JP3388035B2 - Data communication system, transmission apparatus and transmission method using hybrid automatic repeat request method - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a data communication system using a hybrid automatic repeat request (ARQ) system.

This hybrid ARQ system realizes highly reliable and highly efficient data communication, and is used for mobile communication, personal computer communication and the like.

[0003]

2. Description of the Related Art A hybrid ARQ system is a combination of an ARQ system and an FEC (Forward Error Correction) system.

The ARQ method is a method in which, when transmitting data through a communication path in which an error occurs, the receiving device detects an error in the data and requests the transmitting device to retransmit the data. Can be realized.

The FEC method is a method in which redundancy is added to transmission data and error correction is performed by a receiving device, and it is effective when the state of the communication path is unstable or in a bad environment. In the hybrid ARQ system, error detection coding and error correction coding are performed in advance (the detection and correction may be performed with the same code), and a frame is formed including information symbols and parity check symbols, and received. There is a type 1 that performs error correction and detection on the device side, and a type 2 that transmits a parity check symbol when there is a retransmission request from the receiving device side and performs error correction together with the previously transmitted information symbol. There is something called.

[0006]

Incidentally, the above-mentioned A
Throughput is used when evaluating the performance of the RQ scheme. Comparing the performances of the simple ARQ scheme and the hybrid ARQ scheme, the simple ARQ scheme can obtain high throughput when the characteristics of the communication channel are good, that is, when the error rate is low. If the number increases, the number of retransmissions increases sharply and there is a problem that the throughput deteriorates.

Since the hybrid ARQ system is provided with redundancy (parity check symbol) for error correction, the throughput when the error rate is low is lower than that of the simple ARQ system, but some errors are corrected by the FEC function. There is no need to resend because you can. But FE
When the error rate of the communication path is such that errors exceeding the correction capability of the C function occur frequently, there is still a problem that the throughput drops sharply.

Further, if the hybrid ARQ system in which the FEC function is further strengthened is used, it is possible to adapt even in a place where the characteristics of the communication channel are poor, but it is extremely difficult to change the FEC application method according to the characteristics of the communication channel. It is difficult to use because it is difficult.

The present invention has been made in view of the above circumstances, and is based on a hybrid automatic repeat request system capable of efficiently and properly performing error correction of transmission information in accordance with a deterioration state of characteristics of a communication path. It is intended to provide a data communication system.

[0010]

FIG. 1 shows the principle of the present invention. This figure is a principle diagram of a data communication system by a hybrid automatic repeat request system having a return path for requesting retransmission of data from the receiver 12 to the transmitter 11.

In the transmission device 11, 13 is a block forming means for dividing the transmission data D1 into a plurality of blocks. 14 is error detection data adding means,
Block data D2 output from the blocking means 13
Check data for error detection is added to.

Reference numeral 16 is an encoding means, which error-codes the block data D3 to which the check data is added, and the error-coded data is converted into a plurality of frame data n-.
It is divided into A, n-B, and n-C.

Reference numeral 17 is a number adding means for adding a block number (denoted by n) and a frame number (denoted by A, B, C) to a plurality of frame data n-A, n-B, n-C. Is.

Reference numeral 18 denotes a first storage means, which is a plurality of frame data n to which a block number and a frame number are added.
-A, n-B, n-C are stored. Reference numeral 19 denotes a first control means which controls the frame data n-A, n-B and n-C stored in the first storage means 18 in the order of block numbers and transmits them. NA indicating that there is an error in the received block data
Control for transmitting the frame data of the untransmitted frame number of the block number indicated by the NACK signal when receiving the CK signal, and transmitting the frame data of the next block number when receiving the ACK signal indicating that there is no error in the block data Is to do.

In the receiving device 12, numeral 23 is a number extracting means for extracting the block number and frame number of the frame data n-A, n-B, n-C sent from the transmitting device 11. .

A second storage means 24 stores the frame data n-A, n-B and n-C for each block number and frame number extracted by the number extraction means 23.

Reference numeral 25 is a decoding means, which is the second storage means 24.
Frame data n-A, n-B, n- read from
Decoding is performed at an encoding rate corresponding to the number of C frames.

Reference numeral 26 is an error detecting means, which is a decoding means 25.
The error detection is performed by the check data in the frame data n-A, n-B, and n-C decoded in.
Reference numeral 27 denotes a second control means, which controls the reading of the frame data n-A, n-B, n-C stored in the second storage means 24, and when no error is detected by the error detection means 26. The ACK signal is transmitted to and the NACK signal is transmitted when an error is detected. Also, the addition of check data for error detection
Error correction coding of the block data
Divide encoded data into multiple frame data
Encoding means and storage for storing the plurality of frame data
Means and a part of the frame data from the storage means
Read and send to receiving device, error in the frame data
A NACK signal indicating that there is
When the transmission is performed, the
The frame data is read from the storage means and the received data is received.
And a control means for transmitting to the communication device.
A communication device is provided. In addition, check for error detection
Error correction coding of block data with data
The error-correction-encoded data into multiple frames.
Dividing into data and the plurality of frame data
And storing the frame data in the storage means.
Part of the data is read from the storage means and transmitted to the receiving device
NACK indicating that the frame data has an error
When a signal is received from the receiving device, the storage means
The untransmitted frame data stored in
Reading from the storage means and transmitting to the receiving device
A transmission method is provided, which comprises:

