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| Industrial ring network time synchronization based on
waydelay weighted feedback algorithm |
| ZHANG Han, FENG Dong-qin, CHU Jian |
| Institute of Advanced Process Control, Zhejiang University, Hangzhou 310027, China |
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Abstract The backup link in ring topology was used as feedback path according to the characteristic of the physical link in order to satisfy the requirement of high precise time synchronization in large scale industrial network. The accumulated offset was feedbacked to all devices in the ring network by master device. Based on the accumulated offset and the delay of synchronization frames between each device in the ring network, the path weighted feedback algorithm was introduced to improve the precision of synchronization of each slave device with offset compensation. Then the high precise time synchronization of large scale industrial ring network was achieved. The offset of each device was calculated using waydelay weighted feedback algorithm based on the offset of onejump synchronization and the accumulated offset of boundary clock algorithm. The theoretical analysis and experimental results show that the algorithm can achieve higher precise time synchronization in industrial ring network.
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Published: 19 March 2012
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基于路径加权反馈的工业环网时钟同步方法
为了实现大规模环形网络系统中所有结点的高精度时钟同步,根据环形链路存在物理环路的特点,通过环形链路中的备用链路,由主时钟进行累积同步偏差反馈.基于该累积同步偏差和所有设备间时钟同步数据帧在环网中的传输时延,对累积偏差进行路径加权反馈,实现系统中所有时钟的偏差补偿,提高其同步精度,从而实现大规模工业环形网络的高精度时钟同步.在分析单跳同步偏差以及边界时钟累积同步偏差的基础上,得出基于路径加权反馈后所有设备的同步偏差,理论证明了该算法的有效性.进一步通过实验验证,该算法显著提高了环形网络时钟同步精度
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| [1] IEEE std 802.3 2002, Carrier sense multiple access with collision detection (CSMA/CD) access method and physical layer specification [S]. New York: IEEE, 2002.
[2] EPA criterion for industrial control system,digital communication for measurement and control [S]. Beijing: National Standard Committee, 2004.
[3] IEEE std 1588 2008, IEEE standard for a precision clock synchronization protocol for networked measurement and control systems [S]. New York: IEEE, 2008.
[4] GADERER G, LOSCHMIDT P, SAUTER T, et al. Investigations on fault tolerant clock synchronization within a powerline communication structure [C]∥2006 IEEE International Symposium on Power Line Communications and Its Applications. Orlando: IEEE, 2006: 178183.
[5] 黄文君,遇彬.基于FPGA的精确时钟同步方法[J\].浙江大学学报:工学版,2007,41(10): 16971700.
HUANG Wenjun, YU Bin. Method for precise time synchronization based on FPGA [J]. Journal of Zhejiang University: Engineering Science, 2007, 41(10): 16971700.
[6] KOHLER D. A practical implementation of an IEEE1588 supporting ethernet switch [C\]∥ Precision Clock Synchronization for Measurement, Control and Communication. Vienna: IEEE, 2007: 134137.
[7] 黄文君,金建祥,冯冬芹,等.控制系统的冗余策略和实现准则[J].仪器仪表学报,2004, 25(4): 545547.
HUANG Wenjun, JIN Jianxiang, FENG Dongqin, et al. Research on redundancy strategy and design rule in control system [J]. Chinese Journal of Scientific Instrument, 2004, 25(4): 545547.
[8] EIDSON J, HAMILTON B. IEEE1588 node synchronization improvement by high stability oscillators [C]∥Workshop on IEEE 1588, Standard for a Precision Clock Synchronization Protocol for Networked Measurement and Control Systems. Gaithersburg, Maryland: IEEE, 2003: 95101.
[9] 张先富,冯冬芹.基于加权最小二乘法的精确时钟同步算法研究与实现[J].传感技术学报,2008,21(9): 15561560.
ZHANG Xianfu, FENG Dongqin. Realization of precise time synchronization algorithm based on weighted leastsquares algorithm[J]. Chinese Journal of Sensors and Actuators, 2008, 21(9): 15561560.
[10] FERRARI P, FLAMMINI A, MAMRIOLI D, et al. Synchronization of the probes of a distributed instrument for realtime ethernet networks [C]∥ IEEE International Symposium on ISPCS. Vienna: IEEE, 2007: 3340. |
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