使用 Xilinx 设计和实现带纠错功能的汉明码

International Journal of Scientific Research in Computer Science, Engineering and Information Technology Pub Date : 2024-07-25 DOI:10.32628/cseit24104117

Ms. Delphine Mary. P, Simran. A

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引用次数: 0

摘要

先进的电路非常注重无差错通信。传输过程中发生的信息错误可能会导致接收到不正确的信息。电路中经常使用纠错码来保护存储在存储器和寄存器中的数据。其中一种正向纠错码是汉明码。它采用偶奇偶校验或奇奇偶校验方法。在这里，我们使用偶数奇偶校验方法来实现汉明码。与奇偶校验方法相比，汉明码的效果更好。这里的汉明码是在 Xilinx 中实现的，使用的是带有 4 个冗余位的 7 位数据传输方案。DSCH（数字原理图编辑器和仿真器）程序中也使用了这种方法。为了发现双位错误，采用了特定的奇偶校验位。在这种情况下，我们采用 SEDC-DED（单比特错误检测和纠正-双比特错误检测）方法进行错误检测和纠正。

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Design and Implementation of Hamming Code with Error Correction Using Xilinx

Advanced electrical circuits are very concerned about error-free communication. Information mistakes that happen during transmission may result in incorrect information being received. Error correction codes are frequently employed in electrical circuits to safeguard the data stored in memory and registers. One of these forward error correcting codes is the hamming code. It either employs the even parity or odd parity check approach. Here, we used the even parity check approach to implement hamming code. Compared to the parity check approach, hamming code is better. The hamming code is implemented here in Xilinx and uses a 7-bit data transmission scheme with 4 redundant bits. It is also used in the DSCH (Digital Schematic Editor & Simulator) programme. To find double bit errors, a specific parity bit is employed. For error detection and correction in this instance, we employed the SEDC-DED (Single Bit Error Detection and Correction-Double Bit Error Detection) method.

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International Journal of Scientific Research in Computer Science, Engineering and Information Technology

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