[0019]

According to the present invention described above, when the received data has an error, the NA is controlled by the second control means 27.
The CK signal is transmitted to the first control means 19, whereby the first control means 19 transmits the other framed data of the data of the block number in which the error occurred, and the destination including the transmitted data. Since the data is decoded together with the erroneous data, it can be processed as a code whose coding rate changes depending on the number of retransmissions. As a result, the second transmission is performed after the first transmission and the second transmission is performed after the second transmission. The correction capability increases as the number of times increases, and a rapid increase in the number of times of retransmission due to deterioration of the characteristics of the communication path can be suppressed.

[0020]

Embodiments of the present invention will be described below with reference to the drawings. FIG. 2 is a block diagram of a data communication system using the hybrid automatic repeat request system according to the first embodiment of the present invention.

The data communication system shown in this figure is realized by a combination of a convolutional code and SW (Stop and Wait) -ARQ. In the figure, 11 is a transmitting device and 12 is a receiving device, and an antenna 2 is provided between both devices 11 and 12.
Wireless communication is performed via 0 and 22.

The transmission device 11 includes an information blocking unit 13
And a CRC (Cyclic Redundancy Check) encoder 14
, Tail bit adding section 15, and convolutional encoder 16
, Numbering unit 17, memory unit 18, SW-ARQ
The control unit 19 is included.

The receiving device 12 includes a number extracting unit 23, a memory unit 24, a Viterbi decoder 25, an error detecting unit 26,
The SW-ARQ control unit 27 is provided.
The information blocking unit 13 of the transmission device 11 includes the reception device 12
The information bit data D1 to be transmitted to is divided into 128-bit blocks, and the blocked information bit data D2 is output to the CRC encoding unit 14.

The CRC encoder 14 adds 16-bit parity check data for error detection by performing a CRC operation to the blocked information bit data D2, and the parity check data added 1
Convolutional encoder 1 with 44-bit information bit data D3
Output to 6.

When the information bit data D3 is input to the convolutional encoder 16, the tail bit adding unit 15 controls the addition of 3-bit "0" as a tail bit for converging the state of the convolutional code. That is, the convolutional encoder 16 is input with 147-bit data to which 3 tail bits are added.

The convolutional encoder 16 performs convolutional encoding for error correction, and has the configuration shown in FIG. 3, and the above 147-bit data D3 'is converted into three different frame data n. Output as -A, n-B, and n-C. However, each frame data n-A, n-B,
Each of nC has 147 bits.

As shown in FIG. 3, the convolutional encoder 16 has a constraint length of "4", and three flip-flops (FF) 31 for sequentially holding and shifting the data D3 '.
An exclusive OR circuit (EO) which takes the exclusive OR of 32 and 33, the data D3 'and the output data of the FFs 31 and 33 and outputs them as the first frame data nA.
R circuit) 34, an EOR circuit 35 for taking the exclusive OR of the data D3 'and the output data of the FFs 32 and 33 and outputting it as the second frame data n-B, the output data of the FF 31 and the EOR circuit 35. And an EOR circuit 36 that takes the exclusive OR of the output frame data n-B and outputs it as the third frame data n-C.

The number adding unit 17 shown in FIG. 2 is a frame data n-A, n-output from the convolutional encoder 16.
A process of assigning a block number and a frame number to B and nC is performed. Here, n of each frame data is a block number, and A, B, and C are frame data. However,
It is assumed that n = 1, 2, 3, ...

That is, when the first blocked information bit data D2 blocked by the information blocking unit 13 is framed by the convolutional encoder 16, the frame data includes 1-A, 1-B, Numbered 1-C,
The frame data when the second blocked information bit data D2 is framed includes 2-A, 2-B, 2
-C numbered.

The frame data n-A, n-B, and n-C in which the block number-frame number are added in this way are
It is stored in the memory unit 18. SW-ARQ control unit 19
Is the frame data n−A stored in the memory unit 18,
n-B and n-C are sequentially read in the order of block number-frame number, and the SW-ARQ control unit 27 of the receiving device 12 is also read.
Frame data n-A, n-B, n-C according to the response of
Control to read. A detailed description of this control will be given in the description of the automatic retransmission request control operation described later.

The frame data n-A, n-B, and n-C read from the memory unit 18 are modulated with a radio frequency signal by a transmitter (not shown) and transmitted from the antenna 20, and further the receiving device 12 receives. The signal is received by the antenna 22 and demodulated by a receiver (not shown).

