KR100550414B1 - Encoding and Decoding Apparatus using Low Density Parity Check codes - Google Patents

Abstract

The present invention relates to an encoding device and a decoding device using a Low Density Parity Check (LDPC) code in a hybrid retransmission system.

The first LDPC code encoder of the LDPC encoding apparatus performs LDPC encoding on input information data and transmits the LDPC encoding to the decoding apparatus. The interleaver interleaves and outputs the input information data. The second LDPC code encoder is located in parallel with the first LDPC code encoder with respect to the input information data, and performs LDPC encoding on the input information data interleaved by the interleaver to transmit the same to the decoding apparatus. At this time, the first LDPC code encoder transmits its output to the decoding device in odd-numbered transmission of the input information data according to the retransmission request from the decoding apparatus, and the second LDPC code encoder inputs according to the retransmission request from the decoding apparatus. Even output of the information data transmits its output to the decoding device.

According to the present invention, since the LDPC code is used, an error floor phenomenon of a turbo code is alleviated, and data throughput is increased due to a reduction in decoding time.

Hybrid Retransmission, Error Correction Code, LDPC Code, Decoder, Encoder, Interleaver

Description

Encoding and Decoding Apparatus using Low Density Parity Check codes}

1 is a diagram schematically illustrating a concept of a hybrid retransmission method used in an EV-DO and an HSDPA system.

2 is a block diagram of an encoding device and a decoding device using LDPC codes in a hybrid retransmission system according to an embodiment of the present invention.

3 is a block diagram of an encoding device and a decoding device using LDPC codes in a hybrid retransmission system according to a second embodiment of the present invention.

FIG. 4 is a diagram illustrating generation and parity check metrics configured in the case of incremental redundancy among hybrid retransmission using LDPC codes.

The present invention relates to a hybrid retransmission system, and in particular, LDPC (Low Density Parity Check) code as an error correction code, and interleaving the packet during retransmission, LDPC code that improves error correction capability and packet data transmission efficiency The present invention relates to an encoding device and a decoding device to be used.

There are two ways to control the errors caused by the channel environment in the communication system. One is a method of detecting an error occurring on a channel without correcting it at a receiver and notifying the transmitter only to notify the transmitter and retransmitting at the transmitter. This method uses forward error correction to correct an error without retransmitting it.

Recently, a technique for correcting an error while also retransmitting is called a hybrid automatic repeat request (HARQ) technique. In the mobile communication system, both the retransmission and the error correction code are used as independent techniques, and for recent high-speed data transmission, a hybrid automatic repeat request (HARQ) technique that corrects an error while performing the retransmission is also used. have.

In the third generation mobile communication system, the EV-DO (EV-DO) system, which is a synchronous high-speed data service system, and the asynchronous HSDPA (High Speed Downlink Packet Access) system, use hybrid retransmission (HARQ) technology. In such a retransmission technique, turbo codes are used as error correction codes, and chase combining and incremental redundancy schemes are used as ARQs.

When the EV-DO system and the HSDPA system transmit a data packet encoded with information data using a turbo encoder and receive the decoding at the receiver and perform decoding with the turbo decoder, the decoding stage fails. This again informs the sender that it has failed to send the data packet.

Meanwhile, the receiver determines whether the decoding succeeds or fails by performing a CRC check on the decoding result after decoding by the decoder. If the determined result is successful, an acknowledgment (ACK) is sent to the transmitting side, and if it fails, a negative acknowledgment (NAK) is sent to the transmitting side. When the transmitting side receives the ACK from the receiving side, it transmits new data because the transmission is successful. When the transmitting side receives the NAK, the transmitting side attempts to retransmit within the given number of retransmissions.

Among the retransmission methods, the chase combining method transmits the same packet as the previously sent data packet at the time of retransmission, and the receiving side combines the retransmitted packet and the previously sent packet to decode the decoder. The incremental redundancy scheme encodes the data packet in a different form from the data packet previously transmitted by the transmitting side at the time of retransmission and transmits the data packet to the receiving side.

Originally, the error correction code uses the principle of restoring the data to be sent when decoding by using the redundancy when the redundancy is transmitted by performing encoding to the data to be sent. Incremental redundancy increases the efficiency of the decoder by increasing the redundancy from the decoder's point of view by adding redundancy at every retransmission. Therefore, the receiver performs decoding by using the previously transmitted packet and the newly received packet together. The chase combining method retransmits the same packet several times on the transmitting side and performs decoding by combining the packets received several times on the receiving side, so that the complexity of the system does not increase significantly. Therefore, the chase combining method can obtain only diversity gain because the packet is transmitted by combining several times, whereas the incremental redundancy method converts and transmits to another packet at the time of retransmission. The complexity of the decoder is greatly increased due to the increase in the packet received each time it is retransmitted. However, incremental redundancy has a high probability of recovering the original information signal relatively accurately by receiving and decoding new types of packets. Therefore, the incremental redundancy scheme is known to have better performance because it can simultaneously obtain diversity gain and coding gain. That is, the chase combining method is inferior to the incremental redundancy method, but has the advantage of reducing the increase in the complexity of the system, and the incremental redundancy method is superior in performance but has the disadvantage of increasing the complexity of the system.

Error correction codes can be divided into Block Codes and Trellis Codes. An example of a block code is an LDPC code, and an example of a trellis code is a convolutional encoder of a turbo code.

