts irrelevant to the description are omitted in order to clearly describe the present invention, and like reference numerals designate like parts throughout the specification.

In addition, when a part is said to "include" a certain component, this means that it may further include other components, except to exclude other components unless otherwise stated.

In addition, the term module described herein refers to a unit for processing a specific function or operation, which may be implemented in hardware or software, or a combination of hardware and software.

3 is a diagram schematically illustrating a structure of an uplink frame in which an ACK channel region is divided into a plurality of ACK channels based on a code axis according to a first embodiment of the present invention.

In the structure of the uplink frame according to the present invention, the control region 210 and the data region 220 are separated based on the subcarrier axis, and the control region 210 is based on the time symbol axis and the feedback channel region 212 and the ACK channel. Area 214 is separated.

Here, the ACK channel region 214 for transmitting a response to the HARQ channel received from the base station is divided into a plurality of ACK channels based on the code axis. In addition, responses transmitted by each mobile terminal are mounted on a plurality of ACK channels separated based on a code axis.

The mobile terminal receiving the HARQ packet through the downlink includes a mobile station such as a number of a downlink frame, a located cell or sector number, a mobile identification number (MIN), or an electronic serial number (ESN). The response bits of the ACK or the NACK are generated using the ID, and the like, the spreading scrambled bits of the generated ACK or NACK are transmitted to the allocated ACK channel.

3 illustrates an ACK channel region 214 divided into N ACK channels based on a code axis in accordance with the present invention. The ACK channel located at the bottom is the first ACK channel 2142 loaded with the response bits of the ACK or NACK transmitted from the first mobile terminal, and the ACK channel located at the top of the first ACK channel 2142 based on the code axis is The second ACK channel 2144 is loaded with a response bit of the ACK or NACK transmitted from the second mobile terminal. In this way, N ACKs or NACK response bits transmitted from the mobile terminals are mounted in the ACK channel set in each mobile terminal.

In FIG. 3, an ACK response bit is mounted on the first ACK channel 2142 and the third ACK channel 2146 of the N ACK channels, and a NACK response is provided on the second ACK channel 2144 and the N-th ACK channel 2148. The structure of an uplink frame with bits is shown.

As described above, in an uplink frame including a plurality of ACK channels based on a code axis, an ACK channel loaded with response bits of an ACK or NACK transmitted from one mobile terminal may use radio resources of other ACK channels, time symbols, and subcarriers. All will be shared. That is, when the first ACK channel 2142 to the N-th ACK channel 2148 are scrambled with the code axis, an integrated ACK channel (hereinafter referred to as an integrated ACK channel) based on the subcarrier axis and the time symbol axis ( 2140 is generated. As shown in FIG. 3, the integrated ACK channel 2140 in which a plurality of ACK channels are scrambled uses all radio resources of the subcarrier axis and the time symbol axis, and is transmitted to the base station through the ACK channel region 214.

As such, in the structure of an uplink frame according to an embodiment of the present invention, efficiency may be improved as all radio resources of the ACK channel are used.

In addition, when the number N of mobile terminals to transmit a response to the HARQ packet in an uplink frame according to the present invention is small, interference occurring between each ACK channel is reduced, and thus an ACK response or The reliability of the NACK response is increased.

In the present invention, although the mobile terminal essentially generates one response bit among the response bits of the ACK or the NACK and may be configured to transmit the generated response bit on the ACK channel, the mobile resource can be efficiently used. And to improve the reliability of the response according to the interference reduction, it is preferable to set to transmit only one response of the response bits of the ACK or NACK to the base station.

That is, when the mobile terminal is configured to transmit only an ACK response to the HARQ packet, only the mobile terminal which has confirmed that there is no error in the HARQ packet generates an ACK response bit and assigns the generated ACK response bit to each mobile terminal. It is mounted on the ACK channel and transmitted to the base station. On the other hand, the mobile terminal which checks an error of the HARQ packet and generates a response bit of the NACK generates an empty ACK channel by not mounting the generated NACK in the ACK channel. Here, the mobile terminal which has confirmed the error of the HARQ packet may be configured not to generate the NACK signal.

Conversely, in the practice of the present invention, only the mobile terminal which has confirmed the error of the HARQ packet may be configured to generate a NACK response signal and mount the generated NACK response signal on the ACK channel and transmit the same to the base station. At this time, the base station determines that there was no error in the HARQ packet transmitted to the mobile terminal allocated to the ACK channel in which the NACK response was not transmitted.

