• Title/Summary/Keyword: Parallel BCH Decoder

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Design of High-performance Parallel BCH Decoder for Error Collection in MLC Flash Memory (MLC 낸드 플래시 메모리 오류정정을 위한 고속 병렬 BCH 복호기 설계)

  • Choi, Won-Jung;Lee, Je-Hoon;Sung, Won-Ki
    • The Journal of the Korea Contents Association
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    • v.16 no.3
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    • pp.91-101
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    • 2016
  • This paper presents the design of new parallel BCH decoder for MLC NAND flash memory. The proposed decoder supports the multi-byte parallel operations to enhance its throughput. In addition, it employs a LFSR-based parallel syndrome generator for compact hardware design. The proposed BCH decoder is synthesized with hardware description language, VHDL and it is verified using Xilinx FPGA board. From the simulation results, the proposed BCH decoder enhances the throughput by 2.4 times than its predecessor employing byte-wise parallel operation. Compared to the other counterpart employing a GFM-based parallel syndrome generator, the proposed BCH decoder requires the same number of cycles to complete the given works but the circuit size is reduced to less than one-third.

Design of Lightweight Parallel BCH Decoder for Sensor Network (센서네트워크 활용을 위한 경량 병렬 BCH 디코더 설계)

  • Choi, Won-Jung;Lee, Je-Hoon
    • Journal of Sensor Science and Technology
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    • v.24 no.3
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    • pp.188-193
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    • 2015
  • This paper presents a new byte-wise BCH (4122, 4096, 2) decoder, which treats byte-wise parallel operations so as to enhance its throughput. In particular, we evaluate the parallel processing technique for the most time-consuming components such as syndrome generator and Chien search owing to the iterative operations. Even though a syndrome generator is based on the conventional LFSR architecture, it allows eight consecutive bit inputs in parallel and it treats them in a cycle. Thus, it can reduce the number of cycles that are needed. In addition, a Chien search eliminates the redundant operations to reduce the hardware complexity. The proposed BCH decoder is implemented with VHDL and it is verified using a Xilinx FPGA. From the simulation results, the proposed BCH decoder can enhance the throughput as 43% and it can reduce the hardware complexity as 67% compared to its counterpart employing parallel processing architecture.

Low-Complexity Triple-Error-Correcting Parallel BCH Decoder

  • Yeon, Jaewoong;Yang, Seung-Jun;Kim, Cheolho;Lee, Hanho
    • JSTS:Journal of Semiconductor Technology and Science
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    • v.13 no.5
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    • pp.465-472
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    • 2013
  • This paper presents a low-complexity triple-error-correcting parallel Bose-Chaudhuri-Hocquenghem (BCH) decoder architecture and its efficient design techniques. A novel modified step-by-step (m-SBS) decoding algorithm, which significantly reduces computational complexity, is proposed for the parallel BCH decoder. In addition, a determinant calculator and a error locator are proposed to reduce hardware complexity. Specifically, a sharing syndrome factor calculator and a self-error detection scheme are proposed. The multi-channel multi-parallel BCH decoder using the proposed m-SBS algorithm and design techniques have considerably less hardware complexity and latency than those using a conventional algorithms. For a 16-channel 4-parallel (1020, 990) BCH decoder over GF($2^{12}$), the proposed design can lead to a reduction in complexity of at least 23 % compared to conventional architecttures.

Design of BCH Code Decoder using Parallel CRC Generation (병렬 CRC 생성 방식을 활용한 BCH 코드 복호기 설계)

  • Kal, Hong-Ju;Moon, Hyun-Chan;Lee, Won-Young
    • The Journal of the Korea institute of electronic communication sciences
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    • v.13 no.2
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    • pp.333-340
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    • 2018
  • This paper introduces a BCH code decoder using parallel CRC(: Cyclic Redundancy Check) generation. Using a conventional parallel syndrome generator with a LFSR(: Linear Feedback Shift Register), it takes up a lot of space for a short code. The proposed decoder uses the parallel CRC method that is widely used to compute the checksum. This scheme optimizes the a syndrome generator in the decoder by eliminating redundant xor operation compared with the parallel LFSR and thus minimizes chip area and propagation delay. In simulation results, the proposed decoder has accomplished propagation delay reduction of 2.01 ns as compared to the conventional scheme. The proposed decoder has been designed and synthesized in $0.35-{\mu}m$ CMOS process.

An Implementation of parallel Decoder for TEC-BCH codes (3중 오류정정 BCH부호의 병렬복호기 구현에 관한연구)

  • Kim, Chang-Soo;Rhee, Man-Young
    • Proceedings of the KIEE Conference
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    • 1988.07a
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    • pp.183-185
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    • 1988
  • Some efficient methods for solving the equations over GF($2^m$) are proposed in this paper. Using these algorithms, parallel decoder for a triple-error-correcting(31, 16) BCH code is implemented. By incorporating with ROM and PAL which are inserted in a decoder, the complex logic circuits can be substantially reduced and therefore a high speed decoder can be constructed.

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A LDPC Decoder for DVB-S2 Standard Supporting Multiple Code Rates (DVB-S2 기반에서 다양한 부호화 율을 지원하는 LCPC 복호기)

  • Ryu, Hye-Jin;Lee, Jong-Yeol
    • Journal of the Institute of Electronics Engineers of Korea SD
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    • v.45 no.2
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    • pp.118-124
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    • 2008
  • For forward error correction, DVB-S2, which is the digital video broadcasting forward error coding and modulation standard for satellite television, uses a system based the concatenation of BCH with LDPC inner coding. In DVB-S2 the LDPC codes are defined for 11 different code rates, which means that a DVB-S2 LDPC decoder should support multiple code rates. Seven of the 11 code rates, 3/5, 2/3, 3/4, 4/5, 5/6, 8/9, and 9/10, are regular and the rest four code rates, 1/4, 1/3, 2/5, and 1/2, are irregular. In this paper we propose a flexible decoder for the regular LDPC codes. We combined the partially parallel decoding architecture that has the advantages in the chip size, the memory efficiency, and the processing rate with Benes network to implement a DVB-S2 LDPC decoder that can support multiple code rates with a block size of 64,800 and can configure the interconnection between the variable nodes and the check nodes according to the parity-check matrix. The proposed decoder runs correctly at the frequency of 200MHz enabling 193.2Mbps decoding throughput. The area of the proposed decoder is $16.261m^2$ and the power dissipation is 198mW at a power supply voltage of 1.5V.