KR20010092900A - Apparatus for stopping recursive decoding and turbo decoder comprising it - Google Patents

Abstract

PURPOSE: An apparatus for stopping repetitive decoding in a turbo decoder and a turbo decoder including the same are provided to stop repetitive decoding according to a decision result of a predetermined decision function for a soft decision output. CONSTITUTION: A soft decision value output portion(100) outputs a soft decision value by decoding repetitively turbo coded data and stops repetitive decoding according to a repetitive stop signal. A minimum absolute value discriminator(111) outputs an absolute value of a current soft decision value as a minimum absolute value when the absolute value of the current soft decision value is less than an absolute value of a previous soft decision value. A comparator(113) compares the minimum absolute value with a reference value and outputs the first level signal when the minimum absolute value is less than the reference value. A repetitive decoding stop signal output portion(114) outputs a repetitive decoding stop signal after the soft decision value output portion performs a repetitive decoding operation.

Description

Apparatus for stopping recursive decoding and turbo decoder comprising it

The present invention relates to an apparatus for stopping repetitive decoding in a turbo decoder and a turbo decoder having the same. An apparatus for stopping repetitive decoding according to a determination result of a predetermined decision function for a soft decision output of a turbo decoder and the same. It relates to a turbo decoder provided.

The Turbo code, which is an error correction code, is a code obtained by connecting interleavers and recursive systematic convolutional codes that change the order of input in parallel. The recursive organization convolutional code constituting the turbo code is called a component code. The output of the turbo code is the output bits obtained by encoding the input bits, the parity bits except for the same bits as the input bits among the outputs obtained by encoding the input bits with the component code, and the encoding by the component code after changing the order of the input bits with the interleaver. It consists of parity bits except the same bits as the reordered input bits. In some cases, more than one interleaver and component code may be used.

The turbo code is decoded in component code units. The decoder input of the constituent code consists of organizational symbols and parity symbols and dictionary information for the organizational symbols. The decoder output of the constituent code consists of a Log Liklihood Ratio (LLR) obtained by decoding the organizational symbols and additional information of the organizational symbols. The organizational symbols in the decoder input of the component code are the symbols corresponding to the input bits of the component code in the output of the turbo code to the interleaver. Parity symbols in the decoder input of the component code are symbols corresponding to parity bits of the component code during output of the turbo code. The dictionary information of the decoder input of the constituent code is composed of values in which the additional information in the output of the decoders of the other constituent codes is ordered to the interleaver.

Decoding of the turbo code is performed by performing decoding to the component part sequentially or in parallel on all component codes. When decoding component codes once for all component codes, it is said that repeated decoding of turbo codes is performed once.

When encoded with a turbo code, the received signals may be classified into the following three cases because of the repetitive decoding characteristics of the turbo code.

(1) After convergence to a predetermined value as the number of repeated decoding increases, there is no change anymore, and the error does not occur because the converged value and the input data are the same.

(2) After convergence to a predetermined value as the number of repeated decoding increases, there is no change anymore, and an error occurs because the converged value and input data are different.

(3) When the number of repeated decoding does not converge to a predetermined value, and the position of the error varies depending on the number of repeated decoding

In the above classifications (2) and (3), even if repeated decoding is large, errors in the received signal cannot be corrected. In the case of (1), the error cannot be corrected when repeated decoding until convergence, and the error can be corrected when repeated decoding until convergence. Therefore, as the number of repetitions increases, the case where the error cannot be corrected by stopping repetitive decoding before convergence when the case of (1) occurs, the decoding performance in terms of bit error rate (BER) can be improved.

However, as the number of iteration decoding increases, the degree of improvement of the decoding performance of the turbo code according to the number of iteration decoding decreases, and the amount of computation according to the iteration decoding increases proportionally with the number of iteration decoding, so the number of iterations should be appropriately determined. .

Rather than performing the same number of iterations for all input frames, it is necessary to estimate the necessary number of iterations from the input symbols of the turbo decoder and the outputs of the decoder to perform iterative decoding as many times as necessary.

Since the transmission signal is unknown in the turbo decoder, the cases of (1) and (2) are not known. In addition, it is very difficult to distinguish the case of (3) and the case of (1) or (2) only by the output of the turbo decoder unless the maximum number of iteration decoding is large.

Therefore, it is necessary to stop the repeated decoding after finding the instant of convergence to the output of the decoder while performing the repeated decoding on the received signal.

SUMMARY OF THE INVENTION The present invention has been made in an effort to provide an apparatus for stopping repeated decoding according to a determination result of a predetermined determination function for a soft decision value output from a turbo decoder, and a turbo decoder having the same.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram of a repetitive decoding stop device and a turbo decoder having a repetitive decoding stop function of a turbo decoder according to the present invention.