As such, when each mobile terminal is configured to transmit only one response of ACK or NACK, the number of mobile terminals not to transmit a response may be predicted in advance, and the mobile terminal may be configured to accommodate more mobile terminals than the number of ACK channels. As a result, the radio resource can be used more efficiently.

That is, when it is predicted that M mobile terminals among the N mobile terminals will not transmit a response, the mobile station can set N + M mobile terminals through an uplink frame. As described above, statistical multiplexing gain can be obtained by accommodating a larger number (N + M) of mobile terminals than the number N of conventionally acceptable mobile terminals using the same radio resource.

On the other hand, the mobile terminal should transmit the response of the ACK or NACK mounted in the ACK channel region through the uplink frame to the base station and at the same time load the channel quality information in the feedback channel to the base station.

The conventional feedback channel region 112 includes a respective feedback channel allocated to a plurality of mobile terminals in the same manner as the ACK channel region 114, and has a structure in which feedback information of each mobile terminal is mounted in each feedback channel. .

In the structure of the uplink frame according to the first embodiment of the present invention, the ACK channel region 214 of the control region 210 is divided into a plurality of ACK channels. However, the feedback channel region 212 located in the control region 210 is conventionally divided into a plurality of feedback channels and assigned to each mobile terminal, whereby the feedback information is mounted on the feedback channel allocated by each mobile terminal to the base station. The transmission method is used.

That is, as the feedback channel region 212 is divided into a plurality of feedback channels like the conventional ACK channel region 114 and allocated to each mobile terminal, radio resources may be wasted. Accordingly, in order to use the radio resource more efficiently, a method of separating the feedback channel region 212 into a plurality of feedback channels based on a code axis, such as the ACK channel region 214 according to the present invention, may be used.

FIG. 4 schematically illustrates a structure of an uplink frame in which an ACK channel region and a feedback channel region exist in the same region and are divided into a plurality of ACK channel regions and a feedback channel region based on a code axis according to the second embodiment of the present invention. It is a figure shown.

In the uplink frame according to the second embodiment of the present invention, the control region 310 and the data region 320 are separated based on the subcarrier axis. The control area 310 is composed of a plurality of mobile terminal control channels 3110, 3120, 3130, and 3140. Here, FIG. 4 illustrates an uplink frame accommodating N mobile terminals. Accordingly, the uplink frame includes N mobile terminals from the first mobile terminal control channel 3110 to the Nth mobile terminal control channel 3140. Control channel is included. Each mobile terminal control channel includes a first feedback channel, a second feedback channel, and an ACK channel.

In the following description, the first mobile terminal control channel 3110 including the first feedback channel 3112, the second feedback channel 3114, and the ACK channel 3116 of the first mobile terminal will be described. do.

The ACK channel 3116 is a portion in which an ACK response or NACK response signal is mounted for the HARQ packet, and the first feedback channel 3112 and the second feedback channel 3114 are transmitted to the base station for the received HARQ packet by the mobile terminal. This is the portion where the feedback information is mounted.

That is, each mobile terminal includes channel quality information such as channel gain and channel interference through the first feedback channel 3112 and the second feedback channel 3114 at a predetermined period or any time point as necessary. The feedback information is transmitted to the base station, and the ACK response or the NACK response to the HARQ packet received through the downlink is transmitted through the ACK channel region 3116.

At this time, the first feedback channel 3112 and the second feedback channel 3114 including the feedback information transmitted through the uplink and the ACK channel 3116 including the ACK or NACK are spread by a unique scrambling code, respectively. do.

In the first feedback channel 3112 and the second feedback channel 3114, a feedback bit to be transmitted is transmitted using a number of downlink frames, a located cell or sector number, an ID of a mobile terminal, and a feedback channel ID for distinguishing from another channel. Diffusion scrambling.

The ACK channel 3116 spreads and scrambles the response bit to be transmitted using the number of the downlink frame, the located cell or sector number, the ID of the mobile terminal, and the ACK channel ID for distinguishing it from other channels. In this case, in order to spread scramble the ACK, a representative ID of a radio resource used for HARQ packet transmission may be used instead of the ID of the mobile terminal.

In the uplink frame illustrated in FIG. 4, a response signal and feedback information about an HARQ packet are transmitted through a first mobile terminal control channel 3110 and a third mobile terminal control channel 3130. In addition, the second mobile terminal control channel 3120 and the N-th mobile terminal control channel 3140 do not have a response signal and feedback information for the HARQ packet.