The number extraction unit 23 extracts the block number-frame number of the demodulated frame data n-A, n-B, n-C. Frame data n-A, n-B, n-C for each of the extracted block number-frame number
Are stored in the memory unit 24.

The Viterbi decoder 25 receives the convolutionally encoded frame data n sequentially read from the memory unit 24.
Decoding of -A, n-B and n-C is performed by Viterbi decoding calculation.

The error detector 26 detects an error in the information bit data in the decoded frame data n-A, n-B, n-C by CRC calculation. SW-ARQ control unit 27
When an error is detected by the error detection unit 26, the automatic transmission request is sent to the SW-ARQ control unit 19 of the transmission device 11, and the frame data n via the number extraction unit 23 is sent.
-A, n-B, and n-C are written and stored in the memory unit 24, and read out is controlled. A detailed description of this control will be given in the description of the automatic retransmission request control operation described later.

Next, the automatic repeat request control operation of the first embodiment will be described with reference to FIG. First, the SW of the receiving device 11
-Under the control of the ARQ control unit 19, the two frame data 1-A and 1-B of the first block indicated by reference numerals 38 and 39 in FIG. 4 are read from the memory unit 18 and transmitted to the receiving device 12 as indicated by the solid arrow. To do.

This transmitted frame data 1-A, 1
-B is received by the antenna 22, and the number extraction unit 2
The block number-frame number is extracted in 3 and stored in the memory unit 24 as indicated by reference numerals 40 and 41 for each of the extracted numbers.

This stored frame data 1-A, 1
-B is read from the memory unit 24 and input to the Viterbi decoder 25 under the control of the SW-ARQ control unit 27,
It is decrypted here. That is, the convolutional code is decoded. At this time, the information bit data D4 is decoded as a code having a coding rate of 1/2, and the Viterbi decoder 25 outputs the information bit data D4 to which the parity check data is added. The information bit data D4 is input to the error detection unit 26, where the CRC calculation using the parity check data is performed to perform error detection.

As a result, if no error is detected, the SW-ARQ control unit 27 indicates 1-ACK (Acknowledgment) indicating that the data of the first block has no error.
As shown by the broken line arrow in FIG.
-Transmit to the ARQ control unit 19. This is indicated by a dashed arrow 42 in FIG. Further, the SW-ARQ control unit 27 receives the frame data 1-A, 1-B from the memory unit 24.
Erase.

When no error is detected, the error detecting unit 26 outputs the first block of information bit data D5 which is the same as the information block forming unit 13 of the transmitter 11.

Upon receiving the 1-ACK signal, the SW-ARQ control unit 19 receives from the memory unit 18 the frame data 2-A and 2-B of the next second block indicated by reference numerals 43 and 44 in FIG.
Is read out and transmitted to the receiving device 12.

This transmitted frame data 2-A, 2
In the case of -B, the block number-frame number is extracted by the number extracting unit 23, and reference numerals 45 and 4 are provided for each of the extracted numbers.
It is stored in the memory unit 24 as indicated by 6.

This stored frame data 2-A, 2
-B is decoded by the Viterbi decoder 25 as a code having a coding rate of 1/2, and the error detection unit 26 performs error detection. As a result, if an error is detected, SW-AR
The Q control unit 27 performs control to store the frame data 2-A and 2-B as they are, and 2-NACK (Negative Ackn) indicating that the data of the second block is erroneous.
The owledgment) signal is transmitted to the SW-ARQ control unit 19 of the transmission device 11 as indicated by a dashed arrow 47 in FIG.

SW-ARQ receiving 2-NACK signal
The control unit 19 reads from the memory unit 18 the frame data 2-C of the different frame of the second block, which has been previously transmitted and is denoted by reference numeral 48 in FIG. 4, and transmits it to the receiving device 12.

The transmitted frame data 2-C is
The block number-frame number is extracted by the number extraction unit 23, and is stored in the memory unit 24 as 2-C frame data as indicated by reference numeral 49.

This stored frame data 2-C is
Together with the previously stored frame data 2-A, 2-B,
It is read out under the control of the SW-ARQ control unit 27, and is decoded by the Viterbi decoder 25 as a code having a coding rate of 1/3. That is, the correction capability is higher than that when decoding was performed using the previous frame data 2-A and 2-B.

The error detection unit 2 is determined by the parity check data added to the decoded information bit data D4.
6 performs error detection, and if no error is detected as a result, the SW-ARQ control unit 27 sends a 2-ACK signal indicating that there is no error in the data of the second block to the dashed arrow 50 in FIG. As shown in FIG.
The frame data 2-A, 2-B, and 2-C are erased from the memory unit 24 while being transmitted to the ARQ control unit 19.

From the error detector 26, the transmitter 11
The information bit data D5 of the second block, which is the same as the information block forming unit 13 of FIG. Or later,
The SW-ARQ control unit 19 of the transmission device 11 responds to the ACK signal or the NACK signal returned from the SW-ARQ control unit 27 of the reception device 12, as described above, according to the memory unit 18.
The frame data 3-A ... Are sequentially read from and are transmitted to the receiving device 12.