According to an aspect of the present invention, there is provided a soft decision value output unit for turbo decoding that outputs a soft decision value by repeatedly decoding turbo encoded data and stops repetitive decoding by a repetition decoding stop signal; If the absolute value of the soft decision value currently output from the soft decoding value output unit of the turbo decoding is smaller than the previously stored minimum absolute value, the absolute value of the currently output soft decision value is stored as the minimum absolute value and the minimum value is output. Absolute value discriminator; A comparator comparing the minimum absolute value with a predetermined reference value and outputting a first level signal if the minimum absolute value is smaller than the reference value; And a repetition decoding stop signal for outputting the repetition decoding stop signal to the soft decision value output unit of the turbo decoding if the comparator outputs a first level signal or if the soft decision value output unit of the turbo decoding has repeatedly performed a predetermined number of times. It includes an output unit.

According to an aspect of the present invention, there is provided a soft decision value output unit for turbo decoding that outputs a soft decision value by repeatedly decoding turbo encoded data and stops repetitive decoding by a repetition decoding stop signal; The soft decision of the turbo decoding is performed when the predetermined determination function obtained from the soft decision value output from the turbo decoding value output unit satisfies a predetermined condition or the soft decision value output unit of the turbo decoding performs repeated decoding for a predetermined number of times. A repeated decoding stop unit for outputting the repeated decoding stop signal to a value output unit; A weighting unit for accumulating the soft decision value by giving a predetermined weight; And a hard decision value output unit which is turned on by the repetition decoding stop signal and hardly determines the output value of the soft decision value output unit of the turbo decoding or the output value of the weighting unit according to whether repetitive decoding has been performed for a predetermined number of times, and outputs a decoded result. Include.

Hereinafter, embodiments of the present invention will be described with reference to the accompanying drawings.

BRIEF DESCRIPTION OF THE DRAWINGS Fig. 1 is a block diagram of a repetitive decoding stop device and a turbo decoder having a repetitive decoding stop function of a turbo decoder according to the present invention. As shown, the repeated decoding stop device includes a soft decision value output unit 100 and a repeated decoding stop unit 110 for turbo decoding. The turbo decoder having a repeat decoding stop function as shown in the figure further includes a weighting unit 120 and a hard decision value output unit 130 in the repeating decoding stop device. In addition, a counter 140 for outputting a control signal to the iterative decoding stop unit 110, the weighting unit 120, or the hard decision value output unit 130 is further provided.

The repetition decoding stop unit 110 includes a minimum absolute value determiner 111, a reference value storage unit 112, a comparator 113, and a repetition decoding stop signal output unit 114. In this embodiment, the iterative decoding stop signal output unit 114 is an OR operation.

The weighting unit 120 includes a multiplier 121, a weight storage unit 122, and an adder 123.

The hard decision value output unit 130 includes a first hard decision unit 131, a second hard decision unit 132, and a selector MUX 133.

The operation according to the configuration is as follows. The soft decision value output unit 100 of the turbo decoding receives the turbo encoded data and outputs the LLR for the i th output bit. As the soft decision value output unit 100 of the turbo decoding, a turbo decoder that performs an existing maximum a posteriori probability (MAP) algorithm or a soft output viterbi algorithm (SOVA) is suitable. The LLR is represented by the following equation.

Since the hard decision is determined as 1 when LLR (i) is positive and 0 when negative, the above equation may be modified as follows.

In the present invention, the minimum absolute value of LLR (i) is used as the determination function for determining the repetitive decoding stop for the LLR (i). It can be determined as a function of the absolute value of the LLR calculated by (BER), or the energy-to-bit energy spectrum (E _b / N ₀ ) per bit obtained from the channel information.

The minimum absolute value discriminator 111 compares the previous minimum absolute value stored therein with the absolute value of the currently output LLR (i) to find the determination function, and stores the smaller of the two to determine the soft decoding of the turbo decoding. The minimum absolute value of the LLR (i) output from the value output unit 100 is found.

The comparator 113 compares the minimum absolute value output from the minimum absolute value discriminator 111 with the reference value stored in the reference value storage unit 112 and outputs 1 when the minimum absolute value is smaller than the reference value, and 0 otherwise. .

The reference value storage unit 112 stores the absolute value of the LLR determined according to the system requirements as described above. This means that the iterative decoding is stopped when the error probability of the decoded bit is smaller than the error probability required by the system. Alternatively, the reference value storage unit 112 may store a function of Eb / No obtained from the channel information.

The OR operator 114 performs an OR on the output of the comparator and the MAX_CNT that is output from the counter 140 to indicate that the iterative decoding has been performed for a predetermined number of iterations, and the result is transmitted to the soft decision value output unit 100 of the turbo decoding. Output In other words, the OR operation 114 outputs the first level signal as a repetitive decoding stop signal when the minimum absolute value is smaller than the reference value or when the MAX_CNT reaches the predetermined number of times. In the present invention, the repeated decoding is stopped when the repeated decoding is performed up to MAX_CNT in a state where the minimum absolute value is not smaller than the reference value. The reason is that even if the number of repeated decoding is increased, the decoded data does not converge to a specific value. Because it exists, and the location of the error depends on the number of iterations. Therefore, if repeated decoding is performed up to MAX_CNT, repeat decoding is stopped. The soft decision value output unit 100 of turbo decoding continues or stops iterative decoding according to the output of the logical sum operator 114.

