KR20100087675A - Apparatus and method for transmitting information through uplink control channel in communication system based on ofdma - Google Patents

Abstract

PURPOSE: An apparatus and a method for transmitting information through uplink control channel in communication system based on OFDMA are provided to minimize the deterioration of reception performance of an upper link control channel. CONSTITUTION: An uplink control information is encoded into a predetermined bit string. A signal stream corresponding to a predetermined bit string is generated. The signal stream is circular rotated according to a predetermined rule. The circular rotated signal stream is adjusted to be matched with the length of uneven subframe.

Description

Apparatus and method for transmitting information through uplink control channel in orthogonal frequency division multiple access communication system {APPARATUS AND METHOD FOR TRANSMITTING INFORMATION THROUGH UPLINK CONTROL CHANNEL IN COMMUNICATION SYSTEM BASED ON OFDMA}

The present invention relates to an apparatus and method for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system, and more particularly to a method and apparatus for transmitting uplink control information through an irregular uplink subframe. It is about.

In the communication system based on Orthogonal Frequency Division Multiple Access (hereinafter referred to as "OFDMA"), the frame structure is shown in FIG.

Referring to FIG. 1, the frame 100 has a length of 5 ms and is divided into a downlink frame 110 and an uplink frame 120. The TTG (Tx / Rx Transition Gap) 115 is an interval between the downlink frame 110 and the uplink frame 120, during which the base station transmits from the transmit mode to the receive mode, and the terminals transmit from the receive mode. Perform the transition to mode. The RTG (Rx / Tx Transition Gap) 125 is an interval between the uplink frame 120 and a subsequent downlink frame, during which the base station is in the receive mode to the transmit mode and the terminals are in the transmit mode to the receive mode. Perform the transfer of.

The downlink frame 110 includes a plurality of subframes 130 and transmits downlink data and control information. The uplink frame 120 is also composed of a plurality of subframes and transmits uplink data and control information.

The uplink control information may include uplink fast feedback information, hybrid automatic repeat request (ARQ) feedback (or ACK channel), and a bandwidth request indicator for requesting uplink resources. Information).

The uplink fast feedback information includes a full signal to noise ratio (SNR) or carrier to interference ratio (CIR), a preferred modulation and coding scheme (MCS) level, and a flexible frequency reuse rate of the UE. Various information such as FFR information, beamforming index, and the like may be included. The hybrid ARQ feedback channel transmits 1-bit information to request retransmission when the data block received by the UE from downlink is not decodable. The band request indication is used to determine whether a plurality of terminals are allocated a specific signal sequence or a randomly selected signal sequence by contention, so that the base station determines whether the terminal requests the band.

The uplink high-speed feedback and the uplink hybrid ARQ feedback and the bandwidth request information amount is not much, but very important information for the operation of the communication system, high reliability for transmission should be guaranteed. However, in order to prevent waste of resources, the physical channel for transmitting them is usually not allocated a lot of frequency-time axis resources, an efficient modulation and demodulation method is required for reliable transmission.

In a typical OFDMA-based communication system, a non-coherent modulation and demodulation method using no channel estimation is used for transmitting and receiving the uplink fast feedback information, hybrid ARQ feedback, and band request indicator information. In addition, in order to secure high reliability of the fast feedback information, frequency diversity gain is obtained by transmitting through several different frequency resources.

On the other hand, in general, 48 OFDM symbols are included in one frame 110, and the downlink frame: uplink symbol ratio is 5: 3, and downlink frame 110 includes 30 OFDM symbols, and uplink The frame 120 includes 18 OFDM symbols. Here, one subframe 130 includes six OFDM symbols.

In some cases, one OFDM frame includes 42 OFDM symbols, and a downlink frame: uplink symbol ratio is 27:15, and the downlink frame 110 includes 27 OFDM symbols and an uplink. In the irregular uplink frame structure in which the frame 120 includes 15 OFDM symbols, one uplink subframe includes 5 OFDM symbols.

Therefore, in order to apply a signal sequence for uplink control information in an irregular uplink frame structure to a general uplink frame structure (that is, one uplink subframe includes 6 OFDM symbols), (puncturing) repetition. This may distort the orthogonality / correlation between the codes and cause serious performance degradation. In addition, since a part of the signal sequence needs to be repeated, resource efficiency is lowered.

An object of the present invention is to provide an apparatus and method for transmitting information through an uplink control channel in an OFDMA-based communication system.

Another object of the present invention is to provide an apparatus and method for transmitting uplink control information through an uplink resource of an irregular subframe having a modified length in an OFDMA-based communication system.

Another object of the present invention is to provide an apparatus and method for minimizing performance degradation in an OFDMA-based communication system, even if the amount of available resources does not match the size of a signal sequence for noncoherent modulation and demodulation.

According to a first aspect of the present invention for achieving the above object, in a method for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system, the uplink control information to a predetermined bit string A process of encoding, generating a signal sequence corresponding to the predetermined bit string, cyclically rotating the signal sequence according to a predefined rule, and adjusting the cyclically rotated signal sequence according to a subframe length. It is characterized by.

According to a second aspect of the present invention for achieving the above object, a method for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system, the uplink control information to a predetermined bit string Encoding, generating a signal sequence corresponding to the predetermined bit string, cyclically rotating the generated signal sequence differently according to a plurality of subcarrier groups, and mapping the plurality of subcarrier groups to the plurality of subcarrier groups. And adjusting a signal sequence mapped to each to fit an irregular subframe length.

