KR101206176B1 - High-performance concatenated bch based forward error correction system and method - Google Patents

Abstract

High performance concatenated BCH-based forward error correction system using BCH (Bose-Chaudhuri-Hocquenghen) (3920,3824,8) code and BCH (996,956,4) code for internal long-band optical fiber communication system; and The method is disclosed.
In one embodiment, the high performance concatenated BCH based forward error correction system and method compensates for errors occurring in a channel using forward error correction using concatenated BCH codes, thereby providing ^10-15 decoders after six iterations of decoding. It has a high coding gain performance of 9.19dB at the output bit error rate, and the concatenated BCH code has the same frame structure as RS (255,239,8), which is a standard forward error correction. It is easy.

Description

HIGH PERFORMANCE CONCATENATED BCH BASED FORWARD ERROR CORRECTION SYSTEM AND METHOD}

Embodiments of the present invention are a forward error correction (FEC) system that corrects an error occurring in data during a data transmission process at a transmitting end in a digital communication system, and an external code is a BCH (for wideband long distance optical communication system). Bose-Chaudhuri-Hocquenghen) (3920,3824,8) codes and internal codes are directed to forward error correction systems and methods using BCH (996,956,4) codes.

Reed-Solomon (RS) code and BCH code are used for forward error correction technology that can find and correct a number of errors that occur during transmission in optical communication, digital video broadcasting, memory, and data storage systems. Is widely used.

The forward error correction technique inserts and transmits additional information called parity, which contains information on the shape of the original signal, and corrects a certain amount of error at the receiving end based on the information contained in the original signal and parity. Is an error control technique.

로 표현되는 갈로아체(GF, Galois field)의 지수인 m으로부터

의 수식에 의한 관계로 정의된다.

는 실제 데이터의 심볼 수를 의미하며,

에서 mt 심볼의 패리티 심볼로부터 데이터 전송상에서 생길 수 있는 오류를 부호어당 t 개까지 정정할 수 있다. 일반적으로 BCH 부호라 하면 각 심볼이 1비트(bit)로 이루어진 바이너리(binary) BCH 부호를 가리키며, 본 발명에서도 마찬가지로 BCH 부호는 바이너리 BCH 부호를 의미한다.A typical form of representing the BCH code is BCH (n, k, t). n is the total number of codeword symbols to be encoded, including the original data and the parity as a whole, and t is the maximum number of error symbols that can be corrected among the codewords.

From m, the exponent of Galois field (GF)

It is defined as the relationship by the formula of.

Means the number of symbols in the actual data,

Up to t errors per codeword can be corrected in the data transmission from the parity symbol of the mt symbol at. In general, a BCH code refers to a binary BCH code consisting of 1 bit, and in the present invention, a BCH code means a binary BCH code.

로 계산되어진다. RS 부호의 경우 각 심볼은 m비트로 이루어져 있다.The RS sign is also expressed as RS (n, k, t), where t is

Is calculated. In the case of the RS code, each symbol consists of m bits.

In broadband, long-distance optical communications systems using dense-wavelength division multiplexing (DWDM) technology, transmission distances range from hundreds of kilometers to thousands of kilometers and data throughput reaches 100Gb / s. In such a broadband long distance optical communication system, a large amount of data is transformed according to the channel environment of the transmission path and causes errors during transmission. To alleviate the amount of errors that occur during transmission, the 8-byte error correction RS (255,239,8) code has been adopted by the International Telecommunication Union (ITU-T) as a standard forward error correction technology to date to reduce the amount of errors that occur during transmission. It has become an element.

However, only RS (255,239,8) codes have a problem in that they do not satisfy the Net Coding Gain (NCG) performance required by a long distance optical communication system. Accordingly, ITU-T discussed the standard of forward error correction structure that can guarantee the very high data rate and reduce the bit error rate (BER) significantly compared to RS (255,239,8) codes. In December, we released the G.975.1 standard recommendation, which consists of eight forward error corrections with high coding gains for DWDM optical communication systems.

The forward error correction codes of the G.975.1 standard recommendation provide high coding gain performance of 8 to 9 dB, but do not share the frame structure with the standard forward error correction RS (255,239,8) code and are currently required 9.0. There is a problem that actual implementation that satisfies a high coding gain of 100 dB or more and 100 Gb / s data throughput is difficult. Based on this experience, ITU-T recently established a standard for 100Gb / s high-speed, high-performance forward error correction codes for optical transport unit 4 (OTU4), which share the frame structure with RS (255,239,8). It has a coding gain of more than 9.0dB.