In the case of the block code, the characteristics of the encoder and the decoder are determined by the generating matrix G and the parity check matrix H. Basically, LDPC code is encoded by one encoder, and iterative decoding is performed by one decoder to obtain good performance similar to turbo code. At this time, the decoder calculates a probability value that satisfies the relationship between the parity check matrix H and the received codeword C '(H · C ′ = 0) to perform decoding.

In the case of the trellis code, encoding is performed using the generator polynomial, and the decoder performs decoding by calculating all probabilities for possible trellis.

As described above, in the case of the LDPC code, the relationship between the parity check matrix H and the received codeword C '(H · C' = 0) can be calculated in parallel in the decoder, but the trellis code is compared to the trellis. Since it needs to be decoded sequentially, parallel computation is impossible, which takes a long time.

Turbocode guarantees performance in that it uses two convolutional encoders and an interleaver at the encoder, and repeatedly performs decoding at the decoder at the two decoders. In other words, if the turbo code is composed of only one encoder and decoder, the good performance expected from the turbo code may not be obtained.

FIG. 1 is a diagram schematically illustrating the concept of a hybrid retransmission method used in an EV-DO and an HSDPA system.

It can be seen from FIG. 1 that the convolutional encoder 1, the convolutional encoder 2, the interleaver, the puncturer, i.e., the turbo code is composed of a hybrid retransmission encoder (the same configuration is used even when no retransmission is performed). .

In the case of using the chase combining method at the code rate 1/3, an example of a conventional hybrid retransmission technique will be described.

The transmitting side first transmits data X, Y1, and Z2, and when the receiving side performs decoding to determine that decoding has failed by CRC check, it stores the decoded result and requests retransmission. The transmitting side retransmits the same data X, Y1, Z2.

The receiver performs decoding, and if it fails, requests the transmitter to retransmit if less than a given number of retransmission requests. The above process is performed until less than a given number of retransmissions.

On the other hand, in the incremental redundancy scheme, the transmitting side transmits X, Y1, and Z2. If the decoding fails at the receiving side, the transmitting side stores the decoding result and requests retransmission. The transmitting side retransmits the data X, Y2 and Z1, and the receiving side decodes using the received data and previously stored data. If decoding fails, retransmission is requested if less than a given number of retransmission requests. The transmitting side transmits data X, Y1, Z2 for odd-numbered transmissions, and the data X, Y2, Z1 for even-numbered transmissions. The above process is performed until less than the given number of retransmissions.

As described above, in case of using a turbo code as an error correction code for high-speed data transmission, an error floor phenomenon and a decoder unit that do not improve performance even when more signal energy is used at an operating point are used. Because of the sequential operation, the decoding takes a long time.

Accordingly, an object of the present invention is to provide an encoding device and a decoding device using an LDPC code capable of parallel computation processing at a decoder instead of a turbo code in a hybrid retransmission system in order to overcome the above problems.

The embodiment of the present invention is characterized in that the conventional hybrid retransmission encoder uses an LDPC code encoder, in particular, two LDPC code encoders and an interleaver, unlike the turbo encoder.

As a method of performing hybrid retransmission using an LDPC code, a chase combining method and an incremental redundancy method may be considered. To make the incremental redundancy among these methods, the generation matrix G and the parity check matrix H can be configured as shown in FIG. Here, G1 and H1 correspond to the first transmission, G2 and H2 correspond to the second transmission, and G3 and H3 correspond to the third transmission. In this way, incremental redundancy greatly increases the complexity of the system because the size of the matrix increases significantly with each retransmission.

Since the LDPC code does not improve the performance as much as the turbo code even if the code rate is reduced at the code rate 1/2, when the incremental redundancy method is used in the retransmission method, the complexity increases significantly compared to the performance improvement. Thus, for systems requiring moderate complexity, the chase coupling scheme is more suitable than the incremental redundancy scheme.

Therefore, the present invention is modified from the chase coupling method, and proposes a method that is superior to the conventional chase coupling method.

In the original chase combining method, it consists of one encoder and one decoder.In hybrid retransmission, the transmitting side encodes one encoder and retransmits the same packet, and the receiving side compares the previously decoded result with the currently received codeword to signal ratio. This is a method of multiplying the weighting by and adding the result to the decoder to decode.

In the present invention, the accuracy of decoding can be improved by exchanging information between two LDPC code decoders and decoding using more information than when using one LDPC code decoder.

An apparatus for encoding a hybrid retransmission system using an LDPC code according to an aspect of the present invention for achieving the above object,

A first LDPC code encoder for performing LDPC encoding on input information data and transmitting the same to the decoding apparatus; An interleaver for interleaving and inputting the input information data; And a second LDPC code encoder positioned in parallel with the first LDPC code encoder with respect to the input information data, and performing LDPC encoding on the input information data interleaved by the interleaver to transmit to the decoding apparatus. The first LDPC code encoder transmits its output to the decoding device in odd-numbered transmission of the input information data according to the retransmission request from the decoding device, and the second LDPC code encoder requests a retransmission from the decoding device. It is preferable to transmit its output to the decoding apparatus according to the even transmission of the input information data.

The encoding apparatus may further include an encoding control unit configured to control the first LDPC code encoder for odd-numbered transmissions and to control the second LDPC code encoder for even-numbered transmissions when retransmission is requested from the decoding apparatus. do.

Further, it is preferable that the first LDPC code encoder and the second LDPC code encoder have the same generation matrix and parity check matrix.

In addition, it is preferable that the first LDPC code encoder and the second LDPC code encoder perform retransmission according to a chase combining method for the retransmission request of the decoding apparatus.