According to a third aspect of the present invention for achieving the above object, in a method for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system, the uplink control information in a predetermined bit string Encoding and generating a signal sequence having a rule subframe length corresponding to the predetermined bit stream, determining whether to map the signal stream to an irregular subframe or a rule subframe, and to map the signal stream to an irregular subframe. In this case, the generated signal sequence is cyclically rotated differently according to a plurality of subcarrier groups to map the plurality of subcarrier groups and the signal sequences mapped to the plurality of subcarrier groups are adjusted to have an irregular subframe length. Characterized in that it comprises a.

According to a fourth aspect of the present invention for achieving the above objects, an apparatus for transmitting information through an uplink control channel in an orthogonal frequency division multiple access type communication system, the uplink control information to a predetermined bit string A channel encoder for encoding, a signal string generator for generating a signal string corresponding to the predetermined bit string, a signal string circular rotator for circularly rotating the signal string according to a predefined rule, and the circularly rotated signal string to match an irregular subframe length. It characterized in that it comprises a subcarrier mapper to adjust.

According to a fifth aspect of the present invention for achieving the above objects, an apparatus for transmitting information through an uplink control channel in an orthogonal frequency division multiple access type communication system, the uplink control information to a predetermined bit string A channel encoder for encoding, a signal sequence generator for generating a signal sequence corresponding to the predetermined bit sequence, and a plurality of signal sequence cycle rotators for circularly rotating the generated signal sequence differently according to a plurality of subcarrier groups and mapping the plurality of subcarrier groups. And a plurality of subcarrier mappers configured to adjust signal sequences mapped to the plurality of subcarrier groups to fit an irregular subframe length.

According to a sixth aspect of the present invention for achieving the above object, in a method for operating a receiver for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system, uplink control information in a frequency domain Separating subcarrier signals of at least one tile structure in which corresponding signal sequences are received; restoring an order of signal sequences corresponding to the uplink control information for each of the at least one tile structure subcarrier signal; And performing a correlation on the signal sequence.

According to a seventh aspect of the present invention for achieving the above object, in a method for operating a receiver for receiving information through an uplink control channel in an orthogonal frequency division multiple access method communication system, uplink control information in the frequency domain Separating subcarrier signals of at least one tile structure in which corresponding signal sequences are received; restoring an order of signal sequences corresponding to the uplink control information for each of the at least one tile structure subcarrier signal; And separating the index and the phase difference vector of the orthogonal sub-signal sequence with respect to the received signal sequence.

According to an eighth aspect of the present invention for achieving the above object, in a receiving apparatus for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system, corresponding to uplink control information in the frequency domain A feedback resource extractor for separating at least one subcarrier signal of at least one tile structure in which the signal sequences are received, a signal sequence extractor for restoring an order of the signal sequence corresponding to the uplink control information for each subcarrier signal of at least one tile structure; And a signal string correlator for performing correlation with the restored signal string.

According to a ninth aspect of the present invention, an apparatus for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system corresponds to uplink control information in a frequency domain. A feedback resource extractor for separating at least one subcarrier signal of at least one tile structure in which the signal sequences are received, a signal sequence extractor for restoring an order of the signal sequence corresponding to the uplink control information for each subcarrier signal of at least one tile structure; And separating the index and the phase difference vector of the reconstructed signal sequence.

As described above, the present invention is to minimize the degradation of the reception performance of the uplink control channel allocated to the irregular subframe by mapping so that the truncated portion or the repeated portion of the signal sequence in the irregular subframe in the OFDMA-based communication system is different. There is an advantage to this. In addition, the resource interval to which the uplink control channel is allocated can maintain almost the same characteristics regardless of the regular subframe or the irregular subframe.

1 is a frame structure in a communication system based on OFDMA,
2 shows 6 × 6 subcarrier group resource structures on a frequency-time axis,
3 shows a 2x6 subcarrier group resource structure on a frequency-time axis,
4 is an exemplary diagram corresponding to a length 12 orthogonal signal sequence for 2x6 frequency-time axis resources;
5 is an exemplary diagram for mapping uplink control channel information in an irregular subframe according to an embodiment of the present invention;
6 is a transmitter for transmitting information through an uplink control channel in an OFDMA-based communication system according to an embodiment of the present invention;
7 is a flowchart for transmitting information through an uplink control channel in an OFDMA based communication system according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Reference will now be made in detail to the preferred embodiments of the present invention, examples of which are illustrated in the accompanying drawings. In the following description of the present invention, detailed descriptions of related well-known functions or configurations will be omitted if it is determined that the detailed description of the present invention may unnecessarily obscure the subject matter of the present invention. 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.

Hereinafter, the present invention will be described a transmission apparatus and method for an uplink control channel using asynchronous detection through an irregular length subframe in an orthogonal frequency division multiple access (OFDMA) based communication system.

In the OFDMA-based communication system, for efficient operation and allocation of radio resources, as shown in FIG. 1, a plurality of adjacent OFDM symbols are combined to form a subframe (or called a slot), and a plurality of subframes are bundled to form a frame. It is a hierarchical structure. In particular, the subframe consists of several OFDM symbols and represents the minimum unit of radio resource allocation that can be divided on the time axis.

The subframes are generally designed to have a constant length. For example, in the Institute of Electrical and Electronics Engineers (IEEE) 802.16 standard, not only various frequency bands are used depending on the operator, but also time division duplex (hereinafter referred to as "time division duplex") In the " TDD ") mode, the uplink frame-to-downlink frame ratio is variously used, therefore, it is difficult to guarantee that all subframes have a constant length. In addition, one or two symbols may not be allocated among uplink subframes in order to support a relay zone or an uplink sounding channel.