The characteristics of the forward error correction codes that are currently proposed are that they all use a concatenated code method that uses a block code. A description of the concatenated code scheme is shown in FIG. Referring to FIG. 1, the concatenated coding scheme is composed of an internal coder, an external code, and an interleaver / deinterleaver that rearranges data sequences therebetween. Have. As the number of iterative decoding increases, the error correction performance of the forward error correction system is improved.

The process of the concatenated code forward error correction system will be described in detail. First, the forward error correction system first determines 110 the iteration decoding number N according to a desired error correction performance and a design condition. Then, the external terminal 121 first encodes the raw data to be transmitted by the transmitter 120. Thereafter, in order to increase resistance to burst errors, the data stream is rearranged through interleaving 122 and then internally encoded 123.

The receiving end 130 performs the internal decoding 131 in the reverse order, and rearranges the data string again according to the external code through the deinterleaving 132 and then performs the external decoding 133. If the number of iterative decoding reaches N predetermined times, the decoding is stopped. Otherwise, the decoding is again interleaved 134 and the process returns to the internal decoding step.

By concatenating decoding in this manner, high coding gain performance can be obtained. Codes currently proposed for ITU-T have achieved coding gain performance of 9.0dB or more near the Shannon limit, and it is remarkable that both BCH codes are used as external / internal codes.

Forward error correction system with high error correction capability matching the standard RS (255,239,8) code and frame structure for the development of next generation broadband optical communication system that can reuse existing network for the same reason as described so far Has become an important challenge.

The RS (255,239,8) code, a standard forward error correction in optical communication systems, provides 6.2dB of net gain gain (NCG) performance at ^10-15 decoder output bit error rate (BER). It is not enough to support a s-class broadband long distance optical communication system.

One embodiment of the present invention has the same structure as the RS (255,239,8) code, which is the standard forward error correction, has a high coding gain of 9.0dB or more at a ^10-15 decoder output bit error rate, and is a low complexity and efficient high performance forward error correction performance. A forward error correction system and method are provided.

A high performance concatenated BCH based forward error correction system for achieving the above embodiment comprises: an external encoder encoding raw data, an interleaver interleaving the encoded data, and an internal encoder encoding the interleaved data; And an internal decoder for decoding the data encoded by the transmitter, a deinterleaver for deinterleaving the decoded data, an external decoder for decoding the deinterleaved data, and interleaving the data decoded by the external decoder. It includes a receiving end including an interleaver provided to.

In addition, as a technical method for achieving the above embodiment, a high performance concatenated BCH-based forward error correction method for performing encoding at a transmitting end may include: an 8-channel BCH (3920, 3824, 8) external encoder encodes raw data and thus an external code. Generating a parity of; Interleaving the outer code by the interleaver; And a 32-channel BCH (996, 956, 4) internal encoder encodes the interleaved outer code to generate parity of the inner code.

In addition, as a technical method for achieving the above embodiment, a high performance concatenated BCH based forward error correction method for performing decoding at the receiving end, the 32-channel BCH (996, 956, 4) internal decoder to decode the data received from the transmitting end ; A deinterleaver deinterleaving the decoded data; An 8-channel BCH (3920,3824,8) external decoder to decode the deinterleaved data; The processor terminating the decoding if the number of decoding is equal to the predetermined number of repeated decoding; And if the number of decoding is less than the predetermined number of repetitive decoding, the interleaver interleaves the data decoded by an 8-channel BCH (3920,3824,8) external decoder to provide the 32-channel BCH (996,956,4) internal decoder. Include.

According to one embodiment of the present invention, a BCH code concatenation (concatenated BCH code) by using the compensation of the errors in the channel using a forward error correction, after six iterations ^10-15 decoder output bit error rate of 9.19dB at high Has coding gain performance.

In addition, according to an embodiment of the present invention, since the concatenated BCH code has the same frame structure as that of RS (255,239, 8), which is a standard forward error correction, the system is easily compatible with the optical communication system network currently used.