Decoding apparatus of a hybrid retransmission system using an LDPC code according to another feature of the present invention,

A first LDPC code decoder and a second LDPC code decoder for performing LDPC decoding on an LDPC coded codeword transmitted from the encoding apparatus; An interleaver for interleaving the result data decoded by the first code decoder and outputting the interleaved result data to the second LDPC code decoder; And a deinterleaver for deinterleaving the result data decoded by the second LDPC code decoder and outputting the deinterleaved data to the first LDPC code decoder, wherein the first LDPC code decoder is an LDPC coded codeword newly transmitted from the encoding apparatus. And perform LDPC decoding on an odd-numbered LDPC coded codeword by the encoding apparatus due to a transmission error, and the second LDPC code decoder performs LDPC-encoded even-numbered retransmission by the encoding apparatus due to a transmission error. LDPC decoding of a codeword, and the final output of the LDPC coded codeword newly transmitted from the encoding apparatus is output from the first LDPC code decoder, and is retransmitted by the encoding apparatus due to the transmission error. The final output for the codeword is preferably output from the deinterleaver. The.

The decoding device may include a CRC checker configured to perform a CRC check on the result data decoded by the first LDPC code decoder and the second LDPC code decoder; And determining whether to decode success / failure according to the CRC check performed by the CRC checker, and transmitting the decoding success / failure to the encoding device, and transmitting a codeword newly transmitted or retransmitted from the encoding device to the first LDPC code decoder and the second LDPC. The apparatus may further include a decoding controller configured to control the code decoder to perform decoding.

The first LDPC code decoder may use result data output from the deinterleaver during LDPC decoding of the odd-numbered retransmitted LDPC coded codeword.

The second LDPC code decoder may use result data output from the interleaver during LDPC decoding on the even-numbered retransmitted LDPC coded codeword.

In addition, when retransmission is requested due to a CRC check failure on the result data decoded by the first LDPC code decoder, an even-numbered LDPC coded codeword is retransmitted from the encoding apparatus and received by the second LDPC code decoder. desirable.

In addition, when retransmission is requested due to a CRC check failure on the result data decoded by the second LDPC code decoder, an odd-numbered LDPC coded codeword is retransmitted from the encoding apparatus and received by the first LDPC code decoder. desirable.

An encoding apparatus of a hybrid retransmission system using an LDPC code according to another aspect of the present invention,

A first LDPC code encoder for performing LDPC encoding on input information data and transmitting the same to the decoding apparatus; An interleaver for interleaving and outputting the LDPC coded data by the first LDPC code encoder; And a second LDPC code encoder serially connected to the first LDPC code encoder with respect to the input information data, and performing LDPC encoding on the result data interleaved by the interleaver to transmit the LDPC code encoder to the decoding apparatus. The first LDPC code encoder transmits its output to the decoding device in odd-numbered transmission of the input information data according to the retransmission request from the decoding device, and the second LDPC code encoder is adapted to the retransmission request from the decoding device. Accordingly, it is preferable to transmit its output to the decoding apparatus by the even-numbered transmission of the input information data, and the final output of the LDPC coded codeword transmitted by the encoding apparatus is output by the first LDPC code decoder.

Decoding apparatus of a hybrid retransmission system using an LDPC code according to another aspect of the present invention,

A first LDPC code decoder and a second LDPC code decoder for performing LDPC decoding on an LDPC coded codeword transmitted from the encoding apparatus; An interleaver for interleaving the result data decoded by the first code decoder and outputting the interleaved result data to the second LDPC code decoder; And a deinterleaver for deinterleaving the result data decoded by the second LDPC code decoder and outputting the deinterleaved data to the first LDPC code decoder, wherein the first LDPC code decoder is newly transmitted from the encoding apparatus. LDPC decoding for odd-numbered LDPC coded codewords in the encoding apparatus due to an error and a transmission error, and the second LDPC code decoder performs an LDPC encoding in even-numbered retransmissions in the encoding apparatus due to a transmission error. It is preferable to perform LDPC decoding on the codeword.

Here, it is preferable that retransmission due to a transmission error is requested to the encoding apparatus when a CRC check fails on the result data decoded by the first LDPC code decoder.

Further, when the CRC check fails for the result data decoded by the first LDPC code decoder for an odd numbered LDPC coded codeword from the encoding apparatus due to the transmission error, the first LDPC code decoder Preferably, the decoded result data is repeatedly decoded using the interleaver, the second LDPC code decoder, the deinterleaver, and the first LDPC code decoder.

Further, the LDPC coded codeword retransmitted evenly from the encoding apparatus due to the transmission error is decoded by the second LDPC code decoder and then decoded by the first LDPC code decoder through the deinterleaver. When the CRC check on the result data fails, it is preferable to repeatedly decode the result data decoded by the first LDPC code decoder by using the interleaver, the second LDPC code decoder, the deinterleaver, and the first LDPC code decoder. Do.

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. Like parts are designated by like reference numerals throughout the specification.

First, an encoding apparatus and a decoding apparatus using an LDPC code in a hybrid retransmission system according to an embodiment of the present invention will be described in detail with reference to the drawings.

2 is a block diagram of an encoding apparatus 100 and a decoding apparatus 200 using LDPC codes in a hybrid retransmission system according to an embodiment of the present invention.

The encoding apparatus 100 includes an interleaver 110, an LDPC code encoder 1 120, and an LDPC code encoder 2 130.

The LDPC code encoder 1 120 performs LDPC encoding on the information signal and outputs an LDPC encoded signal.

