JPH08186560A - Transmitting/receiving method and device therefor - Google Patents

Abstract

PURPOSE: To shorten transmission time for transmitting data without adding any error correcting code by dividing the data into several blocks and obtaining the codes different in code length by performing variable length encoding for each block. CONSTITUTION: A sequence number allocating part 5 successively fetches the respective codes different in code length into a code storage part 4, adds sequence numbers to the codes and sends them to a code length detecting part 6. The code length detecting part 6 detects the code lengths of the respective transmitted codes, sends all the codes to a code transmitting part 8 and further stores the codes, whose code lengths are longer than a fixed reference value, in a resending code storage part 7. After all the codes from the code length detecting part 6 are transmitted, the code transmitting part 8 fetches the codes in the resending code storage part 7 and transmits the codes again. A code receiving part 10 stores only the codes without any error among the transmitted codes in a code storage part 11 and the stored codes are edited in an editing in an editing part 12 by referring the sequence numbers.

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a transmission / reception method and a transmission / reception apparatus for compressing and transmitting information such as image signals and the like, and particularly to re-transmission between transmission / reception stations when errors occur in reception information due to transmission path errors. The present invention relates to a transmission / reception method and a transmission / reception device suitable for avoiding an increase in transmission time due to a request.

[0002]

2. Description of the Related Art Generally, data having a large amount of information, such as an image signal, is compressed by a data compression technique before being transmitted. FIG. 6A shows an example of an image compression system used for compressing an image signal. That is, in the image compression system shown in the figure, the image signal (image data) is first given to the series conversion unit 20 so as to convert the data series of the original image into a series having the smallest average information amount. Then, the block division unit 21 of the sequence conversion unit 20
Then, the original image data is divided into blocks, and each block data is sent to the orthogonal transformation unit 22 one by one, subjected to orthogonal transformation and converted into a sequence having a smaller average information amount than the original image data sequence and transmitted. . In this way, the sequence conversion unit 2
The data sequence-converted by 0 is then given to the entropy coding unit 23, a code is assigned so that the average code length thereof approaches the average information amount after the above-mentioned sequence conversion, and is transmitted as a certain code sequence. . In the entropy coding, generally, an FV code (Fixed-Var code) is used in view of the fact that data can be represented by a small bit length.
The iave code) method is used. The code sequence for each block obtained as described above is used to generate a transmission frame for each block, and the transmission frames corresponding to each block are sequentially generated and transmitted.

By the way, as described above, as a receiver for receiving code sequence data for each block which forms a transmission frame and is transmitted, a transmission frame having poor transmission line quality and an error has been transmitted. Sometimes a type of requesting the same side to retransmit the same data, that is, ARQ method (A
An automatic repeat request method) is widely used. FIG. 6B is an operation diagram for explaining the ARQ method. That is, in the above method, the receiving side determines whether or not there is an error in the data frame each time it receives data relating to one transmission frame, that is, one data frame from the transmitting side, and if there is no error, an ACK ( Acknowledgement)
If there is an error in the signal, NAK (Negative)
An Acknowledgement) signal is sent to the sender. Then, the transmitting side transmits the next data frame when receiving the ACK signal, but retransmits the data frame transmitted immediately before when receiving the NAK signal.

However, in the above-mentioned basic ARQ system, the data frame cannot be continuously transmitted from the transmitting side, and the transmission efficiency is poor. In order to improve this point, a batch response method in which a response is collectively returned from the receiving side to the transmitting side for some data frames is considered. FIG. 6 (c)
FIG. 7 is an operation diagram for explaining this collective response method.
That is, in this method, in order to identify the data frame, the transmitting side adds a sequence number to each data frame and transmits the data frame. When the receiving side detects an erroneous data frame, the receiving side sends the sequence number as an error notification to the transmitting side, and the transmitting side receives the sequence number and retransmits the data frame after the sequence number.