The multiplier 121 multiplies the LLR output from the soft decision value output unit 100 of the turbo decoding with one of the values stored in the weight storage unit 122. The weight storage unit 122 may store different values to output different values at every repetition number. In this case, the counter 140 stores the storage location of the weight storage unit 122 as the selection signal, and increases the selection signal by 1 and outputs the selection signal to the weight storage unit 122 as the number of repetitions increases. The weights stored in 122 may be sequentially read.

As another example, the weights may be zero or one to eliminate the need for multiplier 121.

The adder 123 is initialized with the reset signal of the counter 140 indicating that the first iterative decoding starts, and accumulates the output of the multiplier 121.

The hard decision value output unit 130 is turned on by the repetition decoding stop signal output from the repetition decoding stop unit 110. That is, if the number of repeated decoding is the maximum or the minimum absolute value is smaller than the reference value, the repeated decoding is stopped and the decoded bit is output.

When the hard decision output unit 130 is turned on by the repeated decoding stop signal, the first hard decision unit 131 hard determines the LLR output from the soft decision value output unit 100 of turbo decoding.

The second hard decision unit 132 hardly determines an output value of the adder 123.

The MUX 133 outputs one of the outputs of the first hard decision unit 131 and the second hard decision unit 132 as a decoding bit according to the MAX_CNT signal of the counter 140. That is, if repeated decoding is performed for a specified number of times, the output of the second hard decision unit 132 is output as a decoding bit, and if not, the output of the first hard decision unit 131 is output as a decoding bit.

According to the present invention, by using the minimum absolute value of the LLR output from the turbo decoder as a determination function, if the determination function satisfies a predetermined condition, iterative decoding is stopped, and after progressing for a specified number of repetitions even when the decoding result does not converge By stopping, the decoding cost can be reduced, and even when the decoding result does not converge, the bit error rate can be reduced by accumulating and decoding the weights of the LLRs.

Claims (6)

A soft decision value output unit for turbo decoding that repeatedly decodes the turbo coded data to output a soft decision value, and stops repetitive decoding by a repetition decoding stop signal; If the absolute value of the soft decision value currently output from the soft decoding value output unit of the turbo decoding is smaller than the previously stored minimum absolute value, the absolute value of the currently output soft decision value is stored as the minimum absolute value and the minimum value is output. Absolute value discriminator; A comparator comparing the minimum absolute value with a predetermined reference value and outputting a first level signal if the minimum absolute value is smaller than the reference value; And An output of a repetition decoding stop signal for outputting the repetitive decoding stop signal to the soft determination value output unit of the turbo decoding, when the comparator outputs a first level signal or the soft determination value output unit of the turbo decoding has repeatedly performed a predetermined number of times; Loop stop device of the turbo decoder including the unit. A soft decision value output unit for turbo decoding that repeatedly decodes the turbo coded data to output a soft decision value, and stops repetitive decoding by a repetition decoding stop signal; The soft decision of the turbo decoding is performed when a predetermined determination function obtained from the soft decision value output from the turbo decoding value output unit satisfies a predetermined condition or the soft decision value output unit of the turbo decoding repeatedly performs decoding for a predetermined number of times. A repeated decoding stop unit for outputting the repeated decoding stop signal to a value output unit; A weighting unit for accumulating the soft decision value by giving a predetermined weight; And And a hard decision value output unit which is turned on by the repetition decoding stop signal and hardly determines the output value of the soft decision value output unit of the turbo decoding or the output value of the weighting unit according to whether repetitive decoding is performed for a predetermined number of times and outputs a decoded result. A turbo decoder having a repeat decoding stop function. The method of claim 2, wherein the iterative decoding stop unit If the absolute value of the soft decision value currently output from the soft decoding value output unit of the turbo decoding is smaller than the previously stored minimum absolute value, the absolute value of the currently output soft decision value is stored as the minimum absolute value and the minimum value is output. Absolute value discriminator; A comparator comparing the minimum absolute value with a predetermined reference value and outputting a first level signal if the minimum absolute value is smaller than the reference value; And A repeat decoding stop signal output unit for outputting the repeat decoding stop signal to the soft decision value output unit of the turbo decoding if the comparator outputs the first level or the soft decision value output unit of the turbo decoding performs the repeated decoding for the number of times; A turbo decoder having a repeat decoding stop function. The weighting unit of claim 2 or 3, wherein the weighting unit A multiplier for multiplying a soft decision value output from the soft decision value output unit of the turbo decoding by a predetermined weight; A weight storage unit for storing the weight and outputting the weight to the multiplier; And And a turbo decoder having an iterative decoding stop function including an adder that accumulates the output of the multiplier. The method of claim 4, wherein the weight storage unit And a plurality of weights for storing a plurality of weights and outputting the weights of positions selected by a predetermined selection signal to the multiplier. The method of claim 4, wherein the hard decision value output unit A first hard decision unit for hard decision of the soft decision value output from the soft decision value output unit of the turbo decoding. A second hard decision unit which hardly determines the output of the adder; And And a selector for selecting an output of the first hard decision unit or the second hard decision unit as a decoding bit according to whether or not to perform repeated decoding for the number of times.