Such LDPC code encoder 1 (120) includes Thomas J. Richardson and M. Amin Shokrollahi et al., "Design of Capacity-Approaching Irregular Low-Density Parity-Check Codes" (IEEE TRANSACTIONS ON INFORMATION THEORY, VOL. 47, NO.2, The LDPC encoder disclosed in FEBRUARY 2001 may be used.

The interleaver 110 interleaves the information signal and outputs the interleaved information signal to the LDPC code encoder 2 130. As the interleaver 110, a conventionally known interleaver may be used. For example, a random interleaver or a turbo internal interleaver and a block interleaver used in the 3GPP TS 25.212 WCDMA physical layer standard may be used.

The LDPC code encoder 2 130 performs LDPC encoding on the signal output from the interleaver 110 to output the LDPC coded signal. The LDPC code encoder 2 130 may also use the encoder described with reference to the LDPC code encoder 1 120.

LDPC code encoder 1 120 and LDPC code encoder 2 130 are arranged in parallel with respect to the information signal.

As such, when the two encoders 120 and 130 are arranged in parallel, when the two encoders 120 and 130 are equally used, that is, the two encoders 120 and 130 have the same LDPC encoding for the same information signal input. In this case, the decoding apparatus 200 uses two decoders that perform the same LDPC decoding, so that it is possible to implement one encoder and a decoder in the implementation. Improves the signal recovery capability.

The LDPC code encoder 1 120 is represented by a generation matrix G (G = G _{i, j} = 1/0) or a check matrix, and the input information signal I (I = I ₀ , I ₁ , I ₂ , ..., I _k ) And output I · G = C (C is a codeword), or if the parity check matrix H (H = H _{i, j} = 1/0) is a matrix of lower triangular form or similar, Set the relation between I and H to satisfy C · H = 0, perform the operation, and output the codeword C.

The parity check matrix H may be divided into a case in which the number of 1s in a row and a column is regular as shown in Equation 1 below and a case where an irregularity is shown as in Equation 2 below. Regular cases are called regular LDPC codes, and irregular cases are called irregular LDPC codes. In the embodiment of the present invention, the normal LDPC code and the non-normal LDPC code may be used.

[Equation 1]

[Equation 2]

The error correction capability of the LDPC code is determined by the parity check matrix H, which is mostly composed of 0 (Low Density) and rarely (sparse) 1. The number of 1s in the rows and columns is called the degree distribution. The performance changes according to the order distribution, so an optimization process is required. The performance of LDPC code encoder is further improved by encoding with information about parity check matrix H optimized according to code rate and length of code word.

The LDPC code encoder 2 130 operates in the same manner as the above-described LDPC code encoder 1 120 except that an output signal interleaved with the input information signal I is input through the interleaver 110 and LDPC encoded. Omit.

The LDPC code encoder 1 120 encodes a new information signal or encodes the same information signal and transmits the same information signal to the decoding apparatus 200 when an odd-numbered retransmission request is received from the decoding apparatus 200.

On the other hand, the LDPC code encoder 2 130 encodes an output signal of the interleaver 110 and transmits the encoded output signal to the decoding device 200 when an even-numbered retransmission request is received from the decoding device 200.

Meanwhile, the decoding apparatus 200 includes an LDPC code decoder 1 210, an interleaver 220, a deinterleaver 230, and an LDPC code decoder 2 240.

The LDPC code decoder 1 210 performs LDPC decoding on a code word transmitted and received from the encoding apparatus 100. At this time, the codeword re-transmitted by an odd number of times by the retransmission request is used together with the data output from the deinterleaver 230 to perform encoding. The LDPC code decoder 1 210 performs decoding corresponding to the encoding performed by the LDPC encoder 1 120. The design of Capacity-Approaching Irregular Low-Density of Thomas J. Richardson and M. Amin Shokrollahi et al. Parity-Check Codes "(IEEE TRANSACTIONS ON INFORMATION THEORY, VOL. 47, NO.2, FEBRUARY 2001) may be used.

The interleaver 220 interleaves and outputs the data decoded by the LDPC code decoder 1 210. Like the interleaver 110 of the encoding apparatus 100, the interleaver 220 uses a random interleaver or a 3GPP TS 25.212 WCDMA physical layer standard. Internal interleaver, block interleaver, etc. may be used.

The LDPC code decoder 2 240 performs LDPC decoding on the even-numbered retransmitted codeword by using the signal output from the interleaver 220. The LDPC code decoder 2 240 may also use the decoder described with reference to the LDPC code decoder 1 210.

The deinterleaver 230 deinterleaves the data output from the LDPC code decoder 2 240 and outputs the data to the LDPC code decoder 1 210.

The deinterleaver 230 is determined by the interleavers 110 and 220. As described above, a deinterleaver corresponding to a random interleaver or a turbo internal interleaver or a block interleaver used in the 3GPP TS 25.212 WCDMA physical layer standard may be used. have.

Meanwhile, the decoding apparatus 200 may further include CRC checking means for determining whether the decoding succeeds or fails by performing CRC checking on the result data decoded by the LDPC code decoder 1 210 and the LDPC code decoder 2 240. Can be. Such CRC test means is well known and will be easily understood by those skilled in the art, and thus detailed description thereof will be omitted. The CRC checking means determines whether the decoding succeeds / fails as a result of the decoding, and then transfers it to the encoding apparatus 100 as a signal of ACK (decoding success) / NCK (decoding failure).

The encoding apparatus 100 receives an ACK / NCK signal indicating decoding success / failure transmitted from the decoding apparatus 200 and determines whether to retransmit, and if retransmission is required, depending on whether the transmission is odd or even. Encoding control means for controlling the LDPC code encoder 1 (120) and LDPC code encoder 2 (130) to perform retransmission.