[0005]

However, even in the above batch response method, when a transmission path error occurs, the receiving side needs to send the error notification for the number of error data frames, which results in a long transmission time. Become. And this tendency becomes remarkable when the quality of the transmission line is poor.
The present invention has been made in view of the above circumstances, and divides data having a large amount of information such as an image signal into several blocks, and then compresses the information by variable length coding for each block. In addition, it is an object of the present invention to avoid an increase in the transmission time due to a request for retransmission between the transmitting and receiving stations in the transmission / reception in which transmission is performed without adding an error correction code and the retransmission, especially when the quality of the transmission path is poor. And

[0006]

All of the inventions of the present application are as follows.
Data with a large amount of information is divided into several blocks, compression operation is performed by variable length coding for each block to obtain codes with different code lengths, and these codes are transmitted without adding error correction codes. At the time of transmission / reception, at the time of transmission, for all codes having different code lengths or for codes having a certain code length or more, the number of duplications is increased according to the code length, and each is transmitted a plurality of times. Further, when receiving, when receiving the code related to the same block a plurality of times, only the first code received without error is stored and the other codes are discarded.

[0007]

The quality of the transmission path is represented by an error rate per bit of transmission information, that is, BER (Bit Error Rate), and when data (that is, code) having a bit length of L is transmitted. The probability that the code will be received without error by one bit, that is, the reception probability P (L) is expressed by the following equation. P (L) = (1-BER) ^L Therefore, for example, the quality of the transmission path, that is, BER is 0.001.
When transmitting / receiving via the transmission path of, the reception probability P (10) of the code of 10 bits becomes 0.9900, and the reception probability P (100) of the code of 100 bits.
Is 0.9048. That is, when the quality of the transmission path is fixed, the longer the bit length, that is, the longer the code length is, the lower the reception probability is, and the higher the probability of reception including an error is, the more retransmission request is made. The number of times also increases.

By the way, according to the present invention, when each code having a different code length for each block is transmitted, a code having a code length of at least a certain length or more is duplicated according to the code length. It is transmitted multiple times. This behavior is
In order to exclude the retransmission request operation of the receiving side, which has a larger number of times as the code has a longer code length, the transmitting side predicts and predicts this number of times of retransmission request for each code, and repeatedly transmits each code for the number of times of retransmission request. It can be regarded as equivalent to what you are doing. Therefore, it is possible to shorten the transmission time by excluding the retransmission request operation on the receiving side.

In the present invention, the number of retransmission requests for each code is predicted on the transmission side as described above, and the codes are redundantly transmitted by that number of times. However, the number of retransmission requests is strictly the same. Since the prediction is based on probability theory, at the moment when the transmission path quality deteriorates, even if the predicted number of times is repeated, there is a possibility that only the code containing the error will be received and the code will end up. There is. However, when the transmission target is, for example, an image signal or the like, finally an image is formed,
Since it is recognized by the human visual sense, it does not cause a big problem even if an error code that is not recognized by the human visual sense remains. Rather, it is not preferable to repeat the retransmission request many times and lengthen the transmission time due to the existence of a slight error code.

[0010]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS The present invention will be specifically described below with reference to embodiments shown in the drawings. FIG. 1 shows a circuit configuration of a transmitting / receiving apparatus according to a first embodiment of the present invention. In the figure, the block reading unit 1
The orthogonal transformation unit 2 reads out in units of blocks for performing orthogonal transformation.
Is a circuit part for sending out to 8 bits of pixel data per pixel, for example, a total of 64 pixels of 8 pixels in the vertical direction and 8 pixels in the horizontal direction.
Read as a block. The orthogonal transformation unit 2 is a circuit unit that performs orthogonal transformation on the transmitted one block of data to create data with a reduced average amount of information in the data series, and sends the data to the FV encoding unit 3.

The FV encoding unit 3 is a circuit unit for inputting the data from the orthogonal transforming unit 2, encoding so that the average code length approaches the average information amount of the data, and transmitting the obtained code. However, the code lengths of the above-mentioned codes (corresponding to each block) transmitted from the FV encoding unit 3 are not the same. The code storage unit 4 includes the FV encoding unit 3
This is a circuit unit for accumulating the codes sent from the.