Each uplink control channel may be transmitted through a subcarrier group of various sizes according to its information amount and multiplexing method. However, the subcarrier group used is generated by dividing the subcarrier group (hereinafter, referred to as a tile structure) in a subframe or slot used for data transmission by an integer multiple on the frequency-time axis for efficient resource management.

For a more detailed embodiment, the quasi-orthogonal signal sequence for bandwidth request is mapped to a 6x6 tile structure in a subframe consisting of six OFDM symbols, and in order to maintain frequency diversity gain, a 6x6 tile structure is used. Consider using three or more.

In this case, a 6 × 6 tile structure in a subframe or slot is generated by being divided by an integer multiple for the uplink control channel. For example, in FIG. 2, when 3 6 × 6 tile structures on a frequency-time axis are allocated, FIG. 3 illustrates a frequency-time axis resource allocated for transmission of an uplink control channel, and FIG. 3 illustrates a case in which three 2 × 6 tile structures on the frequency-time axis are allocated to an uplink control channel.

Uplink control channels such as a fast feedback channel, a hybrid ARQ channel, and a band request channel are designed to enable asynchronous detection detected without a separate channel estimation. This tile size is modulated using a predetermined orthogonal or quasi-orthogonal signal sequence. That is, when three 6x6 tile structures in a subframe or slot are allocated as shown in FIG. 2, an orthogonal or quasi-orthogonal signal string having a length of 36 is repeatedly used for each 6x6 tile structure, and as shown in FIG. When three six-tile structures are assigned, an orthogonal or quasi-orthogonal signal sequence of length 12 or less is repeated for each 2x6 tile structure.

An example of a method of mapping uplink control channel information such as a fast feedback channel or a hybrid ARQ channel using a 2x6 tile structure as shown in FIG. 4 is shown.

Figure 4 shows an example of a 12 length orthogonal signal sequence corresponding to a 2x6 frequency-time axis resource in accordance with the present invention.

Referring to FIG. 4, since the selected signal sequence is generated based on 6 symbols, such as the rule subframe 410, the selected signal sequence has a length 12 of P [0] to P [11], but the corresponding uplink control channel is allocated. If the subframe is a random subframe 400 consisting of 5 symbols, the signal sequences P [0] to P [9] can be mapped to frequency tones, but P [10] and P [11] are mapped. Can not. In this case, in particular, in the case of a hybrid ARQ channel in which code division multiplexing (hereinafter, referred to as "CDM") in order to increase frequency efficiency of a multi-user signal, orthogonality between users cannot be maintained, reception performance of control channel information can be maintained. Cannot be guaranteed. In contrast, in the case of seven symbol irregular subframes having a length longer than the rule subframe (420), since 14 frequency tones are allocated, 12 signal sequences from P [0] to P [11] are allocated. Two frequency tones remain.

5 shows an example of mapping uplink control channel information in an irregular subframe according to an embodiment of the present invention.

The uplink control information (high speed feedback information, hybrid ARQ information, band request information, etc.) is mapped with a predefined signal sequence, and the predefined signal sequence is mapped with resources on a corresponding frequency-time axis.

That is, when three 6 × 6 tile structures are allocated as shown in FIG. 2, orthogonal or quasi-orthogonal signal strings having a length of 36 are repeatedly used for each 6 × 6 tile structure, and three 2 × 6 tiles as illustrated in FIG. 3. If a structure is assigned, an orthogonal or quasi-orthogonal signal sequence of length 12 or less is repeated for each 2x6 tile structure. The reason why the orthogonal or quasi-orthogonal signal sequence is repeated for each 2x6 tile structure is to obtain frequency diversity gain for uplink control channel information transmission and reception.

As described above, uplink control information is repeatedly transmitted through a plurality of time-frequency resources having a tile structure form. At this time, if the orthogonal / quasi-orthogonal signal sequence mapped to the time-frequency resource is rotated for an irregular subframe, and the circular rotation is different for each tile structure, even if uplink control channel information is transmitted through the irregular subframe, reception performance is achieved. Can reduce the deterioration.

Referring to FIG. 5, uplink control information having a length of 12 in an irregular subframe of 5 OFDM symbols or 7 OFDM symbols instead of 6 OFDM symbol rule subframes that may include 2 × 6 subcarrier groups. It is mapped to the signal sequence of. When uplink control channel information is transmitted through three subcarrier groups, 12 signal sequences ranging from P [0] to P [11] are sequentially mapped in the first tile structure, and 4 cycles are used in the second tile structure. The rotation is applied to map the eight signal sequences from P [4] to P [11] in order, and remap the remaining signal sequences from P [0]. In other words, taking an example of an irregular subframe of 5 symbols in length, {P [4], P [5], P [6], P [7], P [8], P [9], P [10], P [11], P [0], P [1]}. In the same way, in the third subcarrier group, 8 rotational rotations are applied such that {P [8], P [9], P [10], P [11], P [0], P [1], and P [2. ], P [3], P [4], P [5]}. By this mapping method, P [10] and P [11] are not transmitted in the first tile structure, P [2] and P [3] in the second tile structure, and P [6] and in the tile structure. Although P [7] is not transmitted (500), when all three tile structures are received, this can be restored.

Applying the same method to seven OFDM symbol subframes, P [0] and P [1] are transmitted once more in the first tile structure instead of loss, and P [4] and P [in the second tile structure. 5] is transmitted once more, and P [8] and P [9] are transmitted once more in the third tile structure to maximize the gain (510). The specific order in which the signal sequence indicating the information of the uplink control channel corresponds to the time-frequency resource and the cyclic rotation amount of the signal sequence applied to each tile structure may be appropriately selected according to an implementation method.