By the way, as described above, the frame data 2-A, 2- decoded by the Viterbi decoder 25.
Assuming that an error is detected as a result of the error detection of B and 2-C, the SW-ARQ control unit 27 causes the frame data 2-A and
While controlling to store 2-B and 2-C as they are,
The 2-NACK signal indicating that the data of the second block is incorrect is transmitted to the SW-ARQ control unit 19 of the transmission device 11 again.

In this case, S receiving the 2-NACK signal
The W-ARQ control unit 19 reads the frame data 2-A of the first frame number of the second block from the memory unit 18 and transmits it to the receiving device 12.

The transmitted frame data 2-A is
After the block number-frame number is extracted by the number extracting unit 23, the memory unit 2 different from the previously stored 2-A
4 is read out under the control of the SW-ARQ control unit 27 together with the previously stored frame data 2-A, 2-B, 2-C. That is, four pieces of frame data are read out and input to the Viterbi decoder 25, whereby decoding can be performed as a code having a coding rate of 1/4.

As described above, since it is possible to decode as a code having a high correction capability each time retransmission is repeated, it is possible to avoid a rapid increase in the number of retransmissions, that is, a sharp decrease in throughput, even when the characteristics of the communication channel are poor.

As described above, when 2-A having the same code is used and a code having a longer constraint length is used, another data is stored in the memory unit (FF) of the convolutional encoder 16. It is better to use frame data obtained by calculation.

Next, a data communication system using the hybrid automatic repeat request system according to the second embodiment will be described with reference to FIG. However, in the second embodiment shown in FIG.
The same reference numerals are given to the portions corresponding to the respective portions of the first embodiment shown in, and the description thereof will be omitted.

The data communication system shown in FIG. 5 is realized by a combination of a convolutional code and GBN (Go-back-N) -ARQ. The second embodiment shown in FIG. 5 differs from the first embodiment shown in FIG. 2 in that the SW-ARQ shown in FIG.
As shown in FIG. 5, the control units 19 and 27 are set to GBN-ARQ.
The point is that the control units 53 and 54 are used.

GBN-ARQ control unit 5 of transmitter 11
3 and the automatic retransmission request control operation under the control of the GBN-ARQ control unit 54 of the reception device 12 will be described with reference to FIG. First, the GBN-ARQ control unit 53 of the transmission device 11
From the GBN-ARQ control unit 54 of the receiving device 12 to NA.
As long as the CK signal is not sent, the frame data 1-
.. are read in order from the first block number by two frames and transmitted to the receiving device 12.

The receiving device 12 sequentially extracts the frame data 1-A, 1-B, ...
Is stored for each block number-frame number and error detection is performed. That is, the first transmitted frame data 1-
As shown by reference numerals 58 and 59, A and 1-B are memory units 24.
And the stored frame data 1-A, 1
-B is read out under the control of the GBN-ARQ control unit 54, and is decoded by the Viterbi decoder 25 as a code having a coding rate of 1/2, whereby the information bit data D4 with the parity check data added is output. . This information bit data D4 is input to the error detection unit 26,
Here, error detection is performed by performing a CRC calculation using the parity check data.

As a result, if no error is detected, the GBN-ARQ control unit 54 sends a 1-ACK signal indicating that the data in the first block has no error to the transmitter 11 as indicated by the broken line arrow 60. The frame data 1-A and 1-B are erased from the memory unit 24 while being transmitted to the GBN-ARQ control unit 53.

When no error is detected, the error detecting unit 26 outputs the first block of information bit data D5 which is the same as the information block forming unit 13 of the transmitter 11.

On the other hand, the SW-ARQ control unit 19 is
Since the K signal has not been received, the frame data 4-A and 4-B of the next fourth block indicated by reference numerals 61 and 62 in FIG. 6 is read from the memory unit 18 and transmitted to the receiving device 12.

In the receiving device 12, the frame data 2-A, 2- of the second block after the first block is received.
B is stored in the memory section 24 as indicated by reference numerals 63 and 64, and its error detection is performed.

If an error is detected in the frame data 2-A, 2-B, the GBN-ARQ control unit 54 performs control to store the frame data 2-A, 2-B in the memory unit 24 as they are. The 2-NACK signal indicating that the data of the second block is erroneous is indicated by a broken line arrow 65, and the GBN-ARQ of the transmitter 11 is indicated.
It is transmitted to the control unit 53.

GBN-AR receiving 2-NACK signal
The Q control unit 53 reads from the memory unit 18 the frame data 2-C of the different frame of the second block, which has been transmitted previously, as indicated by reference numeral 66, and transmits it to the receiving device 12.

Further, the GBN-ARQ control unit 54 of the receiver 12 transmits the 2-NACK signal and at the same time,
-Waiting for the frame data 2-C of the second block related to the NACK signal to be transmitted, and the frame data 3-A and 3- shown by the broken line arrow 67 in FIG.
B, 4-A, and 4-B perform control to discard. That is, it is not stored in the memory unit 24.