In addition, the decoding apparatus 200 also includes decoding control means for controlling the codeword newly transmitted or retransmitted from the encoding apparatus 100 to be received and decoded by the LDPC code decoder 1 210 and the LDPC code decoder 2 240. can do.

Hereinafter, operations of an encoding device and a decoding device using an LDPC code in a hybrid retransmission system according to an embodiment of the present invention will be described.

First, the encoding apparatus 100 on the transmission side encodes an information signal to be transmitted using the LDPC code encoder 1 120 and transmits the encoded information signal to the decoding apparatus 200 on the receiving side.

If the ACK signal corresponding to the decoding success is transmitted from the decoding device 200, the encoding device 100 inputs a new information signal to the LDPC code encoder 1 (120) and repeats the above transmission.

However, when the NCK signal is transmitted from the decoding apparatus 200 due to a transmission error or the like, and retransmission is requested, the LDPC code encoder 2 after interleaving the first transmitted information signal to the interleaver 110 when the second or even numbered retransmission is requested. The codeword generated by encoding at 130 is retransmitted to the decoding apparatus 200. If the odd-numbered retransmission is performed, the codeword generated by encoding the first transmitted information signal using the LDPC code encoder 1 120 is identically encoded. Transmit to decoding device 200.

On the other hand, when the decoding apparatus 200 on the receiving side is the first reception from the encoding apparatus 100, after decoding with the LDPC code decoder 1 210 and performing a CRC check based on the decoding result, the decoding success or failure is determined. The result of the decoding success failure is transmitted to the transmitting side as ACK (in case of success) / NCK (in case of failure). If it is determined that the decoding fails, the CRC check result stores the decoding result, and a specific storage device is required for such storage.

On the other hand, when the second codeword is received from the encoding apparatus 100 due to a decoding failure, the LDPC code decoder 2 240 decodes the first codeword received by the LDPC code decoder 1 210 as a result of the interleaver 220. Decoding is performed by using the interleaved result data together with the second received codeword. The CRC check means also performs CRC check on the result data decoded by the LDPC code decoder 2 240 to determine the decoding success or failure, and requests retransmission to the encoding apparatus 100 when the CRC check fails.

In the third and subsequent odd codeword reception, the LDPC code decoder 1 210 deinterleaves the result data of the even-numbered received codeword into the LDPC code decoder 2 240 before deinterleaving the data into the deinterleaver 230. Decoding is performed using the result data together with the odd-numbered received codewords. Similarly, after the CRC check is performed as the decoded result, it is determined whether the decoding succeeds or fails, and if necessary, a retransmission request is transmitted to the encoding apparatus 100.

In the fourth and subsequent even-numbered receptions, the LDPC code decoder 2 240 interleaves the result data decoded by the LDPC code decoder 1 210 into the interleaver 220 with the odd-numbered received codeword before. Decoding is performed using the even-numbered received codewords together. Similarly, after the CRC check is performed as the decoded result, it is determined whether the decoding succeeds or fails, and if necessary, a retransmission request is transmitted to the encoding apparatus 100.

Here, the final output of the first received codeword is output from the LDPC code decoder 1 210, and the final output of the second and subsequent received codewords is output from the deinterleaver 230.

As described above, in the embodiment of the present invention, two LDPC code encoders 120 and 130 are used. When retransmission, the result encoded by the LDPC code encoder 120 is retransmitted to an odd number, and the LDPC code encoder 130 is used. The result encoded by is retransmitted to an even number.

In the case of the turbo code described with reference to FIG. 1, two encoders are used, but in the case of the turbo code, the encoding device transmits the result encoded by the two encoders to the decoding device at the same time in the first transmission. There is a difference.

3 is a block diagram of an encoding apparatus 300 and a decoding apparatus 400 using LDPC codes in a hybrid retransmission system according to a second embodiment of the present invention.

The encoding apparatus 300 includes an LDPC code encoder 1 310, an interleaver 320, and an LDPC code encoder 2 330.

The LDPC code encoder 1 310 performs LDPC encoding on the information signal and outputs an LDPC encoded signal.

As described above, the LDPC code encoder 1 310 is described in Thomas J. Richardson and M. Amin Shokrollahi et al. "Design of Capacity-Approaching Irregular Low-Density Parity-Check Codes" (IEEE TRANSACTIONS ON INFORMATION THEORY, VOL. 47 , NO.2, FEBRUARY 2001) may be used.

The interleaver 320 interleaves the codeword encoded by the LDPC code encoder 1 310 and outputs the interleaved codeword to the LDPC code encoder 2 330. As the interleaver 320, a turbo interleaver, a block interleaver, or the like used in the random interleaver or the 3GPP TS 25.212 WCDMA physical layer standard may be used as described above.

The LDPC code encoder 2 330 performs LDPC encoding on the signal output from the interleaver 310 to output the LDPC coded signal. The LDPC code encoder 2 330 may also use the encoder described with reference to the LDPC code encoder 1 310.

On the other hand, LDPC code encoder 1 310 and LDPC code encoder 2 330 are arranged in series with the information signal. That is, they are arranged continuously.

The LDPC code encoder 1 310 encodes a new information signal or encodes the same information signal and transmits the same information signal to the decoding apparatus 400 when an odd-numbered retransmission request is received from the decoding apparatus 400.