For example, the circular rotation value of the signal sequence may be determined according to the random variable for each tile structure. That is, starting from P [1] according to the random variable in the first tile structure, starting from P [5] according to the random variable in the second tile structure, and starting from P [9] according to the random variable in the third tile structure. Can be.

As another embodiment, the cyclic rotation value of the signal sequence may be determined according to Equation 1 below.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe. M is 12 in the IEEE 802.16 standard, and the offset value may be predetermined as a system parameter between the transmitter and the receiver, and may be determined through a signaling procedure between the transmitter and the receiver.

6 illustrates a transmitter for transmitting information through an uplink control channel in an OFDMA based communication system according to an embodiment of the present invention.

Referring to FIG. 6, the transmitter includes a channel encoder 600, a signal sequence generator 610, N control channel signal sequence circular rotors 620_1 to 620_N, N control channel subcarrier mappers 630_1 to 630_N, and an IFFT calculator ( 640.

The channel encoder 600 encodes uplink control channel information such as fast feedback, hybrid ARQ, and band request information into predetermined bits, and provides the same to the signal sequence generator 610.

The signal sequence generator 610 generates an orthogonal or quasi-orthogonal signal sequence corresponding to the uplink control channel information bit sequence and outputs it to the N control channel signal sequence circular rotors 620_1 to 620_N. The orthogonal or quasi-orthogonal signal sequence is a sequence of modulation symbols according to a corresponding modulation scheme (eg, BPSK, QPSK).

The signal sequence circular rotors 620_1 to 620_N are cyclically rotated by applying different shift values to the orthogonal or quasi-orthogonal signal sequence from the signal sequence generator 610 to the subcarrier mappers 630_1 to 630_N. Provide each. For example, the signal sequence circular rotor 620_1 determines that the signal sequence is mapped to the subcarriers from the first modulation symbol p [0] or the second p [1] of the signal sequence according to the index of the tile structure mapped to the subcarrier. The signal sequence circular rotor 620_2 determines that the signal sequence is mapped to the subcarrier from the third modulation symbol p [2] of the signal sequence or the fourth p [3] of the signal sequence according to the index of the tile structure mapped to the subcarrier. The signal sequence circular rotor 620_N has a signal sequence from the N-2 th modulation symbol p [N-2] of the signal sequence or the N-1 th p [N-1] of the signal sequence according to the index of the tile structure mapped to the subcarrier. Determine to be mapped.

The subcarrier mappers 630_1 to 630_N sub-channel each of the orthogonal or quasi-orthogonal signal strings cyclically rotated from the signal string circular rotors 620_1 to 620_N to correspond to the assigned tile structure. That is, the first subcarrier mapper 630_1 forms a subchannel by mapping the signal sequence circulated and rotated from the signal sequence circular rotor 620_1 with the first tile structure. The Nth subcarrier mapper 630_N forms a subchannel by mapping the signal sequence circulated and rotated from the signal sequence cyclic rotor 620_N with the Nth tile structure. In this case, the subcarrier mappers 630_1 to 630_N cut or repeat a portion of the signal sequence so that the signal sequence is mapped to the length of the corresponding subframe.

For example, in FIG. 5, uplink control having a length of 12 in an irregular subframe of 5 OFDM symbols or 7 OFDM symbols rather than 6 OFDM symbol rule subframes that may include a 2 × 6 tile structure. It is mapped to a signal sequence of information. When uplink control channel information is transmitted through three tile structures, 12 signal sequences ranging from P [0] to P [11] are sequentially mapped in the first tile structure, and 4 cycles are used in the second tile structure. The rotation is applied to map the eight signal sequences from P [4] to P [11] in order, and remap the remaining signal sequences from P [0].

In the same way, when applied to seven OFDM symbol irregular subframes, P [0] and P [1] are transmitted once more in the first tile structure, and P [4] and P [5] in the second tile structure. Is transmitted once more, and P [8] and P [9] are transmitted once more in the third tile structure to maximize the gain. The specific order in which the signal sequence indicating the information of the uplink control channel corresponds to the time-frequency resource and the cyclic rotation amount of the signal sequence applied to each subcarrier group may be appropriately selected according to the implementation method.

The IFFT operator 640 transmits the subchannelized data by the subcarrier mappers 630_1 to 630_N through a discrete fast fourier transform (IFFT) operation.

As described above, when the uplink control information is transmitted in a plurality of tile structures, the circular rotation is applied to each tile structure differently, so that the portion where the signal sequence is cut or the repeated portion is changed due to an irregular subframe, thereby receiving performance. Can reduce the deterioration.

7 illustrates a procedure for transmitting information through an uplink control channel in an OFDMA-based communication system according to an embodiment of the present invention.

Referring to FIG. 7, the transmitter encodes uplink control channel information into predetermined bits in step 700, and generates an orthogonal or quasi-orthogonal signal sequence corresponding to the control channel information bit string in step 702.

Thereafter, in step 704, the transmitter performs a corresponding mode operation if it is not an irregular frame. In the corresponding mode operation, the signal sequence does not need to be punctured or repeated in accordance with the length of the orthogonal or quasi-orthogonal signal sequence corresponding to the control channel information bit sequence and the length of the uplink subframe.

On the other hand, in the case of an irregular frame in step 704, the transmitter proceeds to step 706 to cyclically shift the orthogonal or quasi-orthogonal signal sequence by applying different shift values. That is, the starting point at which the signal sequence is mapped to the subcarrier is different for each tile structure.

Thereafter, the transmitter subchannels the orthogonal or quasi-orthogonal signal sequence cyclically rotated in step 708 to correspond to the assigned subcarrier group. In this case, the transmitter cuts or repeats a part of the signal sequence so that the signal sequence is mapped to the length of the corresponding subframe.