1 is a flowchart illustrating an algorithm of a conventional concatenated code error correction system.
2 is a flowchart illustrating an error increase prevention algorithm of a BCH code according to an embodiment of the present invention.
3 is a block diagram illustrating a concatenated BCH codec system according to an embodiment of the present invention.
4 is an exemplary view showing an interleaving method according to the G.975.1 I.3 standard for explaining the present invention.
5 is a diagram illustrating a frame structure of a conventional concatenated coded forward error correction method.
6 is a diagram illustrating a frame structure of a concatenated code forward error correction method according to an embodiment of the present invention.
7 is a diagram illustrating how an outer code is aligned within one frame of OTU4 according to an embodiment of the present invention.
8 is a diagram illustrating how internal codes are aligned within one frame of OTU4 according to an embodiment of the present invention.

Hereinafter, embodiments according to the present invention will be described in detail with reference to the accompanying drawings. However, the present invention is not limited to or limited by the embodiments. The embodiment is specifically described based on an optical channel transport unit 4 (OTU4) frame structure, and the present invention can be equally applied to several other optical communication systems such as a Synchronous Optical Network (SONET) or a Synchronous Digital Hierarchy (SDH). . Like reference symbols in the drawings denote like elements.

The BCH code is the most widely used in communication systems and is widely used in various standards such as the International Telecommunication Union (ITU-T) optical standard and the European Telecommunication Standards Association (ETSI) next generation digital video broadcasting (DVB-S2) standard. It is a forward error correction technique.

로 표현되는 갈로아체(GF, Galois field)의 지수인 m으로부터

의 수식에 의한 관계로 정의된다.

는 실제 데이터의 비트 수를 의미하며,

에서 mt 비트의 패리티(parity) 비트로부터 데이터 전송상에서 생길 수 있는 오류를 부호당 t 개까지 정정할 수 있다.A typical form of representing the BCH code is BCH (n, k, t). n is the length of all code bits to be encoded, including the entire raw data and parity, and t is the maximum number of error bits that can be corrected during the code.

From m, the exponent of Galois field (GF)

It is defined as the relationship by the formula of.

Means the number of bits of actual data,

Up to t errors per code can be corrected from a parity bit of mt bits at.

In BCH decoding, there is a possibility that an error may increase when a decoding attempt fails in a mathematical theory or a conventional technique, which is a principle of technology. However, in the present invention, even if each BCH code fails in a decoding attempt, an error does not occur. To the system.

The BCH code traditionally uses syndrome-based decoding to generate an error-position polynomial with a maximum order of t to find the location of the error. If the degree of the error location polynomial generated during the decoding process is order t, it is one of cases where an uncorrectable error has occurred or t errors can be corrected. Therefore, if the degree of error position polynomial is the maximum order, t error correction signals must be generated to correct the error. Otherwise, it can be determined that an uncorrectable error has occurred.

2 is a flowchart illustrating an error increase prevention algorithm of a BCH code according to an embodiment of the present invention.

The processor first detects the order of the error location polynomial (210). If the order of the error location polynomial is not the maximum order, a correctable error has occurred and the processor terminates the algorithm. If the error location polynomial has the maximum order, the processor finds the error location from the error location polynomial and starts counting the number of correction signals to correct the error (220). If the number of corrected signals coincides with the maximum order of the error location polynomial (230), the algorithm terminates because a correctable error has occurred. Otherwise, the processor generates a FAIL signal (240) that indicates a decode failure. Do not decode.

3 is a block diagram illustrating a concatenated BCH codec system according to an embodiment of the present invention.

In the concatenated BCH codec system, the transmitting end includes a BCH (3920,3824,8) external encoder 310, an interleaver 350, and a BCH (996,956,4) internal encoder 320, and a receiving end is inside the BCH (996,956,4). The decoder 330, the deinterleaver 360, the BCHs 3920, 3824, 8, the external decoder 340, and the interleaver 370 are included. The interleavers present in both the transmitting and receiving ends are combined to correct an error in the data string generated in the transmission path 380.

Referring to Figure 3 describes the principle of operation of the BCH codec system according to an embodiment of the present invention.

Initially, the raw data is encoded in the 8-channel BCH 3920, 3824, 8 external encoder 310, and the raw data and the generated parity are stored at designated positions of OTU4 frames, respectively. After 8 frames have passed the BCH 3920, 3824, 8 external encoder 310, the encoded data are interleaved in the interleaver 350, and then transmitted to the 32-channel BCH (996,956, 4) internal encoder 320. It is then re-encoded and stored again in the designated location of the OTU4 frame. Subsequently, concatenated codes are transmitted along the transmission path 380, and the receiver performs decoding in the exact opposite order.

