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低电压差分信号长线传输的优化设计
2020年电子技术应用第11期
陈晓敏1,薛志超2,张志龙2,文 丰1,袁小康1
1.中北大学 电子测试技术国家重点实验室,山西 太原030051; 2.中国运载火箭技术研究院空间物理重点实验室,北京100076
摘要: 针对影响信号完整性的噪声与衰减进行分析与验证,硬件物理层采取预加重与均衡处理技术、同时进行阻抗匹配优化并设计双重电气隔离,提升信号传输质量。软件链路层进行两级乒乓形式缓存设计以优化传输效率;改进基于CRC校验的反馈重传机制,保证系统实现数据检错重传功能,能适应更多链路异常情况。经验证,优化后在传输长度为100 m时系统可满足180 Mb/s的高可靠传输,满足工程应用技术要求。
中圖分類號: TN914
文獻(xiàn)標(biāo)識碼: A
DOI:10.16157/j.issn.0258-7998.200521
中文引用格式: 陳曉敏,薛志超,張志龍,等. 低電壓差分信號長線傳輸?shù)膬?yōu)化設(shè)計[J].電子技術(shù)應(yīng)用,2020,46(11):104-108.
英文引用格式: Chen Xiaomin,Xue Zhichao,Zhang Zhilong,et al. Optimal design of long-line transmission with low voltage differential signal[J]. Application of Electronic Technique,2020,46(11):104-108.
Optimal design of long-line transmission with low voltage differential signal
Chen Xiaomin1,Xue Zhichao2,Zhang Zhilong2,Weng Feng1,Yuan Xiaokang1
1.National Key Laboratory for Electronic Measurement Technology,North University of China,Taiyuan 030051,China; 2.Key Laboratory of Space Physics, China Academy of Launch Vehicle Technology,Beijing 100076,China
Abstract: The noise and attenuation that affect the signal integrity are analyzed and verified. The hardware physical layer adopts pre-emphasis and equalization processing technology. The impedance matching optimization and double electrical isolation are designed to improve the signal transmission quality. At the software link layer, a two-level ping-pong buffer is designed to optimize transmission efficiency. The feedback retransmission mechanism based on cyclic redundancy check is improved to ensure that the system realizes the function of data error detection and retransmission, and can adapt to more abnormal link conditions.It has been verified that when the optimized transmission length is 100 m, the system can achieve a high reliable transmission of 180 Mb/s, which meets the technical requirements of engineering applications.
Key words : low voltage differential signal;signal integrity;pre-emphasis;ping-pong;feedback retransmission mechanism

0 引言

    在實際工程試驗環(huán)境中,飛行器的多種傳感器及圖像數(shù)據(jù)需要通過穿艙差分電纜傳輸至地面測控臺[1],因此對于數(shù)據(jù)在穿艙差分電纜中的傳輸長度、可靠性有很高要求。基于以上應(yīng)用場合,對低電壓差分信號傳輸鏈路硬件物理層與軟件鏈路層分別做優(yōu)化設(shè)計,所有設(shè)計模塊及信息處理均在FPGA平臺上實現(xiàn),F(xiàn)PGA在單時鐘周期可執(zhí)行多個任務(wù),與單片機(jī)相比FPGA對數(shù)據(jù)響應(yīng)與處理速度更快,在高速數(shù)據(jù)處理方面有很大優(yōu)勢[2]。




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作者信息:

陳曉敏1,薛志超2,張志龍2,文  豐1,袁小康1

(1.中北大學(xué) 電子測試技術(shù)國家重點實驗室,山西 太原030051;

2.中國運(yùn)載火箭技術(shù)研究院空間物理重點實驗室,北京100076)

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