作者:方炜1,2, 任勇峰1, 赵利辉1,3, 储成群1
作者单位:1. 中北大学 电子测试技术国家重点实验室, 山西 太原 030051;
2. 中北大学电气与控制工程学院, 山西 太原 030051;
3. 中北大学软件学院, 山西 太原 030051
关键词:双绞线;衰减特性;线缆模型;矢量网络分析仪
摘要:
在航空航天领域,工程特殊性要求数据传输具备极高的可靠性。为实现测量数据的高速远距离可靠传输,该文针对通用的两种双绞线缆,分别采用BT0、KPN和KM3 3种不同线缆参数模型进行建模,利用最小二乘法完成相应的参数估计,分析3种模型在频率高达几百兆赫兹的范围内信号的衰减特性和模型精度。实验结果表明,所采用的3种模型表征的衰减特性与矢量网络分析仪的实测结果具有较好的一致性。其中,KM3模型具有更好的精度,可为进一步分析LVDS信号实现高速远距离传输提供依据。
Research on modeling long-distance communication cable of LVDS
FANG Wei1,2, REN Yongfeng1, ZHAO Lihui1,3, CHU Chengqun1
1. National Key Laboratory for Electronic Measurement Technology, North University of China, Taiyuan 030051, China;
2. School of Electrical and Control Engineering, North University of China, Taiyuan 030051, China;
3. Software School, North University of China, Taiyuan 030051, China
Abstract: In the field of aerospace, engineering particularity requires high reliability of data transmission. To realize high speed, long distance and reliable of measurement data transmission, this paper introduced three different models of BT0, KPN and KM3 for two twisted pair cables, estimated corresponding parameters by least square method, and analyzed attenuation characteristics and modeling precision in range up to several hundred megahertz. The experiment results indicate that the attenuation characteristic based on three models has good consistency with the measured results of vector network analyzer (VNA). The proposed method provides a strong basis to LVDS transmission.
Keywords: twisted-pair cable;attenuation characteristic;cable model;vector network analyzer
2018, 44(12): 147-151 收稿日期: 2018-02-03;收到修改稿日期: 2018-03-15
基金项目: 国家自然科学基金项目(61771434);重点实验室基金项目(61420010414162001002);山西省高等学校科技创新项目(2017156)
作者简介: 方炜(1980-),男,河北张家口市人,讲师,博士,研究方向为动态测试技术与数据传输可靠性
参考文献
[1] 李辉景, 王淑琴, 任勇峰, 等. 基于CRC校验的高速长线LVDS传输设计[J]. 电子器件, 2015, 38(6):1346-1351
[2] 王鋆晟, 孟文博, 文晓哲, 等. 七芯铠装电缆传输特性仿真模型研究[J]. 中国测试, 2017, 43(4):118-124
[3] 瞿林, 陈海亮, 甄国涌, 等. 某飞行器双绞线数据传输系统的设计与实现[J]. 电工技术应用, 2014, 40(6):49-51
[4] 李鹭. 基于MIMO的双绞线高速传输仿真平台研发[D]. 成都:电子科技大学, 2014.
[5] 崔丹丹. G. fast线路仿真仪的研究[D]. 哈尔滨:哈尔滨工业大学, 2015.
[6] ACATAUASSU D, HOST S, CHEN G L, et al. Simple and Causal Copper Cable Model Suitable for G. fast Frequencies[J]. IEEE Transactions on Communications, 2014, 62(11):4040-4051
[7] NEVOSAD M, LAFATA P. Modelling of Propagation Constant of Twisted Pairs and Its Temperature Dependence at G. fast Frequencies[J]. Elektronika ir Elektrotechnika, 2016, 22(2):107-113
[8] POZAR D M. Microwave Engineering[M]. 4th ed. New York:Wiley, 2012:103-107.
[9] 成凌飞, 王泰华. 矿用通信电缆基本电气参数数值模型[J]. 电工技术学报, 2010, 25(12):36-40
[10] LAFATA P. Simple attenuation models of metallic cables suitable for G. fast frequencies[J]. Advances in Electrical and Electronic Engineering, 2015, 13(2):147-155
[11] CHEN W Y. DSL:Simulation Techniques and Standards Development for Digital Subscriber Line System[M]. Indianopolis:Macmillan Technical Pub, 1998:123-168.
[12] ACATAUASSU D, HOST S, CHEN G L, et al. Simple and Causal Twisted-Pair Channel Models for G. fast Systems[C]//IEEE Global Communications Conference. Atlanta:IEEE, 2013.
[13] 吴爱华, 刘晨, 陈锋, 等. 矢网中噪声选件的校准方法研究[J]. 中国测试, 2017, 43(8):7-10
[14] 张懿. 用网络分析仪测量电缆的方法[J]. 中国测试技术, 2008, 34(6):135-137
[15] ASROKIN A, RAHIM M K A, ABIDINA N Z, et al. Cable Modelling Comparison for Twisted-Pair Copper Plant in Malaysia[C]//2015 IEEE International Conference on Control System, Computing and Engineering. George Town:IEEE, 2016.