Thereafter, in step 710, the transmitter transmits the subchannelized data through an IFFT operation.

The procedure of the present invention is then terminated.

In FIG. 7, a subframe including six OFDM symbols in one subframe is defined as a subframe, and a subframe including five or seven OFDM symbols in one subframe is defined as an irregular subframe. In this case, the start point of the signal sequence is differently applied to each tile structure in which the uplink control information is transmitted according to the irregular frame. However, regardless of the irregular frame, the starting point of the signal sequence may be differently applied to each tile structure in which uplink control information is transmitted. In other words, even in the case of a rule frame, a start point of a signal sequence may be differently applied to each tile structure in which uplink control information is transmitted.

8 illustrates an example of mapping a quadrature sub-signal string (p ₁ , p ₂ , p ₃ , p ₄ ) of length ₄ and subcarriers for fast feedback resources in a 2 × 6 tile structure on a frequency-time axis according to the present invention. 9 shows an example of mapping between a quasi-orthogonal signal sequence of length 3 (p ₁ , p ₂ , p ₃ ) and a subcarrier for fast feedback resources in a 2 × 6 tile structure on a frequency-time axis according to the present invention. It is shown.

8 and 9, the entire quasi-orthogonal signal sequence (p ₁ , p ₂ , p ₃ ) or (p ₁ , p ₂ , p ₃ , p ₄ ) is within a subcarrier bundle to which each orthogonal sub-signal sequence is transmitted. The best detection performance can be ensured only by keeping the channel gain as constant as possible and minimizing the phase change while receiving different orthogonal sub-signals. In order to minimize these channel and phase changes at the receiving end, it is necessary to experience only a change sufficiently smaller than the coherence time or coherence bandwidth of the channel or the time and frequency tolerance at the receiving end. Therefore, in order to correspond to each orthogonal sub-signal sequence above the assigned subcarrier bundle, it must correspond so that this characteristic is satisfied.

Therefore, in order to minimize the channel change in each orthogonal sub-signal sequence, the receivers are located adjacent to each other, and in order to overcome the phase difference between the different orthogonal sub-signal sequences, the receiver corresponds to the corresponding order of the orthogonal sub-signal sequences for each fast feedback resource. You can also change The specific correspondence order of each orthogonal sub-signal sequence may vary.

10 illustrates a receiver for transmitting information through an uplink control channel in an OFDMA-based communication system according to a first embodiment of the present invention.

Referring to FIG. 10, the receiver includes an FFT operator 1000, a plurality of fast feedback resource extractors 1002_1 to 1002_N, a plurality of received signal sequence extractors 1004_1 to 1004_N, a plurality of quasi-orthogonal signal sequence correlators 1006_1 to 1006_N, A plurality of correlation value squarers 1008_1 to 1008_N, a maximum value extractor 1010, and a channel decoder 1012 are configured.

The FFT operator 1000 performs a discrete fast Fourier transform (FFT) on the received signal to convert a signal in the time domain into a signal in the frequency domain.

The plurality of fast feedback resource extractors 1002_1 to 1002_N each extract a received signal having a tile structure in which fast feedback information is transmitted according to a position on a time-frequency axis of the fast feedback resource. For example, in FIG. 5, the fast feedback resource extractor 1002_1 extracts subcarriers of a first tile structure in which fast feedback information is transmitted from all subcarriers in the frequency domain, and the fast feedback resource extractor 1002_2 is configured to determine the frequency of the frequency domain. The subcarriers of the second tile structure in which the fast feedback information is transmitted are extracted from all the subcarriers, and the fast feedback resource extractor 1002_3 extracts the subcarriers of the third tile structure in which the fast feedback information is transmitted from all subcarriers in the frequency domain. .

The plurality of received signal sequence extractors 1004_1 to 1004_N respectively restore the rotated quasi-orthogonal signal sequence of the fast feedback information transmitted through the corresponding tile structure to the original quasi-orthogonal signal sequence. That is, since the quasi-orthogonal signal strings correspond to subcarriers in each of the fast feedback resources in different orders, the quasi-orthogonal signal strings are reconstructed and extracted in the order of the original quasi-orthogonal signal strings according to the number of the fast feedback resources and their corresponding order. For example, in the quasi-orthogonal signal sequence transmitted through the first tile structure in FIG. 5, since the circular rotation is not applied, the first received signal sequence extractor 1004_1 is a quasi-orthogonal angle of the first fast feedback resource extractor 1002_1. The signal sequence is transmitted to the first quasi-orthogonal signal sequence correlator 1006_1. In FIG. 5, since the quasi-orthogonal signal sequence transmitted through the second tile structure has been subjected to cyclic rotation by 4, the second received signal sequence extractor 1004_2 is a quasi-orthogonal signal sequence of the second fast feedback resource extractor 1002_2. P [4], P [5], ... P [10], P [11], P [0], P [1] to P [0], P [1], P [4], P [ 5], ..., P [10] and P [11] are restored to the signal sequence and transmitted to the first quasi-orthogonal signal sequence correlator 1006_2. In FIG. 5, since the quasi-orthogonal signal sequence transmitted through the third tile structure has been subjected to cyclic rotation by eight, the third received signal sequence extractor 1004_3 is a quasi-orthogonal signal sequence P [of the third fast feedback resource extractor 1002_3. 8], ..., P [11], P [0], ..., P [5] to P [0], ..., P [5], P [8], ..., P The signal sequence is restored to the signal sequence and transmitted to the third quasi-orthogonal signal sequence correlator 1006_3.