When the frame data 2-C is transmitted, the GBN-ARQ control unit 54 sends it to the code 68.
It is stored in the memory unit 24 as indicated by. The stored frame data 2-C is read out together with the previously stored frame data 2-A and 2-B under the control of the GBN-ARQ control unit 54, and is encoded by the Viterbi decoder 25 at a coding rate 1 /. 3 code is decoded. That is, the correction capability is higher than that when decoding was performed using the previous frame data 2-A and 2-B.

The error detection unit 2 uses the parity check data added to the decoded information bit data D4.
6 performs error detection, and if no error is detected as a result, the GBN-ARQ control unit 54 sends a 2-ACK signal indicating that there is no error in the data of the second block to a broken line arrow 69 in FIG. GB of the transmitter 11 as shown in
While transmitting to the N-ARQ control unit 53, the memory unit 24
The frame data 2-A, 2-B, 2-C are erased from.

From the error detector 26, the transmitter 11
The information bit data D5 of the second block, which is the same as the information block forming unit 13 of FIG. on the other hand,
In the GBN-ARQ control unit 53 of the transmission device 11,
After transmitting the frame data 2-C indicated by reference numeral 66,
As long as the NACK signal is not transmitted, the frame data 3-A, 3-B of the third block onward of the second block indicated by reference numeral 70 are read out in the order of the block numbers and transmitted to the receiving device 12 two by two. .

By the way, as described above, the frame data 2-A, 2- decoded by the Viterbi decoder 25 is used.
If an error is detected as a result of the error detection of B and 2-C, the GBN-ARQ control unit 54 determines that the frame data 2-
While controlling to store A, 2-B, and 2-C as they are, a 2-NACK signal indicating that the data of the second block is erroneous is again sent to the GBN-ARQ of the transmitter 11.
It is transmitted to the control unit 53.

In this case, the G receiving the 2-NACK signal
The BN-ARQ control unit 53 reads the frame data 2-A of the first frame number of the second block from the memory unit 18 and transmits it to the receiving device 12.

The transmitted frame data 2-A is
The previously stored frame data 2-A, 2 stored in a storage area of the memory unit 24 different from the previously stored 2-A.
Together with -B and 2-C, they are read out by the control of the GBN-ARQ control unit 54 and input to the Viterbi decoder 25.
As a result, decoding can be performed as a code having a coding rate of 1/4.

As described above, since it is possible to decode as a code having a high correction capability each time retransmission is repeated, it is possible to avoid a rapid increase in the number of retransmissions, that is, a rapid decrease in throughput, even when the characteristics of the communication channel are poor.

Next, a data communication system using the hybrid automatic repeat request system according to the third embodiment will be described with reference to FIG. However, in the third embodiment shown in FIG.
The same reference numerals are given to the portions corresponding to the respective portions of the first embodiment shown in, and the description thereof will be omitted.

The data communication system shown in FIG. 7 is realized by a combination of a convolutional code and SR (Selective repeat) -ARQ. The third embodiment shown in FIG. 7 differs from the first embodiment shown in FIG. 2 in that the SW-A shown in FIG.
As shown in FIG. 7, the RQ control units 19 and 27 are set to the SR-AR.
The Q control units 72 and 73 are used, and the order changing circuit 74 is connected to the output side of the error detecting unit 26.

The SR-ARQ control unit 72 of the transmitter 11,
Also, an automatic retransmission request control operation under the control of the SR-ARQ control unit 73 of the receiving device 12 will be described with reference to FIG. First, the SR-ARQ control unit 72 of the transmitter 11 receives the reference numeral 7 in FIG. 8 from the memory unit 18 unless the NACK signal is sent from the SR-ARQ controller 73 of the receiver 12.
Frame data 1-A, 1-B
.. are read in sequence from the first block number by two frames and transmitted to the receiving device 12.

The receiving device 12 sequentially extracts the frame data 1-A, 1-B, ...
Is stored for each block number-frame number and error detection is performed. That is, the first transmitted frame data 1-
As shown by reference numerals 78 and 79, A and 1-B are memory units 24.
And the stored frame data 1-A, 1
-B is read out under the control of the SR-ARQ control unit 73 and is decoded by the Viterbi decoder 25 as a code having a coding rate of 1/2, whereby the information bit data D4 to which the parity check data is added is output. . The information bit data D4 is input to the error detection unit 26, where the CRC calculation using the parity check data is performed to perform error detection.

As a result, if no error is detected, the SR-ARQ control unit 73 sends a 1-ACK signal indicating that there is no error in the data of the first block to a broken line arrow 8
As shown by 0, the SR-ARQ control unit 72 of the transmission device 11
To the frame data 1 from the memory unit 24
-Delete A and 1-B.