The corrected raw data can be found from the output of the BCH 3920, 3824, 8 external decoder 340, and the higher the number of iterative decodings, the higher the coding gain performance of the processor. Specifically, it is 8.83dB for two iterations, 9.05dB for three iterations, 9.13dB for four iterations, 9.13dB for five iterations, 9.16dB for six iterations, and 9.19dB for six iterations based on the ^10-15 decoder output bit error rate. Provides coding gain performance.

The BCH 3920,3824,8 sign used as the outer code is computed on the GF (2 ¹² ) galloise. Each code consists of 3824 bits of data and 96 bits of parity and can be found and corrected when 8 or less errors occur within the 3920 bits of code. The primitive polynomial of the outer code is given by Equation 1 below.

The BCH (996,956,4) code used as the internal code is computed on GF (2 ¹⁰ ) galloise. Each code consists of 956 bits of data and 40 bits of parity and can be found and corrected when four or less errors occur within a 996 bits of code. The primitive polynomial of the outer sign is given by Equation 2 below.

Interleaving / deinterleaving takes the same method as applied in the ITU-T G.975.1 I.3 standard. Figure 4 shows the interleaving applied to the ITU-T G.975.1 I.3 standard specification. Eight frames 410 consisting of 255 symbols per frame cyclically exchange each other's symbols to create eight new frames. Each symbol consists of 128 bits.

In the general concatenated code forward error correction method, an outer code generates a code by treating raw data as its data portion, and an inner code generates a code by treating an external code including the generated raw data as its data portion. . However, in the present invention, unlike the conventional concatenated coding schemes, only the outer data and the inner code use the original data as the message of the sign. Comparing FIG. 5 with FIG. 6 shows such a feature.

5 is a diagram illustrating a structure of a concatenated code forward error correction method according to an embodiment of the prior art.

As shown in FIG. 5, in a general concatenated code forward error correction method, first, an outer encoder generates an outer code parity 520 by treating raw data 510 as data of a code, and an inner coder generates an original code and an outer code. The internal parity parity 530 is generated by treating the entire parity as data of the codeword.

6 is a diagram illustrating a structure of a concatenated code forward error correction method according to an embodiment of the present invention. In the present invention, as shown in FIG. 6, the outer coder treats the raw data 610 as the coded data to generate the outer code parity 620. However, the inner coder includes only the raw data except the outer code parity. In this case, the internal code parity 630 is generated. Since the parity of the outer / internal code is discarded after the decoder, there is little reason that the inner code must correct the error of the outer code. However, in order to minimize the possibility of an uncorrectable error pattern, the error correction capability of the outer code, which is not assisted by the inner code, is set higher than that of the conventional concatenated code forward error correction method.

One OTU4 frame consists of 32640 bits. Among them, 30592 bits and 2048 bits are allocated to the raw data and the parity, respectively.

In the embodiment of the present invention, the 8-channel BCHs 3920, 3824, 8 external codes are used. Since the data length of the external codes is 3824 bits, the 8-channel 30592 bits cover all the data of the OTU4 frame. Since parity is 8 channels of 96 bits for each channel, 768 bits are used among 2048 bits.

The internal code of the BCH (996, 956, 4) is composed of 32 channels. Since the data length of the internal code is 956 bits, the total length of the 32 channels is 30592 bits in the same way as the external code. Since parity is 32 channels with 40 bits for each channel, a total of 1280 bits are used. Since the total amount of parity used by the 8-channel outer code is 768 bits, the total number of parity used by the inner code is 1280 bits, which is exactly the same as the space allocated as parity in the OTU4 frame structure.

7 illustrates how an outer code is aligned within one frame of OTU4 according to an embodiment of the present invention. Data from the OTU4 framer is sequentially transmitted one by one symbol 710 consisting of 128 bits. The structure of one symbol in the outer code is divided into eight channels 720 by 16 bits for each channel and processed. It is done. In this way, after a total of 255 symbols are processed, one frame is processed. When the outer code is processed, the inner code parity 731, which stores a total of 1280 bits of 160 bits 721 for each channel, is passed without any manipulation.