On the other hand, the LDPC code encoder 2 330 encodes an output signal of the interleaver 320 and transmits it to the decoding device 400 when an even-numbered retransmission request is received from the decoding device 400. In this case, the output of the interleaver 320 is different from that of the first embodiment of the present invention in that the codewords encoded in advance by the LDPC code encoder 1 310 are interleaved. 400 also applies.

Meanwhile, the decoding apparatus 400 includes an LDPC code decoder 1 440, an interleaver 430, a deinterleaver 420, and an LDPC code decoder 2 410.

The LDPC code decoder 1 440 performs LDPC decoding on the LDPC coded codeword transmitted from the encoding apparatus 300. At this time, the codeword re-transmitted by the odd number of times by the retransmission request is used together with the data output from the deinterleaver 420 to perform encoding. The LDPC code decoder 1 440 performs decoding corresponding to the encoding performed by the LDPC encoder 1 310. The design of Capacity-Approaching Irregular Low-Density of Thomas J. Richardson and M. Amin Shokrollahi et al. Parity-Check Codes "(IEEE TRANSACTIONS ON INFORMATION THEORY, VOL. 47, NO.2, FEBRUARY 2001) may be used.

The interleaver 430 interleaves and outputs the data decoded by the LDPC code decoder 1 440. Like the interleaver 320 of the encoding apparatus 300, the interleaver 430 uses a random interleaver or a turbo used in the 3GPP TS 25.212 WCDMA physical layer standard. Internal interleaver, block interleaver, etc. may be used.

The LDPC code decoder 2 410 performs LDPC decoding on the even-numbered retransmitted codeword by using the signal output from the interleaver 430. The decoder described with reference to LDPC code decoder 1 440 may also be used as the LDPC code decoder 2 410.

The deinterleaver 420 deinterleaves the data output from the LDPC code decoder 2 410 and outputs the data to the LDPC code decoder 1 440.

The deinterleaver 420 is determined by the interleavers 320 and 430. As described above, a deinterleaver corresponding to a random interleaver or a turbo internal interleaver or a block interleaver used in the 3GPP TS 25.212 WCDMA physical layer standard may be used. have.

Meanwhile, the decoding apparatus 400 may further include CRC checking means for determining whether the decoding succeeds or fails by performing a CRC check on the result data decoded by the LDPC code decoder 1 440. Such CRC test means is well known and will be easily understood by those skilled in the art, and thus detailed description thereof will be omitted. The CRC checking means determines whether the decoding succeeds / fails as a result of the decoding, and then transfers it to the encoding apparatus 300 as a signal of ACK (decoding success) / NCK (decoding failure).

In addition, the encoding apparatus 300 receives an ACK / NCK signal indicating decoding success / failure transmitted from the decoding apparatus 400, and determines whether to retransmit, and whether retransmission is an odd or even transmission. According to the control, the LDPC code encoder 1 310 and the LDPC code encoder 2 330 may include encoding control means for performing retransmission.

In addition, the decoding apparatus 400 also includes decoding control means for controlling a codeword newly transmitted or retransmitted from the encoding apparatus 300 to be received and decoded by the LDPC code decoder 1 440 and the LDPC code decoder 2 410. can do.

In the decoding device 400 according to the second embodiment of the present invention, the LDPC code encoder 1 310 and the LDPC code encoder 2 330 of the encoding device 300 are disposed in series with the interleaver 320 interposed therebetween. As a result, the result data decoded by the LDPC code decoder 1 440 becomes the final output signal. Therefore, in the first embodiment of the present invention, the CRC check means performs CRC check on the result data of the LDPC code decoder 1 210 and the result data of the LDPC code decoder 2 240 to determine whether the decoding succeeds or fails. However, in the second embodiment of the present invention, the CRC check means performs CRC check only on the result data of the LDPC code decoder 1 440 to determine whether the decoding succeeds or fails.

In addition, when it is determined that the CRC check result decoding fails with respect to the result data decoded for the codeword retransmitted from the encoding apparatus 300, the deinterleaver 430 does not transmit the determination result to the encoding apparatus 300. Repeat decoding is performed several times through the LDPC code decoder 2 410, the deinterleaver 420, and the LDPC code decoder 1 440.

Hereinafter, operations of the encoding apparatus and the decoding apparatus using the LDPC code in the hybrid retransmission system according to the second embodiment of the present invention will be described.

First, the encoding apparatus 300 on the transmission side encodes an information signal to be transmitted using the LDPC code encoder 1 310 and transmits the encoded information signal to the decoding apparatus 400 on the receiving side.

If the ACK signal corresponding to the decoding success is transmitted from the decoding device 400, the encoding device 300 inputs a new information signal to the LDPC code encoder 1 310 and repeats the above transmission.

However, when the NCK signal is transmitted from the decoding apparatus 400 due to a transmission error or the like and retransmission is requested, the interleaver 320 encodes the codeword encoded by the LDPC code encoder 1 310 when the second and subsequent even retransmissions are requested. After interleaving with the LDPC code encoder 2 330, the codeword generated by recoding is retransmitted to the decoding apparatus 400. If the odd number is retransmission, the first transmitted information signal is the same using the LDPC code encoder 1 310. The codeword generated by encoding the data is transmitted to the decoding apparatus 400.

On the other hand, the decoding apparatus 400 on the receiving side is the first reception from the encoding apparatus 300, iteratively decodes the LDPC code decoder 1 440 and performs a CRC check with the decoding result to determine the decoding success or failure The result of the decoding success failure is transmitted to the transmitting side as ACK (in case of success) / NCK (in case of failure). If it is determined that the decoding fails, the CRC check result stores the decoding result, and a specific storage device is required for such storage.