Alternatively, the ACK response and feedback information are transmitted through the first mobile terminal control channel 3110 and the third mobile terminal control channel 3130, and the second mobile terminal control channel 3120 and the N-th mobile terminal control. The NACK response and feedback information may be transmitted through the channel 3140.

However, in order to efficiently use radio resources, only one response signal of an ACK response or a NACK response is transmitted, and only feedback information of the mobile terminal to which the response signal is transmitted is the first feedback channel 3112 and the second feedback channel 3114. It is preferable to set to transmit on the mount.

When setting only one response signal as described above, as described with reference to FIG. 3, by predicting the number of mobile terminals that do not transmit a response, a larger number of mobile terminals can be accommodated than a preset mobile terminal. Statistical multiplexing gains can be obtained.

Here, in the OFDMA system, as the amount of feedback information to be transmitted through the uplink frame is large, the feedback channel is divided into the first feedback channel 3112 and the second feedback channel 3114, but in actual implementation, The first feedback channel 3112 and the second feedback channel 3114 may be integrated into one feedback channel.

5 is a block diagram schematically illustrating an internal configuration of a mobile terminal for transmitting a response to a HARQ packet transmitted from a base station in an OFDMA system according to an embodiment of the present invention.

According to the first and second embodiments of the present invention mentioned above, a mobile terminal for transmitting a response to a HARQ packet includes a downlink packet receiving module 4210 for receiving a HARQ packet transmitted from a base station. The error checking module 4310 to check whether the HARQ packet is error, the ACK response generating module 4320 to generate a response signal to be transmitted to the base station when the error checking module 4310 checks whether the HARQ packet is error, to the base station A feedback information generation module 4340 for generating feedback information to be enclosed when transmitting a response signal, an ACK channel positioning module 4330 for mounting a response signal generated by checking a position of an ACK channel included in a received HARQ packet, Feedback channel positioning module 4350 for mounting the feedback signal generated by checking the position of the feedback channel included in the received HARQ packet and the generated feedback information and response An uplink packet transmission module 4220 is included in the uplink frame and transmitted to the base station.

Here, when it is confirmed by the error checking module 4310 that there is no error of the HARQ packet, the ACK response generating module 4320 generates an ACK signal to be transmitted to the base station. If it is confirmed by the error checking module 4310 that an error of the HARQ packet has occurred, the ACK response generating module 4320 generates a NACK signal to be transmitted to the base station.

Here, if an error occurs in the HARQ packet transmitted in the OFDMA system, the base station does not transmit a response signal, and if the base station does not transmit a response signal for a predetermined time, it is determined that an error has occurred and retransmits the HARQ packet. In this case, when it is confirmed by the error checking module 4310 that an error of the HARQ packet has occurred, the ACK response generating module 4320 may not generate a response signal to be transmitted to the base station.

The uplink packet transmission module 4220 mounts the generated response signal on the ACK channel identified by the ACK channel positioning module 4330 and mounts feedback information on the feedback channel identified by the feedback channel positioning module 4350. Then, the base station transmits the uplink frame to the base station.

6 is a block diagram schematically illustrating an internal configuration of a base station for transmitting a HARQ packet to a mobile terminal through a downlink packet and receiving a response transmitted from the mobile terminal through an uplink frame according to an embodiment of the present invention. .

According to the first and second embodiments of the present invention described above, a base station for transmitting a HARQ packet and receiving a response signal from a mobile terminal includes a HARQ packet generation module for generating a HARQ packet to be transmitted to a mobile terminal. 5310), a terminal information checking module 5320 for identifying a mobile terminal to which the HARQ packet is to be transmitted; an ACK channel allocation module for allocating position information of an ACK channel for mounting a response signal to each mobile terminal when transmitting a response of the mobile terminal; In operation 5330, a feedback channel allocation module 5340 and a HARQ packet generation module 5310 allocate the location information of the feedback channel to be loaded with feedback information to be transmitted with the response signal to each mobile terminal when the response signal is transmitted from the mobile terminal. Downlink packet for transmitting the HARQ packet, the ACK channel position information and the feedback channel position information generated through the downlink to the mobile terminal through the downlink A transmission module 5210, an uplink packet receiving module 5220 that receives an uplink packet including a response signal and feedback information transmitted through an uplink frame from a mobile terminal, and extracts a response signal from an uplink packet to confirm An ACK response confirmation module 5350 and a feedback information confirmation module 5260 extracting and confirming feedback information from the uplink packet.

