KR100719743B1 - Coding and decoding using reversible variable length coding - Google Patents

Abstract

The present invention relates to a code and a decoding apparatus for reducing encoding and decoding delays using a variable length (RVLC) technology capable of forward and backward decoding, and to accurately determine the number of repeated decoding. And a variable length encoding means for variable length encoding the transmitted data, and a concatenated decoding for performing concatenated decoding by receiving the transmitted data transmitted from the encoding device and concatenated code data input from the concatenated encoding means. And variable length decoding means for receiving variable length code data transmitted from the variable length coding means and the concatenated decoded data decoded by the concatenated decoding means. The apparatus is characterized in that Variable-length decoding error search means for providing a luxury when an error occurs the concatenated decoding means to search for locations; And data determination means for receiving concatenated decoded data from the concatenated decoding means, receiving variable length decoded data from the variable length decoding means, and outputting decoded data without error. And concatenation decoding is repeatedly performed using the decoded data inputted from the data determining means and the concatenated code data transmitted to the concatenated encoding means based on the error occurrence position information inputted from the decoded error searching means.

Variable length, turbo decoding, turbo code, error determination, dummy data

Description

Coding and decoding apparatus using variable length technology {CODING AND DECODING USING REVERSIBLE VARIABLE LENGTH CODING}

1 is a block diagram of an encoding apparatus for encoding a turbo code in a transmitting end of a general wireless communication system.

2 is a structural diagram of a concatenation encoder in an encoding apparatus for encoding a general turbo code.

3 is a block diagram of a decoding apparatus for decoding a turbo code at a receiving end of a general wireless communication system.

4 is a block diagram of an encoding apparatus using a variable length (RVLC) technique according to the present invention.

5 is an explanatory diagram of an original data structure and a data structure after performing variable length coding according to the present invention.

6 is a block diagram of a decoding apparatus using a variable length (RVLC) technology according to the present invention.

* Explanation of symbols for the main parts of the drawings

411: a joint encoder 412: serial / parallel conversion unit

413 variable length code portion 414 data alignment portion

415: bottle / serial converter

The present invention relates to an encoding and decoding apparatus using a variable-length (RVLC) technique, and in particular, it is possible to minimize the total code and decoding delay time occurring in a channel encoding process such as a turbo code, and to repeat the decoding times. The present invention relates to an encoding and decoding apparatus using a variable length (RVLC) technique for recovering original data in a network in which an error may occur.

The present invention is to transmit original data when transmitting original data in a transmission network in which an error exists and to transmit parity information for compensating for an error when the original data is transmitted.

1 is a block diagram of an encoding apparatus for encoding a turbo code in a transmitting terminal of a general wireless communication system. The interleavers 111 through 11 (n-1) for interleaving input transmission information bits to reduce correlation And an encoder 121 for encoding input transmission information bits, and an encoder 122 to 12n for encoding a signal interleaved through a corresponding interleaver among the interleavers 111 to 11 (n-1).

As shown in FIG. 1, the transmission information bits are directly transmitted as information bits without an encoding process or encoded by the encoders 121 to 12n and transmitted as parity bits.

The encoding apparatus for encoding the turbo code at the transmitter will be described in more detail as follows.

Turbo channel encoding sends the original data once, and uses the result of the Recursive Systematic Convolution (RSC) encoder of the original data and the result data of the interleaver and the RSC encoder as parity information. Here, the interleaver is a device for generating data that is not related to the original data at all. By passing the result of the interleaver to the RSC encoder, generating completely separate output data can distribute the error position of the original data. That is, the turbo code uses 1 bit of information and 2 bits of additional parity information. When recovering the turbo coded data, the decoder recovers the original data sent from the transmitter using these three bits of information. As such, the structure of a typical Recursive Systematic Convolution Encoder used in turbo channel coding is described with reference to FIG. 2.

3 is a block diagram of a decoding apparatus for decoding a turbo code at a receiving end of a general wireless communication system.

The decoding apparatus is composed of a decoder 1 (311), an interleaver (312), a decoder (2) 313, and deinterleavers (314, 315).

As shown in FIG. 3, the decoding apparatus does not know whether the data sent from the transmission side is correct during data recovery, and thus decodes it several times to increase the error recovery rate. In addition, the overall data delay occurs by using the interleaver at the transmitting end and the receiving end, and a considerable delay occurs by performing repetitive decoding to increase the error recovery rate. In addition, it is difficult to accurately determine the number of iterations to increase the error recovery rate. In other words, infinite repetition may be required to show a recovery rate of 100%.

The present invention has been made to solve the above-described problems, by using a variable length (RVLC) technology capable of forward and backward decoding, reducing encoding and decoding delays, and accurately determining the number of iteration decoding, so that an error may occur. An object of the present invention is to provide an encoding and decoding apparatus using a variable-length (RVLC) technology for recovering original data in a capable network.

