KR19990081470A - Method of terminating iterative decoding of turbo decoder and its decoder - Google Patents

Abstract

The present invention relates to a turbo code decoder, and more particularly, to a turbo code decoder that can shorten the decoding time. In order to decode the turbo code, iterative decoding is performed. As the number of iterative decoding increases, the data delay becomes larger. Therefore, it is an object of the present invention to reduce such delay. In a method of decoding a turbo code that performs repetitive decoding, a method of outputting decoded data by ending repetitive decoding in the middle without proceeding up to the maximum number of decoding, first, stores previous decoding data. Next, the current decoding data is compared with the previous decoding data, and if the predetermined condition is satisfied, the repeated decoding ends. It is possible to reduce the data delay by shortening the decoding time by not performing repeated decoding until the maximum number of times that can be repeated unconditionally.

Description

Method of terminating iterative decoding of turbo decoder and its decoder

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a turbo code decoder, and more particularly, to a turbo code decoder that can shorten the decoding time.

The turbo code is currently being studied as an error correction code of the next generation of mobile communication. The performance of the turbo code is known to be superior to that of convolutional codes which are widely used in the mobile communication environment. .

Hereinafter, a general turbo code encoding process will be described with reference to the turbo encoder of FIG. 1.

If the encoding of the turbo code is reduced, two simple recursive systematic convolutional (RSC) codes that make a parity symbol using an input of frames of N information bits are connected in parallel. As shown in Fig. 1, the turbo encoder outputs an information bit 101 as one output χ. (101), this information signal (101) passes through the first RSC encoder (100), and Y _1. (102), the signal 103 obtained by passing the information signal 101 through an interleaver (110) having the same size as a frame of N information bits is used as a second RSC encoder. Pass through Y ₂ After getting 104, it will be sent. Accordingly, the output of the turbo code has dual parity information due to the output of the first RSC encoder as well as the output modified through the interleaver. However, in order to obtain the desired code rate in the turbo encoder, Y ₁ 102 and Y ₂ The 104 punches the output signal through the puncturer. For example, to make the code rate 1/2, Y ₁ With Y ₂ You can drill alternately to output once. The parity bit Y finally obtained by drilling like this Χ 105 Send along with.

To decode codewords coded by the turbo code, the decoder is serially connected and decoded as shown in FIG. 2.

Each of these decoders should have a soft output on the soft input. In general, these decoders use a machiimum a posteriori (MAP) and a soft output viterbialgorithms (SOVA) decoder. However, the performance is known to be better MAP decoder. Unlike the decoder of the multilevel encoder such as conventional concatenated codes, the turbo coder exchanges additional information (eχtrinsic information) between the two decoders to perform decoding repeatedly. And as the number of iterations increases, performance also improves.

As shown in FIG. 2, decoding of a codeword encoded by a turbo code is as follows.

First, χ 201 and y When 202 is a signal through which a codeword of a turbo encoder as shown in FIG. 1 passes through a channel, χ Is the signal that the information bit passed through the channel and y Becomes a signal where the parity bit has passed through the channel. Parity signal y received first By depuncturing 202 (not shown), the parity bit 203 corresponding to the first RSC encoder 100 of FIG. 1 is the first decoder (DEC1) 210 and the second RSC encoder. The parity bit 204 corresponding to 2 120 is sent to the second decoder DEC2 230.

In the first decoder (DEC1) 210, χ 201 and y ₁ Decode using 203, and then interleaving the output 205 of the first decoder DEC1 again with y ₂ and y _2. Decode by the second decoder (DEC2) 230 using the (204). In this case, if the repeated decoding is not desired, the output signal 207 of the second decoder DEC2 is deinterleaved, and the hard decision signal 208 is output as a decoding signal through the hard decision unit 250. However, in order to perform repeated decoding, a signal 209 and a reception signal χ obtained by deinterleaving the output signal 208 of the second decoder DEC2 are included. 201 and y ₁ Decoded back to the first decoder (DEC1) 210 by using (203). This iterative decoding can be done until the desired performance is achieved.