On the other hand, when a second codeword is received from the encoding apparatus 300 due to a decoding failure, the LDPC code decoder 2 410 decodes the codeword first received by the LDPC code decoder 1 440 to interleaver 430. After the interleaved result data and the second received codeword are combined to perform repeated decoding, the result data is deinterleaved through the deinterleaver 420 and input to the LDPC code decoder 1 440. The LDPC code decoder 1 440 performs iterative decoding by using the decoded result data input from the deinterleaver 420 together with the first received codeword, and performs CRC check with the decoding result to determine whether the decoding succeeds or fails. After the determination, if it is determined that the decoding is successful, the signal is transmitted to the transmitting side as an ACK signal (if successful).

However, when decoding is determined to be unsuccessful, the result data of LDPC code decoder 1 440 is interleaved through interleaver 430, inputted to LDPC code decoder 2 410, and repeatedly decoded, and the result is deinterleaver. Deinterleaving through 420 is input to LDPC code decoder 1 440 for repeated decoding. After that, CRC check is performed again to determine whether the decoding succeeds / fails, and when it is determined to be successful, it is transmitted to the encoding apparatus 300 as an ACK signal, and if the failure is determined, the above decoding is repeated again. . If the result after the specified number of times of repeated decoding is determined to be a decoding failure, a NAK signal indicating the failure is transmitted to the encoding apparatus 300 so that further retransmission may be performed.

In summary, in the case of odd-numbered reception in the decoding apparatus 400, the LDPC code decoder 1 440 performs iterative decoding by using the decoding output of the even-numbered codeword previously received and the currently received odd-numbered received codeword together. If decoding fails, the LDPC code decoder 2 410 and the LDPC code decoder 1 440 perform repetitive decoding with a specific number of times between the interleaver 430 and the deinterleaver 420.

On the other hand, in the case of even-numbered reception in the decoding apparatus 400, the LDPC code decoder 2 410 decodes using the even-numbered received codeword currently received, and uses the result together with the previous odd-numbered decoding result to perform LDPC. The code decoder 1 440 performs decoding. When the decoding failure is determined by the CRC check, the LDPC code decoder 2 410 and the LDPC code decoder 2 440 are repeatedly decoded with the interleaver 430 and the deinterleaver 420 interposed a certain number of times.

Although the present invention has been described with reference to the most practical and preferred embodiment, the present invention is not limited to the above-described embodiment, but also includes various modifications and equivalents falling within the scope of the following claims.

According to the present invention, since the LDPC code is used, the error flow phenomenon of the turbo code is alleviated, and the data throughput is increased by reducing the decoding time.

In addition, since encoding is performed by placing an interleaver between encoders of the LDPC code, decoder 1 and decoder 2 obtain and decode information from different neighboring symbols, thereby increasing the probability of recovering the distorted signals, thereby obtaining more coding gain. Therefore, packet data transmission efficiency can be improved.

Claims (20)