The sequence number assigning section 5
This is a circuit unit that reads out the codes stored in the code storage unit 4 in the order in which they are stored in the code storage unit 4, assigns a sequence number to them, and sends them to the code length detection unit 6.
The code length detecting unit 6 detects the code length of each code sent from the sequence number allocating unit 5, sends out a code having a certain code length or more to the retransmission code accumulating unit 7, and outputs from the sequence number allocating unit 5. It is a circuit unit that sends all codes to the code transmission unit 8. The retransmission code storage unit 7 is a circuit unit that stores a code sent from the code length detection unit 6, that is, a code having a code length longer than a certain code length.

The code transmitting section 8 is a circuit section for generating and transmitting a transmission frame as shown in FIG. 2 based on the transmitted code. First, all the codes from the code length detecting section 6 are converted into the above-mentioned codes. As described above, after sequentially transmitting, all the codes accumulated in the retransmission code accumulating section 7 are sequentially transmitted as described above. The transmission path 9 can be regarded as one circuit section, and according to its quality, with a certain probability, the transmission frame from the code transmission section 8 is added with noise and transmitted to the code reception section 10. The code receiving unit 10 receives the above-mentioned transmission frame as a reception frame, determines whether or not there is an error in this reception frame by the error detection code (see FIG. 2), and the error-free reception frame is stored in the code storage unit 11. This is a circuit unit that sends out and discards an erroneous received frame. The code storage unit 11 is a circuit unit that stores error-free received frames sent from the code receiving unit 10. The editing unit 12 is a circuit unit that edits the code stored in the code storage unit with its sequence number.

Next, the operation of the present embodiment configured as described above will be described. FIG. 3 shows an operation diagram of this embodiment. Now, the image data is divided into five by the block reading unit 1, and the data of each block is sequentially orthogonally transformed and FV encoded by the orthogonal transformation unit 2 and the FV encoding unit 3 and accumulated in the code accumulating unit 4. Moreover, the codes sent to the code storage unit 4 second and fifth (that is, the code displayed as data 1 and the code displayed as data 4 in FIG. 3) have a predetermined standard. It is assumed that the code length is longer than the code length.

When transmitting the codes stored in the code storage section 4 as described above, the sequence number allocating section 5 is used.
Reads the above codes in the order in which they are sent to the code storage unit 4, adds sequence numbers such as data 0 to 4 shown in FIG. 3 and sends them to the code length detection unit 6. Reference numeral 6 detects the code lengths of these codes, sends the codes of the data 1 and 4 to the retransmission code storage section 7 for storage, and sends all the codes (codes related to data 0 to 4) to the code transmission section 8. . Then, as shown in FIG. 3, the code transmission unit 8 sequentially transmits all the codes, that is, the codes related to the data 0 to 4, and thereafter, the data 1 and 4 stored in the retransmission code storage unit 7. The code related to is transmitted. In the transmission of all the above codes, the one that has a high probability of being received as an erroneous reception frame is a code related to data 1 or 4 having a long code length. For example, as shown in FIG. Even if the code related to 1 is received as an erroneous received frame, this is discarded by the code receiving unit 10, and the code related to the data 1 sent as retransmission data is stored in the code storage unit 11. . Then, the editing unit 12
The code of the code storage unit 11 is fetched, and each code is edited with reference to the sequence number (data 0 to 4). As a result, the received image is correctly reproduced on the receiving side. The code related to the data 4 in the retransmitted data is discarded as shown in FIG. 3 because the same code has already been received in the error-free state and stored in the code storage section 11.

Next, a second embodiment of the present invention will be described. FIG. 4 shows the circuit configuration of the transmitting / receiving apparatus according to this embodiment. In FIG. 4, a circuit section having the same reference numeral as the circuit section in FIG. 1 showing the circuit configuration of the first embodiment is a circuit section having the same configuration and function as the circuit section in FIG. . When FIG. 4 is compared with FIG. 1, the configuration of FIG. 4 is similar to that of FIG.
And a retransmission code storage unit 17 is added. Then, the code length detection unit 16 uses the sequence number allocation unit 5
Is a circuit unit for inputting all the codes from the above, detecting the code lengths thereof, and selecting only those codes having a code length longer than a certain reference length and transmitting them to the retransmission code accumulating unit 17. It is longer than the reference length in the part 6. The retransmission code storage unit 17 is a circuit unit that stores the code sent from the code length detection unit 16.