According to an aspect of the present invention, there is provided an encoding apparatus comprising: concatenated encoding means for concatenating encoding transmission data, variable length encoding means for variable length encoding the transmission data, and the transmission data transmitted from the encoding apparatus. A concatenated decoding means for receiving concatenated decoding data inputted from the concatenated encoding means and performing concatenated decoding; and receiving concatenated decoded data decoded by the concatenated decoding means and variable length code data transmitted from the variable length encoding means. A decoding apparatus including variable length decoding means for performing variable length decoding, wherein the decoding apparatus searches for a variable occurrence position when decoding the variable length decoding means and provides the variable length decoding error searching means to the contiguous decoding means. ; And data determination means for receiving concatenated decoded data from the concatenated decoding means, receiving variable length decoded data from the variable length decoding means, and outputting decoded data without error. And concatenation decoding is repeatedly performed using the decoded data inputted from the data determining means and the concatenated code data transmitted to the concatenated encoding means based on the error occurrence position information inputted from the decoded error searching means.

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The present invention transmits original data when transmitting data in a transmission network in which an error exists, and transmits parity information for compensating for an error, and adds 2 bits to 1 bit of information to be transmitted. It is intended to recover data using it as.

The above objects, features and advantages will become more apparent from the following detailed description taken in conjunction with the accompanying drawings. Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

4 is a block diagram of an encoding apparatus using a variable length (RVLC) technique according to an embodiment of the present invention, which is an encoder for encoding a turbo code at a transmitting end, and which has a correlation between input data and output data. A concatenated coder 411 for generating predetermined parity information among a plurality of parity information, a serial / parallel converter 412 for converting serially input data from the outside into parallel data, and a serial / parallel conversion The variable length coder 413 and the variable length coder 413 which variable length code the signal inputted through the unit 412 into a vector form having a predetermined size to enable forward and reverse coding are variable. Data sorting unit 414 for inserting dummy data to sort the data in order to keep the length of the generated data constant after generating the data having the length And a parallel / serial conversion unit 415 for converting the parallel data transferred from the data alignment unit 413 into serial data.

Looking at the encoder according to the invention in more detail as follows.

As shown in FIG. 4, the following three output signals are generated using the transmitter input signal d _k . One is output as the original signal X _k , and the other two signals are used as parity information, and are the outputs of the concatenated code unit (encoder) 411 and the variable length (RVLC) code unit 413 capable of forward and reverse decoding. The concatenation code part 411 is initialized to "0" at the time of initial data generation. The input data and the output data are correlated and encoded according to the input signal d _k . This concatenation code part 411 is a general structure used in a turbo encoder and the like, and is the same as the general structure of FIG. 2 mentioned above.

In addition, the variable length (RVLC) encoding is performed by configuring the input signal d _k in a vector form having a plurality of predetermined sizes. To this end, variable length encoding is performed after serial / parallel conversion. Subsequently, the variable length coder 413 receives a vector signal having a predetermined size and outputs a variable index according to a table using probability of input data. At this time, the data structure generated after executing the variable length encoding has a variable length. In this way, in order to keep the length of data constant, dummy data is inserted and has a data size of a constant size as in the original data structure. Thus, Figure 5 shows the original data structure and the data structure after performing variable length encoding, and the sorted data is transmitted in a bit-by-bit structure after parallel / serial conversion.

FIG. 6 is a block diagram of a decoding apparatus using a variable length (RVLC) technology according to the present invention, and is a decoder for decoding a turbo code at a receiving end.

As shown in FIG. 6, the concatenation decoder 601 receives input data X _k transmitted from the encoding apparatus and concatenated encoded data transferred from the concatenation code unit 411 of the encoding apparatus and performs normal concatenation decoding. . The variable length decoder 602 receives the decoded data transmitted from the concatenated decoder 601 and the variable length coded data of the encoding apparatus and performs normal decoding to compensate for an error of the input data.
The variable length decoding error retrieval unit 603 retrieves the existence of an error with respect to the decoded data transmitted from the variable length decoding unit 602 and transmits the error to the concatenated decoding unit 601. The data determination unit 604 determines the input data without error based on the decoded data transmitted from the concatenated decoding unit 601 and the decoded data transmitted from the variable length decoding unit 602. In addition, the concatenated decoding unit 601 receives the determined data inputted from the data determining unit 604 and the error presence data inputted from the variable length error retrieval unit 603, and determines repetitive decoding.

That is, the decoding apparatus according to the present invention will be described in more detail as follows.