When this error is not detected, the error detection unit 26 outputs the first block of the information bit data D5 which is the same as the information block forming unit 13 of the transmission device 11, and the information bit data D5 is input to the order permutation circuit 74 to obtain the information. It is output as bit data D6.

The order changing circuit 74 changes the input information bit data D5 in the order in which they are blocked by the information blocking section 13 and outputs this as information bit data D6.

This is because in the receiving device 12 of the system of the third embodiment, the error detecting section 26 does not output the information bit data D5 in the blocked order, so that the information bit data D5 is corrected in the correct order. What is not done is described later.

On the other hand, the SR-ARQ control section 72 determines the NAC
Since the K signal is not received, the frame data 4-A and 4-B of the next fourth block indicated by reference numerals 81 and 82 in FIG. 8 are read from the memory unit 18 and transmitted to the receiving device 12.

In the receiving device 12, the frame data 2-A, 2- of the second block after the first block is received.
B is stored in the memory unit 24 as indicated by reference numerals 83 and 84, and its error detection is performed.

If an error is detected in the frame data 2-A, 2-B, the SR-ARQ controller 7
3 controls to store the frame data 2-A and 2-B in the memory unit 24 as they are, and transmits a 2-NACK signal indicating that the data of the second block is erroneous as indicated by a dashed arrow 80. It is transmitted to the SR-ARQ control unit 72 of the device 11.

SR-ARQ receiving 2-NACK signal
The control unit 72 reads from the memory unit 18 the frame data 2-C of the different frame of the second block, which has been transmitted previously, as indicated by reference numeral 86, and transmits it to the receiving device 12.

After that, the SR-ARQ control unit 72
Frame data 4 indicated by reference numeral 82 read before reading frame data 2-C in response to reception of a NACK signal
The frame data 5-A of the block number next to -B, that is, the fifth block number indicated by reference numeral 87 is read and transmitted.

Originally, the frame data of the fifth block is sequentially read out for two frames, but here, the 3-NACK signal indicated by the broken line arrow 88, that is, the frame data 3 indicated by reference numerals 89 and 90 in the receiving device 12 is used. -A, 3-
The 3-NACK signal output in response to the B error detection is
If it is received by the SR-ARQ control unit 72, SR-
The ARQ control unit 72 controls the memory unit 18 to read out the frame data 3-C of the different frame of the third block, which is previously transmitted, as indicated by reference numeral 91, and to transmit the frame data 3-C to the receiving device 12.

After that, the SR-ARQ control unit 72 sets the 3-
Code 9 that could not be transmitted because the NACK signal was received
Another fifth frame data shown in 2-5
Send B.

In the receiving device 12, the frame data are processed in the order in which they are transmitted.
Error detection is performed on the frame data 4-A and 4-B indicated by, and if the result is good, 4-A indicated by a dashed arrow 95.
The CK signal is transmitted to the SR-ARQ control unit 72 of the transmitter 11.

Further, the frame data 4-with no error
The information bit data D5 of A, 4-B, that is, the block number of 4 is output from the error detection unit 26 to the order permutation circuit 74.

Since the order exchanging circuit 74 has only received the first information bit data D5 yet, when the fourth information bit data D5 after the first information bit data is inputted, the information bit data of the fifth block is received. Hold D5.

The information bit data D5 of the held fifth block is the information bit data D5 of the fourth block, which is output as the information bit data D6 and is then output.

On the other hand, the SR-ARQ control unit 72 uses the code 9
Frame data 5 of the 5th frame transmitted earlier indicated by 6
-Frame data 6-A after the sixth frame after B-
Are sequentially transmitted.

In the receiving device 12, reference numeral 93,
If the frame data 2-C indicated by reference numeral 97 is transmitted after the error detection of the frame data 4-A and 4-B indicated by 94, the SR-ARQ control unit 73 stores it in the memory unit 24, Frame data stored previously 2-
Read together with A and 2-B. The read three pieces of frame data 2-A, 2-B, and 2-C are decoded by the Viterbi decoder 25 as codes having a coding rate of 1/3.
That is, the correction capability is higher than that when decoding was performed using the previous frame data 2-A and 2-B.

The error detecting section 2 is determined by the parity check data added to the decoded information bit data D4.
If error detection is performed in No. 6, and as a result, no error is detected, the SR-ARQ control unit 73 sends a 2-ACK signal indicating that the data in the second block has no error in FIG. As shown in FIG.
The frame data 2-A, 2-B, 2-C is erased from the memory unit 24 while being transmitted to the ARQ control unit 72.

Further, the frame data 2 without the error
The information bit data D5 of A, 2-B, 2-C, that is, the second block is output from the error detection unit 26 to the order permutation circuit 74.

Since the order changing circuit 74 recognizes that the information bit data D5 of the first block has been output,
The information bit data D5 of the second block is output as the information bit data D6.

