基于FPGA的北斗驯服铷原子频标装置的研制

doi:10.3969/j.issn.1000-1158.2020.03.17

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摘要为了提高铷原子钟频率的准确度和稳定度,设计了基于FPGA技术的多路输出北斗驯服铷原子频标装置。装置采用粗测和细测的时间间隔测量方法实现铷原子频率的驯服和时间跟踪与同步。采用模块化设计和编程,提高了装置的通用性和可移植性。以铯原子钟时间频率为参照,利用该装置对铷原子钟驯服前后的数据进行多次比对测试,结果表明其频率的相对准确度达到了1.5×10^-13,相对稳定度达到6.97×10^-13,与驯服之前相比,铷原子钟频率的准确度和稳定度均得到大幅提高和改善。

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	王亚军
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关键词 ：计量学, 铷钟, 北斗驯服, 同步, 时间间隔, 授时

Abstract：In order to improve the accuracy and stability of the rubidium atomic clock frequency, equipment with multi output GNSS taming rubidium atomic frequency standard is designed based on FPGA technology. The taming and time tracking and synchronization of the rubidium atomic frequency are realized by the method of measuring the time interval using the rough and the fine measurements. Modular design and programming are used to improve the generality and transferability of the device.The data of rubidium atomic clock before and after taming were compared and tested many times taking the time and frequency of cesium atomic clock as reference. The results show that the relative accuracy of the device frequency reaches 1.5×10^-13 and relative stability runs up to 6.97×10^-13. Compared with before taming, the accuracy and stability of rubidium atomic clock frequency have been greatly improved the device not only improves the performance key parameters of rubidium atomic clock, but also broadens its applicability.

Key words： metrology rubidium clock BeiDou taming synchronization time interval time service

PACS:

TB939

基金资助:国家重点研发计划(2017YFF0212000)

作者简介: 王亚军(1984-),男,安徽亳州人,北京市计量检测科学研究院工程师,主要从事测试计量技术及仪器方面的研究。Email: wangyajun@bjjl.cn

引用本文:

王亚军,张磊,谷扬,黄艳,康婷婷. 基于FPGA的北斗驯服铷原子频标装置的研制[J]. 计量学报, 2020, 41(3): 359-362.
WANG Ya-jun,ZHANG Lei,GU Yang,HUANG Yan,KANG Ting-ting. Development of BeiDou Taming Rubidium Frequency Standard Device Based on FPGA. Acta Metrologica Sinica, 2020, 41(3): 359-362.

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［1］陈智勇, 韩蒂, 庆毅, 等. 面向时间应用的可驯服铷钟［J］. 宇航测试技术, 2013, 33(1): 33-34.
Chen Z Y, Han D, Qing Y, et al. A Discipline rubidium oscillator for timing application［J］. Journal of Astronautic Metrology and Measurement, 2013, 33(1): 33-34.
［2］朱江, 李振华. 卫星导航接收机时延测定技术研究［J］. 计量学报, 2019, 40(5): 910-913.
Zhu J,Li Z H. Research on Time Delay Measurement Technology for Satellite Navigation Receivers［J］. Acta Metrologica Sinica, 2019, 40(5): 910-913.

［3］王玉琢, 张爱敏, 张越, 等. 一种原子钟频率稳定度的估计方法［J］. 计量学报, 2018, 39(3): 397-400.
Wang Y Z, Zhang A M, Zhang Y, et al. An estimation method of frequency stability of atomic clock［J］. Acta Metrologica Sinica, 2018, 39(3): 397-400.
［4］Kirsten L. Strandjord; Penina Axelrad Improved prediction of GPS satellite clock sub-daily variations based on daily repeat［J］. Springer Journal, 2018, 3(18): 1-13.
［5］Wang B, Lou Y D, Liu J N, et al. Analysis of BDS satellite clocks in orbit［J］. Springer Journal, 2018, 4(15): 783-794.
［6］尹文芹, 施韶华, 文音华, 等. 基于FPGA实现TDC的布局布线优化方法研究［J］. 时间频率学报, 2018, 41(1): 27-36.
Yin W Q, Shi S H, Liu Y H, et al. Optimization of digital TDC circuit routing based on FPGA［J］. Journal of Time and Frequency, 2018, 41(1): 27-36.
［7］闫菲菲, 马红皎, 何在民, 等. 基于FPGA和TDC芯片的高精度时间间隔计数器研制［J］. 时间频率学报, 2019, 42(1): 33-42.
Yan F F, Ma H J, He Z M, et al. Development of high precision time interval counter based on FPGA and TDC chip ［J］. Journal of Time and Frequency, 2019, 42(1): 33-42.
［8］罗莹, 张志伟, 杨宁, 等. 基于锁相环的解调技术研究［J］. 计量学报, 2015, 36(4): 432-435.
Luo Y, Zhang Z W, Yang N, et al. Research on demodulation technology based on PLL［J］. Acta Metrologica Sinica, 2015, 36(4): 432-435.
［9］魏煜秦, 孔洁, 杨海波, 等. 基于FPGA的时间间隔测量设计与实现［J］. 原子能科学技术, 2017, 51(10): 1893-1897.
Wei Y Q, Kong J, Yang H B, et al. Design and Implementation of Time Interval Measurement Based on FPGA［J］. Atomic Energy Science and Technology, 2017, 51(10): 1893-1897.
［10］孟令达, 施韶华, 赵志雄, 等. 多通道时间间隔测量分析系统的设计与实现［J］. 时间频率学报, 2017, 40(2): 80-86.
Meng L D, Shi S H, Zhao Z X, et al. Design and implementation of multichannel time interval measurement and analysis system［J］. Journal of Time and Frequency, 2017, 40(2): 80-86.
［11］李泽宁, 温淑敏, 何磊磊, 等. 时间频率信号精密测量计数器的设计与实现［J］. 无线电通信技术, 2017, 43(6): 97-102.
Li Z N, Wen S M, He L L, et al. Design and implementation of precision measuring counter for time and frequency signal［J］. Radio Communications Technology, 2017, 43(6): 97-102.
［12］朱江淼, 孙盼盼, 高源, 等原子钟频差数据去噪算法的研究［J］. 计量学报, 2017, 38(4): 499-503.
Zhu J M, Sun P P, G Y, et al. Research on the denoising algorithm of frequency difference data of atomic clock［J］. Acta Metrologica Sinica, 2017, 38(4): 499-503.
［13］高帅, 谷力, 刘烈曙. 高精度时间间隔测量在时间比对和频率校准中的应用［J］. 现代导航, 2016 , 7(4): 239-245.
Gao S, Gu L, Liu L S. Application of high precision time interval measurement in time comparison and frequency calibration［J］. Modern Navigation, 2016 , 7(4): 239-245.