가 연접 복호부(601)에 입력되어 연접 부호화된 데이터

가 출력된다. 이 연접 복호 데이터

는 앞뒤 데이터를 가지고 어느 정도 에러를 복구한 형태가 된다. 연접 복호 데이터

와 가변장 부호화된 데이터

를 사용하여 가변장 복호부(602)는 가변장 복호화를 수행한다. 즉, 연접 복호화 데이터

와 가변장 부호 데이터

를 가변장 복호화를 하면서 서로의 에러에 대한 보상을 하게 된다. 만약 복호시 에러가 양쪽에서 발생되었을 경우 가변장 복호 에러 검색부(603)는 에러 위치 정보를 연접 복호부(601)로 전달하게 된다. 연접 복호 데이터

와 가변장 부호 데이터

를 사용하여 가변장 복호화를 하는 가변장 복호부(602)는 입력 데이터의 앞쪽부터 복호화를 실행하게 된다. 만약, 에러에 의해서 더 이상 진전이 없으면 맨 뒤쪽에서 다시 수행하게 되고, 최종 에러가 발생하는 영역이 가변장 복호 에러 검색부(603)에서 결정되어 연접복호화를 하는 연접복호부(601)로 전달된다. 그러므로, 가변장 복호부(602)는 에러가 없는 정확한 입력 데이터를 결정하게 된다. 이 가변장 복호부(602)의 출력은 데이터 판정부(604)로 전달되어 에러가 없는 전송측 입력 신호를 판정하여 출력하게 된다. First, the original signal X _k transmitted from the encoding device and the output signal of the concatenated encoder.

Is input to the concatenated decoder 601 and concatenatedly encoded data.

Is output. The concatenated decoding data

Takes some form of error recovery with data back and forth. Concatenation Decoded Data

And variable length coded data

The variable length decoding unit 602 performs variable length decoding. That is, concatenated decoded data

And variable length code data

The variable length decoding is used to compensate for each other's errors. If an error occurs at both sides of the decoding, the variable length decoding error search unit 603 transfers the error position information to the concatenated decoding unit 601. Concatenation Decoded Data

And variable length code data

The variable length decoding unit 602, which performs variable length decoding using H, performs decoding from the front of the input data. If no further progress is made due to an error, the process is performed at the far back, and the area where the final error occurs is determined by the variable length decoding error search unit 603 and transferred to the concatenated decoding unit 601 that performs concatenated decoding. . Therefore, the variable length decoder 602 determines accurate input data without errors. The output of the variable length decoding unit 602 is transmitted to the data determining unit 604 to determine and output an error-free transmission side input signal.

As a result of the determination, if the variable length decoding error search unit 603 determines that there are no more errors, the next block is decoded without performing further repeated decoding.

를 사용하여 연접 복호화를 수행하여 연접 복호 데이터

를 역시 얻어낸다.As a result of the determination, if an error exists, the process returns to the concatenated decoding unit 601 which performs concatenated decoding, and d _k replaces the original input signal X _k . As described above, the error position information and the output signal which are determined by the variable length decoding error search unit 603 and transmitted to the concatenated decoder 601.

Concatenation Decoded Data by Concatenating Decoding Using

Also get

를 사용하여 똑같이 가변장 복호화를 수행하여 전송측 데이터를 복구한다. 3번 이상 반복 후에도 가변장 복호 에러 검색부에서 에러가 검색되면 더 이상 복구가 불가능한 것으로 판단한다.This concatenated decoding data and variable length code data

Using variable length decoding, recover the data on the transmission side. If an error is detected by the variable length decoding error search unit after repeating three or more times, it is determined that recovery is no longer possible.

The present invention described above is not limited to the above-described embodiments and the accompanying drawings, and various substitutions, modifications, and changes can be made in the art without departing from the technical spirit of the present invention. It will be clear to those of ordinary knowledge.

The present invention as described above has the effect of reducing the number of repetitions by reducing the coding and decoding delay by using a variable length (RVLC) technology, and making an accurate determination on the received data. In the present invention, it is possible to improve the overall function by accurately determining such a delay and the number of repetitions.

Claims (4)

delete An encoding device comprising concatenated encoding means for concatenating encoding transmission data, variable length encoding means for variable length encoding the transmission data, and the concatenated code data input from the transmission data transmitted from the encoding device and the concatenated encoding means. Concatenation decoding means for performing concatenated decoding and receiving concatenated decoding data decoded by the concatenation decoding means and variable length code data transmitted from the variable length encoding means, and performing variable length decoding. In the decoding apparatus comprising a, The decoding device, Variable length decoding error retrieving means for retrieving an error occurrence position during decoding of said variable length decoding means and providing it to said contiguous decoding means; And And data determination means for receiving concatenated decoded data from the concatenated decoding means, receiving variable length decoded data from the variable length decoding means, and outputting decoded data without errors. The concatenation decoding means, Characterized in that the concatenated decoding is repeatedly performed using the decoded data input from the data determining means and the concatenated code data transmitted to the concatenated encoding means based on the error occurrence position information input from the variable length decoding error search means. And a decoding device. The method of claim 2, The encoding device, Serial / parallel conversion means for converting the transmission data in a serial form in parallel and providing the variable length encoding means to the variable length encoding means; Data alignment means for aligning data by inserting dummy data to maintain a constant length of variable code data output from the variable length encoding means; And And parallel / serial conversion means for serially converting the variable code data of the data alignment means. delete

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