In the present embodiment configured as described above, the code transmission section 8 has the code length detection section 6 as shown in the operation diagram of FIG.
After sequentially transmitting all the codes from 1 to 3 in the order of sequence numbers, the codes stored in the retransmission code storage unit 7 having a code length longer than a certain length (codes related to data 0, 3, 4) are taken in, 1 Retransmitted signal, and after that,
A code (code related to data 3) having a longer code length stored in the retransmission code storage unit 17 is fetched and transmitted as a second retransmission signal. As a result, the receiving side can receive a code having a somewhat long code length (code related to the data 4) even if the first transmission has an error, and the first retransmission code can receive the error without any error. Even if the longest code (code related to data 3) is received as an error in the reception of the first retransmission code, the second retransmission code can be received without error.

The invention of the present application is not limited to the above-described embodiments, and various modifications can be applied without departing from the invention. For example, in each of the above-described embodiments, the sequence number assigning unit 5 is provided and a sequence number is added to each code, and the receiving side edits based on this. Each code is sequentially added to the code accumulating section 4 without being added, and is sequentially taken into the code length detecting section 6, the code length is detected, and the number of times corresponding to the code length (for example, two times), It is needless to say that the code (for example, the code related to the data 1 in FIG. 3) may be repeatedly transmitted, and then the next code (for example, the code related to the data 2 in FIG. 3) may be transmitted.

Even if the transmitter / receiver is configured as shown in FIG. 1, it is needless to say that a code having a long code length stored in the retransmission code storage unit 7 may be retransmitted a plurality of times instead of once. . Further, the first embodiment is provided with a retransmission code storage unit 7, divides the transmission code into two stages according to the code length, and retransmits the code of the retransmission code storage unit 7, and the second embodiment is a retransmission code storage unit. 7 and the retransmission code accumulating unit 17, the transmission code is divided into three stages by the code length, and the retransmission code accumulating unit 7 and the retransmission code accumulating unit 17 are used to perform the retransmission twice. It goes without saying that a larger number of retransmission code storage units may be provided and the retransmission code may be divided into multiple stages and retransmitted many times.

[0020]

As described in detail above, according to the present invention, data having a large amount of information is divided into several blocks, and a compression operation is performed by variable length coding for each block to obtain codes having different code lengths. Therefore, it is possible to avoid an increase in the transmission time due to a large number of retransmission requests in transmission / reception, without adding an error correction code to these codes.

[0021]

[Brief description of drawings]

FIG. 1 is a diagram showing a circuit configuration of a first embodiment of the present invention.

FIG. 2 is a diagram showing a structure of a transmission frame in the first embodiment.

FIG. 3 is a diagram for explaining the operation of the first embodiment.

FIG. 4 is a diagram showing a circuit configuration of a second embodiment of the present invention.

FIG. 5 is a diagram for explaining the operation of the second embodiment.

FIG. 6 is a diagram for explaining a conventional example.

[Explanation of symbols]

 1 block reading unit 2 orthogonal transformation unit 3 FV coding unit 4 code storage unit 5 sequence number allocation unit 6 code length detection unit 7 retransmission code storage unit 8 code transmission unit 9 transmission line 10 code reception unit 11 code storage unit 12 editing unit 16 code length detection unit 17 retransmission code storage unit 20 sequence conversion unit 21 block division unit 22 orthogonal transformation unit 23 entropy coding unit

Claims (6)