The embodiments of the present invention described above are not implemented only through the apparatus and the method, but may be implemented through a program for realizing a function corresponding to the configuration of the embodiment of the present invention or a recording medium on which the program is recorded. Implementation may be easily implemented by those skilled in the art from the description of the above-described embodiments.

Although the embodiments of the present invention have been described in detail above, the scope of the present invention is not limited thereto, and various modifications and improvements of those skilled in the art using the basic concepts of the present invention defined in the following claims are also provided. It belongs to the scope of rights.

As described above, according to the present invention, the ACK channel region, which is conventionally divided into a plurality of frames on the basis of the subcarrier axis and stores the response signal of each mobile terminal, is divided into a plurality of ACK channels based on the code axis. As the response signal of each mobile terminal is stored in the divided ACK channel and then scrambled and transmitted, an efficiency improvement effect of transmitting an uplink signal using all radio resources can be expected.

In addition, when the number of mobile terminals managed by the base station is small, there is little waste of radio resources, and the interference generated between the respective ACK channels is reduced, thereby improving the reliability of the uplink signal.

In addition, by predicting the number of mobile terminals not to transmit a response in advance and additionally accommodating the corresponding mobile terminals, it is possible to expect a statistical multiplexing gain effect to more efficiently use radio resources.

Claims (22)