Here, the plurality of received signal sequence extractors 1004_1 to 1004_N can each know how much the quasi-orthogonal signal sequences of the corresponding tile structure are circulated and rotated from the transmitter, or separately from the transmitter according to a rule defined at the transmitter and the receiver. You do not need to know.

The plurality of quasi-orthogonal signal sequence correlators 1006_1 to 1006_N each correlate with all possible orthogonal or quasi-orthogonal signal sequences to the restored quasi-orthogonal signal sequences of the corresponding received signal sequence extractors 1004_1 to 1004_N, respectively, to square the multiple correlation values. Output to the groups 1008_1 to 1008_N, respectively. The plurality of correlation squarers 1008_1 to 1008_N respectively square the correlation values of the corresponding received signal sequence extractors 1004_1 to 1004_N and output the squares.

The output values from the plurality of quasi-orthogonal signal string correlators 1006_1 to 1006_N are added together and input to the maximum extractor 1010. The maximum value extractor 1010 compares the squares of the outputs of each correlator, determines an orthogonal signal string of the correlator that maximizes the value, and outputs the result to the channel decoder 1012. The channel decoder 1012 determines and outputs a fast feedback information bit string corresponding to the determined orthogonal signal sequence by using the result from the maximum value extractor 1010.

In FIG. 10, quasi-orthogonal signal sequence correlators 1006_1 to 1006_N are each composed of 27, 36, or 64 parallel correlation value extractors, depending on which quasi-orthogonal signal sequence is used. In order to obtain frequency diversity from the first to Nth fast feedback resources, the output of each parallel correlation extractor passes through a squarer, and the squares of the outputs of the correlation extractor for the same quasi-orthogonal signal sequence are summed together. It is determined that the quasi-orthogonal signal string of the correlation value extractor whose sum is maximum is transmitted. The fast feedback information bit string corresponding to the determined quasi-orthogonal signal string is determined.

Meanwhile, in FIG. 10, assuming that a quasi-orthogonal signal sequence having a length of 12 and 64 codewords is received through three fast feedback resources, each quasi-orthogonal signal sequence correlator includes a correlation extractor requiring 12 multiplications. Because each fast feedback resource requires 64, the total receiver requires 192 parallel correlation extractors. In order to reduce the amount of computation, instead of detecting the entire quasi-orthogonal signal sequence at once, a method of separating and extracting the orthogonal sub-signal sequence index and the phase difference vector as shown in FIGS. 11 and 12 may be used.

11 illustrates a receiver for transmitting information through an uplink control channel in an OFDMA based communication system according to a second embodiment of the present invention.

Referring to FIG. 11, the receiver includes an FFT operator 1100, a plurality of fast feedback resource extractors 1102_1 to 1102_N, a plurality of received signal sequence extractors 1104_1 to 1004_N, a plurality of orthogonal sub-signal correlators 1106_11 to 1106_NM, And a plurality of squarers 1108, maximum detectors (orthogonal signal sequence index extractors) 1110.

The FFT operator 1100, the plurality of fast feedback resource extractors 1102_1 to 1102_N, and the plurality of received signal sequence extractors 1104_1 to 1004_N are the FFT operator 1000 and the plurality of fast feedback resource extractors 1002_1 to 1002_N in FIG. 10. ), The same as the plurality of received signal sequence extractors 1004_1 to 1004_N.

In FIG. 11, the signal sequence received as shown in FIGS. 8 to 9 is composed of a plurality of orthogonal sub-signal sequences. Accordingly, each of the signal sequence extractors 1104-1 to 1104-N separates one received signal sequence into a plurality of orthogonal sub-signal sequences and outputs them to the correlator, and each correlator 1106 -11 to 1106-1M, or 1106. -21 to 1106-2M and 1106-N1 to 1106-NM) perform separate correlation for each orthogonal sub-signal sequence. That is, assuming that the quasi-orthogonal signal sequence having a length of 12 and 64 codewords, which are used as an embodiment of the present invention, is received through three fast feedback resources, the entire quasi-orthogonal signal sequence has a length of 4 orthogonal sub-signal sequence 3. Since the quadrature sub-signal correlators 1106_11 to 1106_NM require four correlation extractors for each sub-signal sequence, each of the quadrature sub-signal correlators 1106_11 to 1106_NM requires only 36 parallel correlation extractors in the entire receiver.

Orthogonal sub-signal correlation extractors (e.g., orthogonal sub-signal correlators 1106_11, 1106_21, ..., 1106_N1) or orthogonal sub-signal correlators 1106_21, 1106_22, orthogonal sub-signal correlators 1106_N2) and the outputs of the squarer 1108. Since each orthogonal sub-signal sequence can be transmitted only in a selected combination as shown in Figs. 8 and 9, the orthogonal signal sequence index extractor 1110 is the combination. An orthogonal subsignal sequence index is selected in which the sum of the outputs of the orthogonal subsignal candidates is maximized, and after detecting the orthogonal subsignal sequence index, the phase difference vector is extracted using the structure shown in the block diagram of FIG. Orthogonal sub-signal correlators 1202-11 to 1202_NM output in FIG. 12 are orthogonal sub-signal correlation values corresponding to orthogonal sub-signal sequences previously determined to have been transmitted through FIG. 12. Therefore, no additional correlator operation is required, so the correlator output of each orthogonal sub-signal is multiplied by all the transmittable phase difference vectors U ₁ to U _M to square the sum 1204-1 to 1204_N. 1206_1 to 1206_N, operations in a plurality of fast feedback resources are combined, at which time, the phase difference vector extractor 1208 determines that the candidate of the phase difference vector that maximizes the sum is the phase difference vector transmitted.