Factors that determine the performance of the turbo code include the structure of the RSC code, the structure and size of the integrated receiver, the decoding method and the number of decoding. In order to obtain the structure of the RSC code that shows the best performance, it can be obtained through trial and error through simulation. The decoder is known to have the best performance of the MAP decoder. Also, the larger the interleaver is, the better the random interleaver is. The higher the number of decoding, the better the performance. However, in a general communication system, the delay of data transmission is limited, and in the turbo code decoder, the number of decoding cannot be infinite because the number of decoding does not increase even if the number of decoding increases. Therefore, such a technique is not only inefficient, but also delayed in data transmission because there is a decoding frequency in which the performance is not increased even if the decoding number is increased.

Accordingly, it is an object of the present invention to provide an improved turbo code decoder that can stop decoding at an appropriate number of decoding times.

1 is a block diagram of a general turbo code encoder;

2 is a block diagram of a conventional turbo code decoder;

3 is a block diagram of a turbo code decoder according to the present invention.

A feature of the coded decoder according to the present invention is that the decoding is not always performed until a predetermined maximum number of repeated decoding times, but the decoding ends without performing the repeated decoding any more when the situation meets the decoding escape condition. Here, the escape condition is considered to be the case where the decoding data of the first step and the decoding data of the current decoding step are the same as the current decoding step. That is, after the current decoding step, the decoding data is stored in the memory and compared with the data of the previous step. If the two data are the same, it is assumed that the performance cannot be improved even if the decoding continues, or the data error has been completely corrected, and the decoded data is output to the output without further decoding.

Hereinafter, an embodiment of the present invention will be described in detail with reference to FIG.

3 is the same as in FIG. 2 except for the switch 360 and the data storage and comparator 370 which perform a function of stopping decoding at a predetermined number of decoding times. Therefore, the newly added part will be described and the rest will be omitted.

According to the present invention, if the situation meets the decryption escape condition, the decoding process is terminated without performing the repeated decoding any more. It is considered that the decoding data of the decoding step is the same. In other words, after the current decoding step is completed, the data storage and comparator 370 stores the decoded data 309 in the memory and compares the data with the previous step. At this time, if these two data are the same, it is assumed that the performance cannot be improved even if the decoding continues any more or the data error has been completely corrected, and the decoded data is sent to the output 311 without further decoding. However, if the two data are not the same, the decoding data of the previous step is discarded and a decoding failure signal is sent to the switch 360 to continue decoding. The data storage and comparator 370 may be configured with a memory that is twice the frame length. Since the comparison of one bit of data can be performed with one system clock, the data storage and comparator 370 is not complicated to configure in hardware. The hardware configuration is easy because it does not take any.

On the other hand, the data magnetic field and the comparator 370 can be placed at the position 305, and the data of the previous decoding step, the output of the first decoder of the current decoder 305 and the output of the current decoding step are stored and compared. You can also compare the three data sets.

According to the present invention, it is possible to reduce the data delay by shortening the decoding time by not performing repeated decoding until the maximum number of times that can be repeated unconditionally.

Claims (4)

In the apparatus for decoding a turbo code that performs half-north decoding, the decoding data is generated by ending the repeated decoding in the middle without proceeding up to the maximum number of decoding times. Storing previous decrypted data; And And repeating decoding by comparing current decoding data with previous decoding data. The method of claim 1, End of the iterative decoding is repeated decoding decoding method of the turbo decoder, characterized in that the current decoding data and the previous decoding data is the same. The decoded data determined by the turbo decoder is stored, the current decoding data is compared with the previous decoding data to determine the end of the repeated decoding, and when the repeated decoding is finished, the current decoding data is generated as the final decoding data. Repeat decoding end determining means; And And switching means for providing or not providing a signal provided from said deinterleaver to said first decoder in response to a signal determined from said iterative decoding end determining means. The method of claim 3, And the end of the iterative decoding in the means for determining the end of the iterative decoding is when the current decoding data and the previous decoding data are the same.