[Claims] 1. A data having a large amount of information is divided into several blocks, compression operation is performed by variable length coding for each block to obtain codes having different code lengths, and these codes are
In a transmission method for transmitting without adding an error correction code, according to the code length, for all the codes with different code lengths or for the code with the code length longer than a certain length A transmission method characterized by increasing the number of duplications and transmitting a plurality of times. 2. A receiving method in which data having a large amount of information is divided into several blocks, each block is coded, and a code transmitted without adding an error correction code is received When such a code is transmitted a plurality of times, the receiving method is characterized in that only the first code received without error is accumulated and the other codes are discarded. 3. Data having a large amount of information is divided into several blocks, compression operation is performed by variable length coding for each block to obtain codes having different code lengths, and these codes are added with error correction codes. In the transmitting device that transmits the code length, the number of duplicate transmissions according to the code length is specified for all the codes having different code lengths or for the codes having the code lengths longer than a certain length. A transmission apparatus comprising: a duplicate transmission number designating circuit unit; and a duplicate transmission circuit unit that duplicates each code having a different code length by the number of duplicate transmissions designated by the duplicate transmission number designating circuit unit. . 4. A receiving apparatus for receiving a code transmitted by dividing a data having a large amount of information into several blocks, encoding each block, and adding an error correction code to the same block. When such a code is transmitted multiple times, only the code detected by the error-free code detection circuit unit and the error-free code detection circuit unit that detects the first code received in the error-free state is used. A receiving device, comprising: a storage circuit unit for storing. 5. A code having a large amount of information is divided into several blocks, and a code obtained by performing a compression operation by variable length coding is stored in a code storage section for each block. A sequence number is added to each of the codes stored in the storage unit, the code length of each code is detected, and a group consisting of all codes having a code length of N ₁ or more, N ₂ (However, N ₂ > N
₁ ) Group consisting of all codes above, N ₃ (however, N
_A group consisting of all codes greater than ₃ > N ₂ ) ...
The above codes are divided into groups, such as, and are divided into a first retransmission code storage section, a second retransmission code storage section, a third retransmission code storage section, and so on. First, all codes to which the above sequence number is added are transmitted, and then all codes of the first retransmission code storage section, all codes of the second retransmission code storage section, and third retransmission code storage section All signs of,
……………………… In this order, on the other hand, when receiving the code transmitted as above, the code with the same sequence number is
When transmitted multiple times, only the first code received with no error is accumulated, other codes are discarded, and the accumulated codes are referred to the sequence number added to each. A sending and receiving method characterized by editing by editing. 6. A transmission / reception device comprising the following transmission device and reception device. Data with a large amount of information is divided and read for each block, and the data is sequentially output from the block reading unit, and the data of each block output from the block reading unit is compressed by variable-length coding to obtain a code length. The compression operation unit that sequentially outputs different codes, the code accumulation unit that accumulates the codes that are sequentially output from the compression operation unit, and the codes accumulated in the code accumulation unit Input in the order in which they are stored in the storage unit, and input the sequence number allocation unit that adds a sequence number to each code, and the above-mentioned codes that have been sequence numbers added by the sequence number allocation unit, and then input the code length of each code. , A group consisting of all codes having a code length of N ₁ or more, a group consisting of all codes of N ₂ (where N ₂ > N ₁ ) or more, N ₃ (where N ₃ > N ₂₎ ) All of the above Group of symbols, ..........................., in so on, the a code length detection unit divided into each code group, the code length divided into groups by the code length detection unit N ₁
A group consisting of all the above codes, a group consisting of all N ₂ or more codes, a group consisting of all N ₃ or more codes, ...
The first retransmission code storage unit, the second retransmission code storage unit, the third retransmission code storage unit, which store
............ Retransmission code storage unit provided with the above, and the sequence number assigning unit transmits all the codes to which the sequence numbers are added, and then the first code of the retransmission code storage unit.
A transmission including a retransmission code storage section, a second retransmission code storage section, a third retransmission code storage section, and a code transmission section for transmitting the respective codes stored in this order in this order. apparatus.
When a code to which the same sequence number is added is transmitted a plurality of times, an error-free code detection circuit section for detecting the first code received in an error-free state, and the error-free code detection circuit section The received signal storage circuit section that stores only the code detected by and discards the other codes, and the codes stored in the received signal storage circuit section, refer to the sequence numbers added to them. , A receiving device having an editing circuit section for editing.