Finally, from the result of the orthogonal sub-signal sequence index extractor of FIG. 11 and the phase difference vector extractor of FIG. 12, the transmitted fast feedback information bit string is determined.

13 is a flowchart illustrating an operation of a receiver for transmitting information through an uplink control channel in an OFDMA-based communication system according to an embodiment of the present invention.

Referring to 13, the receiver performs a discrete fast Fourier transform (FFT) on the received signal in step 1300 to convert a signal in the time domain into a signal in the frequency domain.

In step 1302, the receiver separates the subcarrier signal from which the fast feedback information is transmitted on the frequency axis, and transmits through the corresponding tile structure using circular rotation information (that is, mapping start point of the quasi-orthogonal signal sequence) in step 1304. The rotated quasi-orthogonal signal sequence of fast feedback information is restored to the original quasi-orthogonal signal sequence.

Thereafter, the receiver performs correlation for each quasi-orthogonal signal sequence as shown in FIG. 10 in step 1306. Alternatively, as shown in FIG. 11, the correlation may be performed to extract the quadrature sub-signal index and the phase difference vector separately.

Meanwhile, in the detailed description of the present invention, specific embodiments have been described, but various modifications are possible 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 determined not only by the scope of the following claims, but also by the equivalents of the claims.

Claims (46)

A method of operating a transmitter for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system,
Encoding uplink control information into a predetermined bit string;
Generating a signal sequence corresponding to the predetermined bit sequence;
Rotating the signal sequence according to a predefined rule;
And adjusting the circularly rotated signal sequence to match an irregular subframe length.
The method of claim 1,
The generated signal sequence is mapped to a different signal sequence to each of at least one tile structure.
The method of claim 1,
The process of adjusting the circularly rotated signal sequence according to the irregular subframe length,
When the circularly rotated signal sequence is larger than the irregular subframe length, a portion of the signal sequence is cut to fit the irregular subframe length,
And if the circularly rotated signal sequence is smaller than the irregular subframe length, repeating a portion of the signal sequence to fit the irregular subframe length.
The method of claim 1,
The signal sequence is a permutation of modulation symbols of a length of a regular subframe according to a predefined modulation scheme, characterized in that orthogonal or quasi-orthogonal between the modulation symbols.
The method of claim 1,
The process of circularly rotating the signal sequence according to a predefined rule,
Determining the cyclic rotation value of the signal sequence according to the following equation for each tile structure;

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
And mapping a signal sequence for each tile structure according to the determined rotational rotation value.
The method of claim 1,
The uplink control information is characterized in that one of the high-speed feedback information, hybrid ARQ information, band request information.
A method of operating a transmitter for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system,
Encoding uplink control information into a predetermined bit string;
Generating a signal sequence corresponding to the predetermined bit sequence;
Cyclically rotating the generated signal sequence differently according to a plurality of tile structures to map the plurality of subcarrier groups;
And adjusting a signal sequence mapped to each of the plurality of subcarrier groups to fit an irregular subframe length.
The method of claim 7, wherein
The process of adjusting the signal sequence mapped to each of the plurality of tile structures to match an irregular subframe length may include:
When the circularly rotated signal sequence is larger than the irregular subframe length, a portion of the signal sequence is cut to fit the irregular subframe length,
And if the circularly rotated signal sequence is smaller than the irregular subframe length, repeating a portion of the signal sequence to fit the irregular subframe length.
The method of claim 7, wherein
The signal sequence is a permutation of modulation symbols of a length of a regular subframe according to a predefined modulation scheme, characterized in that orthogonal or quasi-orthogonal between the modulation symbols.
The method of claim 7, wherein
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
The method of claim 7, wherein
The uplink control information is characterized in that one of the high-speed feedback information, hybrid ARQ information, band request information.
A method of operating a transmitter for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system,
Encoding uplink control information into a predetermined bit string and generating a signal string having a rule subframe length corresponding to the predetermined bit string;
Determining whether to map the signal sequence to an irregular subframe or a rule subframe;
When the signal sequence is mapped to an irregular subframe, circularly rotating the generated signal sequence differently according to a plurality of tile structures and mapping the plurality of tile structures to the plurality of tile structures;
And adjusting a signal sequence mapped to each of the plurality of tile structures to fit an irregular subframe length.
The method of claim 12,
The process of adjusting the signal sequence mapped to each of the plurality of tile structures to match an irregular subframe length may include:
When the circularly rotated signal sequence is larger than the irregular subframe length, a portion of the signal sequence is cut to fit the irregular subframe length,
And if the circularly rotated signal sequence is smaller than the irregular subframe length, repeating a portion of the signal sequence to fit the irregular subframe length.
The method of claim 12,
The signal sequence is a permutation of modulation symbols according to a predefined modulation scheme, characterized in that orthogonal or quasi-orthogonal modulation symbols.
The method of claim 12,
And when the signal sequence is mapped to a regular subframe, mapping the generated signal sequence to the plurality of subcarrier groups without cyclic shift according to a plurality of subcarrier groups, respectively.
The method of claim 12,
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
The method of claim 12,
The uplink control information is characterized in that one of the high-speed feedback information, hybrid ARQ information, band request information.
An apparatus for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system,
A channel encoder for encoding uplink control information into a predetermined bit string;
A signal string generator for generating a signal string corresponding to the predetermined bit string;
A signal sequence circular rotator for rotating the signal sequence according to a predetermined rule;
And a subcarrier mapper for adjusting the circularly rotated signal sequence to match an irregular subframe length.
19. The method of claim 18,
The generated signal sequence is mapped to at least one tile structure, each different signal sequence.
19. The method of claim 18,
The subcarrier mapper,
When the circularly rotated signal sequence is larger than the irregular subframe length, a portion of the signal sequence is cut to fit the irregular subframe length,
And when the circularly rotated signal sequence is smaller than the irregular subframe length, repeating a portion of the signal sequence to fit the irregular subframe length.
19. The method of claim 18,
Wherein the signal sequence is a permutation of modulation symbols of a length of a regular subframe according to a predefined modulation scheme, and is orthogonal or quasi-orthogonal between modulation symbols.
19. The method of claim 18,
The signal string circulation rotor,
For each tile structure, the cyclic rotation value of the signal string is determined according to the following equation,