Next, assuming that the receiving apparatus 12 transmits the frame data 5-A indicated by the reference numeral 99 after the error detection of the frame data 2-C indicated by the reference numeral 97, S
The R-ARQ control unit 73 stores it in the memory unit 24. At this point, only one of the two pieces of frame data 5-A and 5-B to be subjected to error detection is used, and therefore the control for reading from the memory unit 24 is not performed.

After that, if the frame data 3-C indicated by reference numeral 100 is transmitted, the SR-ARQ control unit 73 stores it in the memory unit 24 and stores the previously stored frame data 3-A, Read with 3-B. These three read frame data 3-A, 3-B, 3-
C is decoded by the Viterbi decoder 25 as a code having a coding rate of 1/3, and the error detection unit 26 performs error detection. As a result, if an error is detected, SR-AR
The Q control unit 73 controls the frame data 3-A, 3-B, 3-C.
Is stored as it is, and the broken line arrow 101 indicating that the data of the third block is incorrect again
The 3-NACK signal is transmitted to the SR-ARQ control unit 72 of the transmitter 11.

In this case, the S receiving the 3-NACK signal
The R-ARQ control unit 72 receives the reference numeral 102 from the memory unit 18.
The frame data 3-A of the first frame number of the third block shown by is read and transmitted to the receiving device 12.

The transmitted frame data 3-A is
The previously stored frame data 3-A, 3 stored in a storage area of the memory unit 24 different from the previously stored 3-A is stored.
It is read by the control of the SR-ARQ control unit 73 together with -B and 3-C, and input to the Viterbi decoder 25. As a result, decoding can be performed as a code having a coding rate of 1/4.

As described above, since it is possible to decode as a code having a high correction capability each time retransmission is repeated, it is possible to avoid a rapid increase in the number of retransmissions, that is, a rapid decrease in throughput, even when the characteristics of the communication channel are poor.

According to the data communication system by the hybrid automatic repeat request system of the first to third embodiments described above, it is possible to process as a code whose coding rate changes according to the number of retransmissions, and as a result, the first transmission For example, the second time is the second time, and the second time is the third time.

As described above, in the first to third embodiments,
In the first transmission, the frame data nA from the transmitter 11 is transmitted.
And n-B are transmitted, and the receiving device 12 decodes as a 1/2 convolutional code, requests retransmission only when an error is detected, and performs compounding as 1/3, 1/4, ... Codes. I did it.

However, if the condition of the communication path is bad, 1
Even if a / 2 convolutional code is used, it is possible that an error cannot be corrected frequently by one retransmission. In such cases, i.e. NACKs are returned frequently,
Frame data n-A, n-B and n- from the first transmission
In some cases, it may be more effective to send C and decode it as a code with a coding rate of 1/3, and if there is an error, request frame data nA again to increase the correction capability. . That is, more efficient communication becomes possible by adaptively controlling the coding rate of the code sent in the first transmission according to the state of the communication path.

[0103]

As described above, according to the present invention,
There is an effect that the error correction of the transmission information can be efficiently and properly performed according to the deteriorated state of the characteristics of the communication path.

[Brief description of drawings]

FIG. 1 is a principle diagram of the present invention.

FIG. 2 is a block diagram of a data communication system based on a hybrid automatic repeat request system according to the first embodiment of the present invention.

FIG. 3 is a block diagram showing a configuration example of a convolutional encoder used in the transmission device in the data communication system of the embodiment.

FIG. 4 is a flowchart for explaining an automatic repeat request control operation in the first embodiment shown in FIG.

FIG. 5 is a block diagram of a data communication system using a hybrid automatic repeat request system according to a second embodiment of the present invention.

FIG. 6 is a flowchart for explaining an automatic repeat request control operation in the second embodiment shown in FIG.

FIG. 7 is a block diagram of a data communication system using a hybrid automatic repeat request system according to a third embodiment of the present invention.

8 is a flowchart for explaining an automatic repeat request control operation in the third embodiment shown in FIG.

[Explanation of symbols]

11 transmitter 12 Receiver 13 Blocking means 14 Error detection data adding means 16 Encoding means 17 Number addition means 18 First storage means 19 First control means 23 Number extraction means 24 Second storage means 25 Decoding means 26 Error detection means 27 Second control means

─────────────────────────────────────────────────── ─── Continuation of front page (58) Fields surveyed (Int.Cl. ⁷ , DB name) H04L 1/00 H04L 1/16

Claims (9)