A method for transmitting a response signal for a hybrid automatic repeat request (HARQ) packet by a mobile terminal of an OFDMA system, (a) generating a response signal for the HARQ packet received from the base station; (b) identifying, via the received HARQ packet, an ACK channel allocated to the mobile terminal, wherein the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; (c) mounting the response signal on the identified ACK channel; And (d) transmitting an ACK channel equipped with the response signal to the base station using uplink; Response transmission method for a HARQ packet comprising a. The method of claim 1, Step (d) is, When transmitting the response signal to the base station, the response information for the HARQ packet is transmitted together with feedback information, wherein the feedback information is channel quality information including channel gain and channel interference. Way. The method of claim 2, And transmitting feedback information of the mobile terminal in a feedback channel allocated to the mobile terminal among a plurality of feedback channels in which the feedback channel region is divided based on a code axis. The method of claim 3, Step (d) is, (d1) confirming a feedback channel allocated to the mobile terminal through the received HARQ packet; (d2) mounting feedback information of the mobile terminal on the identified feedback channel; And (d3) transmitting the feedback information mounted in the feedback channel when transmitting the response signal to the base station; Response transmission method for a HARQ packet, characterized in that it further comprises. The method of claim 1, Step (a) is, (a1) checking whether the HARQ packet is in error; And (a2) generating an ACK signal if no error is found as a result of the error checking, and generating an NACK signal or generating an empty response signal if an error is found; Response transmission method for a HARQ packet, characterized in that it further comprises. The method of claim 5, If an error is found in the HARQ packet received by the mobile terminal and an empty response signal is generated, step (c) may include: A method of transmitting a response to a HARQ packet, characterized in that a response signal transmitted from another mobile terminal is mounted on the ACK channel allocated to the mobile terminal and transmitted to the base station. A method for transmitting a hybrid automatic repeat request (HARQ) packet for receiving a response signal from a plurality of mobile terminals located in a cell by a base station of an OFDMA system, (a) generating a HARQ packet to be transmitted to a plurality of mobile terminals located in the cell; (b) assigning each of the plurality of mobile terminals an ACK channel, wherein the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; And (c) transmitting the location information of the ACK channel to a plurality of mobile terminals located in the cell together with the HARQ packet; HARQ packet transmission method comprising a. The method of claim 7, wherein After step (c), (d) checking response signals of the plurality of mobile terminals through a plurality of ACK channels transmitted through uplink; (e) if a response signal indicating that an error has occurred in the HARQ packet is confirmed, retransmitting the HARQ packet to a mobile terminal of an ACK channel including a response signal indicating that an error has occurred in the HARQ packet. HARQ packet transmission method characterized in that it further comprises. The method of claim 8, Step (d) is, Feedback information of a mobile terminal transmitting the response signal through a feedback channel region when receiving the response signal from the mobile terminal through the uplink, wherein the feedback information includes channel quality information including channel gain and channel interference. HARQ packet transmission method characterized in that it receives together. The method of claim 9, And receiving feedback information of the mobile terminal through a feedback channel allocated to the mobile terminal among a plurality of feedback channels in which the feedback channel is divided based on a code axis. The method of claim 8, Step (d) is, When an ACK signal is transmitted from the mobile terminal through the ACK channel, it is determined that no error has occurred in the HARQ packet transmitted to the mobile terminal. If a response signal indicating that there is no error is not transmitted from the mobile terminal for a predetermined time or when a NACK signal is transmitted from the mobile terminal through the ACK channel, it is determined that an error has occurred in the HARQ packet. HARQ packet transmission method. A mobile terminal for transmitting a response signal for a hybrid automatic repeat request (HARQ) packet received from a base station in an OFDMA system, An error checking module for checking an error of an HARQ packet transmitted from the base station; An ACK response generation module for generating a response signal to be transmitted to the base station according to an error check result by the error checking module; An ACK channel allocated to the mobile terminal transmitted with the HARQ packet, wherein the ACK channel is one of a plurality of ACK channels in which an ACK channel region is divided based on a code axis; and generated by the ACK response generation module. An ACK channel positioning module configured to mount a response signal on the ACK channel; And Uplink packet transmission module for transmitting the ACK channel loaded with the response signal to the base station through an uplink frame Mobile terminal comprising a. The method of claim 12, A feedback information generating module for generating feedback information to be enclosed when transmitting the response signal to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And A feedback channel region positioning module for identifying a feedback channel allocated to the mobile terminal and mounting the feedback information generated in the feedback information generating module to the feedback channel; Mobile terminal, characterized in that it further comprises. The method of claim 13, The uplink packet transmission module, And an ACK channel including the response signal and a feedback channel including the feedback information to the base station through the uplink frame. The method of claim 12, The ACK response generation module, When it is confirmed that an error has occurred in the HARQ packet, the NACK signal is not generated or no response signal is generated. When the error checking module determines that there is no error in the HARQ packet, an ACK signal is generated. Mobile terminal. A base station for performing HARQ packet retransmission through a response signal of a mobile terminal transmitted through an uplink frame in an OFDMA system, A HARQ packet generation module for generating HARQ packets to be transmitted to a plurality of mobile terminals located in a cell; An ACK channel allocation module for allocating an ACK channel to the plurality of mobile terminals, wherein the ACK channel is one of a plurality of ACK channels whose ACK channel region is divided based on a code axis; A downlink packet transmission module for transmitting location information of an ACK channel allocated to each mobile terminal together with the HARQ packet to a plurality of mobile terminals located in the cell; An uplink packet receiving module configured to receive a response signal indicating whether an error occurs in the HARQ packet transmitted from the mobile terminal through uplink; And The acknowledgment module confirms whether an error of the HARQ packet occurs through the response signal, and if the error of the HARQ packet is confirmed, requesting retransmission of the HARQ packet. Base station of the OFDMA system comprising a. The method of claim 16, A feedback information verification module for identifying feedback information received with the response signal, wherein the feedback information is channel quality information including channel gain and channel interference; And Feedback channel assignment module for allocating position information of a feedback channel to mount the feedback information to each mobile terminal The base station of the OFDMA system, characterized in that it further comprises. A mobile terminal for transmitting a response signal for a hybrid automatic repeat request (HARQ) packet received from a base station in an OFDMA system, An ACK channel region including a plurality of divided ACK channels based on a code axis, wherein the ACK channel is a channel on which a response signal for an error of an HARQ packet transmitted by the base station is mounted; A feedback channel region carrying feedback information enclosed when transmitting a response to the HARQ packet to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And A data area including data transmitted from the mobile terminal to the base station A mobile terminal for transmitting a response signal for the HARQ packet to the base station using an uplink frame comprising a. The method of claim 18, The feedback channel region, A feedback channel divided into a plurality of reference channels based on a code axis, wherein the feedback channel is a region in which feedback information identified in the mobile terminal is loaded; and a response signal for the HARQ packet using an uplink frame. A mobile terminal for transmitting to the base station. The method of claim 18, The ACK channel region, the feedback channel region and the data region are separated based on a time symbol axis and a subcarrier axis based on a mobile station for transmitting a response signal for the HARQ packet to the base station using an uplink frame. . A base station for performing HARQ packet retransmission through a response signal of a mobile terminal transmitted through an uplink frame in an OFDMA system, An ACK channel region including a plurality of ACK channels divided based on a code axis, wherein the ACK channel is a region in which a response signal for an error of an HARQ packet transmitted by the base station is mounted; A feedback channel region carrying feedback information enclosed when transmitting a response to the HARQ packet to the base station, wherein the feedback information is channel quality information including channel gain and channel interference; And A data area including data transmitted from the mobile terminal to the base station The base station of the OFDMA system for receiving a response signal for the HARQ packet transmitted from the mobile terminal using an uplink frame comprising a. delete

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