An encoding apparatus for encoding input information data using a Low Density Parity Check (LDPC) code in a hybrid retransmission system and transmitting the encoded information data to a decoding apparatus, A first LDPC code encoder for performing LDPC encoding on input information data and transmitting the same to the decoding apparatus; An interleaver for interleaving and inputting the input information data; And A second LDPC code encoder positioned in parallel with the first LDPC code encoder with respect to the input information data, and performing LDPC encoding on the input information data interleaved by the interleaver to be transmitted to the decoding apparatus; Including; The first LDPC code encoder transmits its output to the decoding device in odd-numbered transmission of the input information data according to a retransmission request from the decoding device, The second LDPC code encoder transmits its output to the decoding device in even-numbered transmission of the input information data according to a retransmission request from the decoding device. An apparatus for encoding a hybrid retransmission system using an LDPC code, characterized in that. The method of claim 1, When retransmission is requested from the decoding apparatus, the LDPC code further comprises an encoding control unit controlling the first LDPC code encoder for odd-numbered transmissions and controlling the second LDPC code encoder for even-numbered transmissions. Encoding device for hybrid retransmission system. The method according to claim 1 or 2, And the first LDPC code encoder and the second LDPC code encoder have the same generation matrix and parity check matrix. The method of claim 3, And a first LDPC code encoder and a second LDPC code encoder perform retransmission according to a chase combining method for the retransmission request of the decoding apparatus. In a decoding apparatus for receiving and decoding a codeword encoded using a Low Density Parity Check (LDPC) code from an encoding apparatus in a hybrid retransmission system, A first LDPC code decoder and a second LDPC code decoder for performing LDPC decoding on an LDPC coded codeword transmitted from the encoding apparatus; An interleaver for interleaving the result data decoded by the first code decoder and outputting the interleaved result data to the second LDPC code decoder; A deinterleaver for deinterleaving the result data decoded by the second LDPC code decoder and outputting the deinterleaved data to the first LDPC code decoder. Including; The first LDPC code decoder performs LDPC decoding on an LDPC coded codeword newly transmitted from the encoding apparatus and an LDPC coded codeword retransmitted oddly in the encoding apparatus due to a transmission error. The second LDPC code decoder performs LDPC decoding on an even-numbered LDPC coded codeword retransmitted by the encoding apparatus due to a transmission error, The final output for the LDPC coded codeword newly transmitted from the encoding apparatus is output from the first LDPC code decoder, The final output for the LDPC coded codeword retransmitted by the encoding apparatus due to the transmission error is output from the deinterleaver. Decoding apparatus of a hybrid retransmission system using an LDPC code, characterized in that. The method of claim 5, A CRC checker for performing a CRC check on the result data decoded by the first LDPC code decoder and the second LDPC code decoder; And Determining whether the decoding succeeds / fails according to the CRC check performed by the CRC checker, and transmits the decoding to the encoding device, and transmits a codeword newly transmitted or retransmitted from the encoding device to the first LDPC code decoder and the second LDPC code. Decoding control unit to control the decoder to receive and perform decoding Decoding apparatus of a hybrid retransmission system using the LDPC code further comprising. The method according to claim 5 or 6, And the first LDPC code decoder uses result data output from the deinterleaver during LDPC decoding on the odd-numbered retransmitted LDPC coded codeword. The method according to claim 5 or 6, And the second LDPC code decoder uses result data output from the interleaver during LDPC decoding of the even-numbered retransmitted LDPC coded codeword. The method according to claim 5 or 6, When retransmission is requested due to a CRC check failure on the result data decoded by the first LDPC code decoder, an even-numbered LDPC coded codeword is retransmitted from the encoding apparatus and received by the second LDPC code decoder. Decoding apparatus of a hybrid retransmission system using an LDPC code. The method according to claim 5 or 6, When retransmission is requested due to a CRC check failure on the result data decoded by the second LDPC code decoder, an odd-numbered LDPC coded codeword is retransmitted from the encoding apparatus and received by the first LDPC code decoder. Decoding apparatus of a hybrid retransmission system using an LDPC code. An encoding apparatus for encoding input information data using a Low Density Parity Check (LDPC) code in a hybrid retransmission system and transmitting the encoded information data to a decoding apparatus, A first LDPC code encoder for performing LDPC encoding on input information data and transmitting the same to the decoding apparatus; An interleaver for interleaving and outputting the LDPC coded data by the first LDPC code encoder; And A second LDPC code encoder connected in series with the interleaver and performing LDPC encoding on the result data interleaved by the interleaver to transmit to the decoding apparatus Including; The first LDPC code encoder transmits its output to the decoding device in odd-numbered transmission of the input information data according to a retransmission request from the decoding device, The second LDPC code encoder transmits its output to the decoding device in even-numbered transmission of the input information data according to a retransmission request from the decoding device. An apparatus for encoding a hybrid retransmission system using an LDPC code, characterized in that. The method of claim 11, When retransmission is requested from the decoding apparatus, the LDPC code further comprises an encoding control unit controlling the first LDPC code encoder for odd-numbered transmissions and controlling the second LDPC code encoder for even-numbered transmissions. Encoding device for hybrid retransmission system. The method according to claim 11 or 12, wherein And a first LDPC code encoder and a second LDPC code encoder perform retransmission according to a chase combining method for the retransmission request of the decoding apparatus. A decoding apparatus for receiving and decoding a codeword encoded using a Low Density Parity Check (LDPC) code from an encoding apparatus in a hybrid retransmission system, A first LDPC code decoder and a second LDPC code decoder for performing LDPC decoding on an LDPC coded codeword transmitted from the encoding apparatus; An interleaver for interleaving the result data decoded by the first code decoder and outputting the interleaved result data to the second LDPC code decoder; A deinterleaver for deinterleaving the result data decoded by the second LDPC code decoder and outputting the deinterleaved data to the first LDPC code decoder. Including; The first LDPC code decoder performs LDPC decoding on an LDPC coded codeword newly transmitted from the encoding apparatus and an LDPC coded codeword retransmitted oddly in the encoding apparatus due to a transmission error. The second LDPC code decoder performs LDPC decoding on an even-numbered LDPC coded codeword retransmitted by the encoding apparatus due to a transmission error. Decoding apparatus of a hybrid retransmission system using an LDPC code, characterized in that. The method of claim 14, A CRC checker for performing a CRC check on the result data decoded by the first LDPC code decoder; And Determining whether the decoding succeeds / fails according to the CRC check performed by the CRC checker, and transmits the decoding to the encoding device, and transmits a codeword newly transmitted or retransmitted from the encoding device to the first LDPC code decoder and the second LDPC code. Decoding control unit to control the decoder to receive and perform decoding Decoding apparatus of a hybrid retransmission system using the LDPC code further comprising. The method according to claim 14 or 15, And the first LDPC code decoder uses result data output from the deinterleaver during LDPC decoding on the odd-numbered retransmitted LDPC coded codeword. The method according to claim 14 or 15, And the second LDPC code decoder uses result data output from the interleaver during LDPC decoding of the even-numbered retransmitted LDPC coded codeword. The method according to claim 14 or 15, And a retransmission due to a transmission error is requested to the encoding device when a CRC check on the result data decoded by the first LDPC code decoder is failed. The method according to claim 14 or 15, Decoded by the first LDPC code decoder when the CRC check fails for the result data decoded by the first LDPC code decoder for the odd-numbered LDPC coded codeword retransmitted due to the transmission error And decoding the resultant data repeatedly by using the interleaver, the second LDPC code decoder, the deinterleaver, and the first LDPC code decoder. The method according to claim 14 or 15, Result data decoded by the second LDPC code decoder after the LDPC coded codeword retransmitted evenly from the encoding device due to the transmission error, and then decoded by the first LDPC code decoder through the deinterleaver If the CRC check fails for the result, the result data decoded by the first LDPC code decoder is repeatedly decoded using the interleaver, the second LDPC code decoder, the deinterleaver, and the first LDPC code decoder. Decoding apparatus of hybrid retransmission system using LDPC code.

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