(57) [Claims] 1. A data communication system according to a hybrid automatic repeat request system, comprising a feedback path for requesting a retransmission of data from a receiving device to a transmitting device, wherein said transmitting device comprises blocking means for dividing transmission data into a plurality of blocks. Error detection data adding means for adding check data for error detection to the block data output from the block forming means, error correction coding of the block data added with the check data, and this error correction coding Means for dividing the data into a plurality of frame data, a numbering means for adding a block number and a frame number to the plurality of frame data, and a plurality of numbers for adding a block number and a frame number to the plurality of frame data Storing means for storing the frame data of, and storing in the first storing means In the control for reading out and transmitting the frame data in the order of block numbers, when the NACK signal indicating that the block data transmitted from the receiving device has an error is received, the block number indicated by the NACK signal is not AC indicating that there is no error in the block data by transmitting the frame data of the transmission frame number
A first control means for controlling transmission of frame data of the next block number when receiving the K signal, and the receiving device, the block number of the frame data sent from the transmitting device, and a number extracting means for extracting the frame number, the second storage means and the frame of the frame data read out from the second storage means for storing frame data for each block number and frame number extracted by該番No. extracting means Decoding means for decoding at a coding rate corresponding to the number, error detecting means for performing error detection by check data in the frame data decoded by the decoding means, and frame data stored in the second storage means. Read control is performed, and if no error is detected by the error detection means, the ACK signal is transmitted to detect an error. The NACK signal data communication system according to a hybrid automatic repeat request method, characterized by being configured and a second control means for controlling to send to when. 2. The second control means, when no error is detected by the error detection means, erases the frame data of the block number and the frame number having no error from the second storage means, and When it is detected, control is performed to hold the frame data having the block number and the frame number having the error in the second storage means, and the frame data transmitted by the first control means when the NACK signal is received is stored in the second storage means. 2. The data according to the hybrid automatic repeat request system according to claim 1, further comprising a function of storing the frame data in the storage means and controlling the frame data and the frame data having the same block number as the frame data to be stored. Communications system. 3. The NACK instead of the first control means
The frame data from said first storage means unless it receives a signal and transmits the read out in the order of block numbers, said NACK
When the signal is received, there is provided third control means for transmitting the frame data of the untransmitted frame number of the block number indicated by the NACK signal, and sequentially transmitting the frame data from the next block number after the transmission, and the second control means. Instead, when the error is not detected by the error detecting means, the ACK signal is transmitted, and the frame data of the block number and the frame number having no error is erased from the second storage means, and the error is detected. When the NACK signal is transmitted, the NACK signal is transmitted, the frame data having the block number and the frame number having the error is held in the second storage means, and the received frame data other than the held data is controlled, and the third data is stored. The frame data transmitted by the control means at the time of receiving the NACK signal is stored in the second storage means. 3. The data according to the hybrid automatic repeat request system according to claim 1 or 2, further comprising: fourth control means for controlling the reading of the stored frame data and the frame data of the same block number as the frame data. Communications system. 4. The NACK instead of the first control means
The frame data from said first storage means unless it receives a signal and transmits the read out in the order of block numbers, said NACK
When receiving a signal, the frame data of the untransmitted frame number of the block number indicated by the NACK signal is transmitted, and after this transmission, the frame data is sequentially transmitted from the next block number transmitted before the reception of the NACK signal. Control means is provided, and instead of the second control means, the frame data is stored in the second storage means and read out in the order of being transmitted under the control of the fifth control means, and an error is detected by the error detection means. If not, the ACK signal is transmitted, the frame data of the block number and the frame number having no error is erased from the second storage means, and if the error is detected, the NACK signal is transmitted and Frame data having an erroneous block number and frame number is held in the second storage means, and the held data Other than the received frame data is discarded, and the frame data transmitted by the fifth control means at the time of receiving the NACK signal is stored in the second storage means and the stored frame data and the frame data are stored. The data communication system according to the hybrid automatic repeat request system according to claim 1 or 2, further comprising a sixth control means for controlling reading of frame data having the same block number. 5. The data communication system according to the hybrid automatic repeat request system according to claim 4, further comprising an order changing means for outputting the data output from the error detecting means in the order of the block numbers. 6. A convolutional encoder for convolutionally encoding the block data added with the check data is provided in place of the encoding means, and the convolutionally encoded frame data is decoded in place of the decoding means. A data communication system according to the hybrid automatic repeat request system according to claim 1, further comprising a Viterbi decoder. Wherein said first, third, and fifth control means, said estimating the state of the communication channel from the reception frequency of ACK signals and NACK signals, Shi read out from said first memory means when said ACK signal received 7. The data communication system according to the hybrid automatic repeat request system according to claim 1, further comprising a function of controlling the number of frames in one block of frame data to be transmitted. 8. Addition of check data for error detection
Error correction coding of the block data
Divide normal encoded data into multiple frame data
Encoding means, Storage means for storing the plurality of frame data, Read a part of the frame data from the storage means
Transmitted to the receiving device and the frame data is incorrect.
When a NACK signal indicating
Is the untransmitted frame stored in the storage means.
System data from the storage means to the receiving device
A transmitting apparatus comprising a control means for transmitting. 9. Addition of check data for error detection
Error correction coding of the block data
Divide normal encoded data into multiple frame data
Step, Storing the plurality of frame data in a storage means
When, Read a part of the frame data from the storage means
Transmitted to the receiving device and the frame data is incorrect.
When a NACK signal indicating
Is the untransmitted frame stored in the storage means.
System data from the storage means to the receiving device
A transmission method comprising a step of transmitting.