8 illustrates how an inner code is aligned within one frame of OTU4 according to an embodiment of the present invention. An internal code consisting of 32 channels 810 is processed by dividing each symbol by 4 bits for each channel. Like the outer code, once 255 symbols are processed, one frame 820 is processed. When the inner code is processed, the outer code parity 821 stores 24 bits (811) of 768 bits for each channel. It will pass without any manipulation.

As described above, the high performance forward error correction system structure based on the concatenated BCH provides high coding gain performance at the ^10-15 decoder output bit error rate and is fully compatible with OTU4 frame and standard RS (255,239,8) forward error correction system. Accordingly, one embodiment of the present invention has potential application to the application of the high speed forward error correction system for broadband long distance optical communication system.

In addition, embodiments of the present invention are directed to DVB-T2 / S2 mobile broadcasting systems and optical media such as hard disks, CD-ROMs, DVDs, and ROMs, RAMs, flash memories, and the like. A forward error correction system of the memory system is included.

In the present invention as described above has been described by the specific embodiments, such as specific components and limited embodiments and drawings, but this is provided to help a more general understanding of the present invention, the present invention is not limited to the above embodiments. For those skilled in the art, various modifications and variations are possible from these descriptions. It is therefore to be understood that within the scope of the appended claims, the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. .

310: BCH (3920,3824,8) external encoder
320: BCH (996,956,4) internal encoder
330: BCH (996,956,4) internal decoder
340: BCH (3920,3824,8) external decoder
350: interleaver
360: deinterleaver

Claims (8)

A transmitter comprising an external encoder for encoding raw data, an interleaver for interleaving the encoded data, and an internal encoder for encoding the interleaved data; And
An internal decoder to decode the data encoded by the transmitter, a deinterleaver to deinterleave the decoded data, an external decoder to decode the deinterleaved data, and interleave the data decoded by the external decoder to interleave the data. Receiving end including interleaver provided
Including,
The receiving end,
High performance concatenated BCH based forward error correction system performing repetitive decoding for the number of times selected by the transmitter. delete The method of claim 1,
The receiving end,
10 ^-15 decoder output bit error rate reference number of times of the iterative decoding,
Decoding at the receiving end has coding gain performance of 8.83dB for two iterations, 9.05dB for three iterations, 9.13dB for four iterations, 9.16dB for five iterations, 9.19dB for six iterations and 9.19dB for six iterations. A high performance concatenated BCH based forward error correction system. The method of claim 1,
The external encoder uses 8 channels of BCH (3920, 3824, 8) external encoder,
The internal encoder uses a 32 channel BCH (996, 956, 4) internal encoder,
The internal decoder uses a 32-channel BCH (996, 956, 4) internal decoder,
The external decoder uses an 8-channel BCH (3920, 3824, 8) external decoder,
And the interleaver and the deinterleaver satisfy the ITU-T G.975.1 I.3 specification. The method of claim 1,
The code for performing the encoding and decoding,
High performance concatenated BCH based forward error correction system compatible with OTU4 (Optical Transport Unit 4) frame structure and RS (255,238,8) codes. An eight-channel BCH (3920,3824,8) outer encoder encoding raw data to generate parity of the outer code;
Interleaving the outer code by an interleaver;
A 32-channel BCH (996, 956, 4) internal encoder encoding the interleaved outer code to generate parity of the inner code; And
Transmitting the parity of the outer code, the interleaved outer code, and the parity of the inner code to a receiving end.
The high performance concatenated BCH-based forward error correction method for performing the encoding at the transmitting end. Decoding, by the 32-channel BCH 996, 956, 4 internal decoder, the data received from the transmitting end;
A deinterleaver deinterleaving the decoded data;
An 8-channel BCH (3920,3824,8) external decoder to decode the deinterleaved data;
The processor terminating the decoding if the number of decoding is equal to the predetermined number of repeated decoding; And
An interleaver interleaving the data decoded by an 8-channel BCH (3920,3824,8) external decoder and providing it to the 32-channel BCH (996,956,4) internal decoder if the number of decoding is less than the predetermined number of repeated decoding.
The high performance concatenated BCH-based forward error correction method for performing decoding at the receiving end. The method of claim 7, wherein
Steps to prevent errors if the processor determines that an error has failed by checking for errors when decoding the data
Further comprising a high performance concatenated BCH based forward error correction method for performing decoding at the receiving end.

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