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
And mapping a signal sequence for each tile structure according to the determined rotational rotation value.
19. The method of claim 18,
And the uplink control information is one of fast feedback information, hybrid ARQ information, and band request information.
A transmission apparatus for transmitting information through an uplink control channel in an orthogonal frequency division multiple access communication system,
A channel encoder for encoding uplink control information into a predetermined bit string;
A signal string generator for generating a signal string corresponding to the predetermined bit string;
A plurality of signal sequence circular rotators for circulating the generated signal sequence differently according to a plurality of tile structures and mapping them to the plurality of tile structures;
And a plurality of subcarrier mappers configured to adjust signal sequences mapped to the plurality of tile structures to match an irregular subframe length.
25. The method of claim 24,
The subcarrier mapper
When the circularly rotated signal sequence is larger than the irregular subframe length, a portion of the signal sequence is cut to fit the irregular subframe length,
And when the circularly rotated signal sequence is smaller than the irregular subframe length, repeating a portion of the signal sequence to fit the irregular subframe length.
25. The method of claim 24,
Wherein the signal sequence is a permutation of modulation symbols of a length of a regular subframe according to a predefined modulation scheme, and is orthogonal or quasi-orthogonal between modulation symbols.
25. The method of claim 24,
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
25. The method of claim 24,
And the uplink control information is one of fast feedback information, hybrid ARQ information, and band request information.
A method of operating a receiver for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system,
Separating subcarrier signals of at least one tile structure in which signal sequences corresponding to uplink control information are received in a frequency domain;
Restoring an order of a signal sequence corresponding to the uplink control information for each subcarrier signal of the at least one tile structure;
And performing correlation on the restored signal sequence.
30. The method of claim 29,
Restoring the order of the signal sequence corresponding to the uplink control information,
And rearranging the signal sequences corresponding to the uplink control information transmitted by circular rotation to different starting points for each tile structure in the original order.
30. The method of claim 29,
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
30. The method of claim 29,
The uplink control information is characterized in that one of the high-speed feedback information, hybrid ARQ information, band request information.
A method of operating a receiver for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system,
Separating subcarrier signals of at least one tile structure in which signal sequences corresponding to uplink control information are received in a frequency domain;
Restoring an order of a signal sequence corresponding to the uplink control information for each subcarrier signal of the at least one tile structure;
And separating the index and the phase difference vector of the orthogonal sub-signal sequence with respect to the restored signal sequence.
34. The method of claim 33,
Restoring the order of the signal sequence corresponding to the uplink control information,
And rearranging the signal sequences corresponding to the uplink control information transmitted by circular rotation to different starting points for each tile structure in the original order.
34. The method of claim 33,
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
34. The method of claim 33,
The uplink control information is characterized in that one of the high-speed feedback information, hybrid ARQ information, band request information.
34. The method of claim 33,
And wherein the signal sequences in the one tile structure include a plurality of orthogonal subsignal sequences.
A receiving apparatus for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system,
A feedback resource extractor for separating at least one subcarrier signal of at least one tile structure in which signal sequences corresponding to uplink control information are received in a frequency domain;
A signal sequence extractor for restoring an order of signal sequences corresponding to the uplink control information for each subcarrier signal of the at least one tile structure;
And a signal sequence correlator for performing correlation with the restored signal sequence.
The method of claim 38,
The signal sequence extractor,
And rearranging the signal sequences corresponding to the uplink control information transmitted by circular rotation to different starting points for each tile structure in the original order.
The method of claim 38,
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
The method of claim 38,
And the uplink control information is one of fast feedback information, hybrid ARQ information, and band request information.
A receiving apparatus for receiving information through an uplink control channel in an orthogonal frequency division multiple access communication system,
A feedback resource extractor for separating at least one subcarrier signal of at least one tile structure in which signal sequences corresponding to uplink control information are received in a frequency domain;
A signal sequence extractor for restoring an order of signal sequences corresponding to the uplink control information for each subcarrier signal of the at least one tile structure;
And a maximum value extractor for separating an index of the reconstructed signal sequence and a phase difference vector.
The method of claim 42, wherein
The signal sequence extractor,
And rearranging the signal sequences corresponding to the uplink control information transmitted by circular rotation to different starting points for each tile structure in the original order.
The method of claim 42, wherein
The circular rotation of the signal sequence is characterized in that determined according to the following equation.

Here, P [k] is a signal sequence, C [k] is a signal sequence P [k] is a signal sequence to which circular rotation is applied, k is a modulation symbol index, and mod [i, j] returns the remainder of i divided by j. Is a modulo operation, t is a tile index, offset is a cyclic value between tiles, and m is the size of a signal sequence mapped to a subframe.
The method of claim 42, wherein
And the signal sequences in the one tile structure include a plurality of orthogonal subsignal sequences.
The method of claim 42, wherein
And the uplink control information is one of fast feedback information, hybrid ARQ information, and band request information.

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