275km京沪光纤干线高精度时频传递研究
High Precision Time and Frequency Transfer on 275 km Beijing-Shanghai Fiber Backbone
查看参考文献17篇
文摘
|
为实现准国土范围内高精度授时和守时,利用光纤传递铯钟、氢钟等高精度原子钟的时频信号,在实际光纤链路上验证其长距离传递性能。采用波分复用和双向双波长的传输方法,介绍了在275km京沪干线上实现高精度时频传递的相关工作。针对长距离光纤链路的特点,探讨了链路损耗与散射、色散与频率噪声、补偿系统动态范围和反馈带宽等对时频传递性能的影响。实验获得了频率信号的秒稳定度达5×10-14和天稳定度达7×10-18的传递性能,同时,千秒尺度下的时间方差可达2.4ps。 |
其他语种文摘
|
To achieve high precision timing and punctuality in quasi national territory,time and frequency signal of high precision atomic clocks,such as cesium clock or hydrogen maser,is transferred by using fiber to examine the transfer performance of long distance on actual fiber link.By adopting the methods of wavelength division multiplexing and dual wavelength bi-directional transmitting,the related work of achieving high precision time and frequency signal is introduced on 275 km Beijing-Shanghai backbone.Based on the characteristics of long distance fiber link,the impact of loss and scattering of link,dispersion and frequency noise,feedback loop bandwidth and dynamic range of compensating system on time and frequency transfer performance is discussed.Results show that the frequency stabilities are up to 5×10-14 in one second averaging time and 7×10-14 in one day averaging time,and time synchronization stabilities are up to 2.4ps in one thousand second averaging time. |
来源
|
中国激光
,2016,43(7):0706001-1-0706001-8 【核心库】
|
DOI
|
10.3788/CJL201643.0706001
|
关键词
|
光纤光学
;
时频传递
;
时间同步
;
波分复用
|
地址
|
1.
中国科学院上海光学精密机械研究所, 上海市全固态激光器与应用技术重点实验室, 上海, 201800
2.
中国科学院上海光学精密机械研究所, 中国科学院量子光学重点实验室, 上海, 201800
3.
中国科学技术大学, 量子信息与量子科技前沿协同创新中心, 安徽, 合肥, 230026
|
语种
|
中文 |
文献类型
|
研究性论文 |
ISSN
|
0258-7025 |
学科
|
物理学 |
基金
|
国家自然科学基金
|
文献收藏号
|
CSCD:5765102
|
参考文献 共
17
共1页
|
1.
Jiang Y Y. Making optical atomic clocks more stable with 10-16 level laser stabilization.
Nature Photonics,2011,5(3):158-161
|
被引
50
次
|
|
|
|
2.
Bloom B J. An optical lattice clock with accuracy and stability at the 10-18 level.
Nature,2014,506(7486):71-75
|
被引
108
次
|
|
|
|
3.
王义遒. 建设我国独立自主时间频率系统的思考.
宇航计测技术,2004,24(1):1-10
|
被引
8
次
|
|
|
|
4.
李得龙. 光纤链路时延波动对频率传递稳定度的影响.
激光与光电子进展,2014,51(1):010602
|
被引
6
次
|
|
|
|
5.
吴雷. 大动态范围连续可调光纤实时延迟线的设计与制作.
光纤与电缆及其应用技术,2012(3):15-17
|
被引
3
次
|
|
|
|
6.
Gao C. Fiber-based multiple-access ultrastable frequency dissemination.
Optics Letters,2012,37(22):4690-4692
|
被引
14
次
|
|
|
|
7.
Chen W. Joint time and frequency dissemination network over delay-stabilized fiber optic links.
IEEE Photonics Journal,2015,7(3):7901609
|
被引
8
次
|
|
|
|
8.
Lopez O. 86-km optical link with a resolution of 2×10-18 for RF frequency transfer.
European Physical Journal D,2008,48(1):35-41
|
被引
23
次
|
|
|
|
9.
Chen W. Fiber based radio frequency dissemination scheme to multiple users.
China Satellite Navigation Conference,3,2015:379-387
|
被引
1
次
|
|
|
|
10.
程楠. 光纤时间频率同时传递系统中时间同步方法的研究.
中国激光,2015,42(7):0705002
|
被引
13
次
|
|
|
|
11.
Cheng N. Joint transfer of time and frequency signals and multi-point synchronization via fiber network.
Chinese Physics B,2016,25(1):014206
|
被引
3
次
|
|
|
|
12.
Olsson N A. Lightwave systems with optical amplifiers.
Journal of Lightwave Technology,1989,7(7):1071-1082
|
被引
8
次
|
|
|
|
13.
Wood T H. Observation of coherent Rayleigh noise in single-source bidirectional optical fiber systems.
Journal of Lightwave Technology,1988,6(2):346-352
|
被引
4
次
|
|
|
|
14.
Liu Q. Bidirectional erbium-doped fiber amplifiers used in joint frequency and time transfer based on wavelength-division multiplexing technology.
Chinese Optics Letters,2015,13(11):110601
|
被引
6
次
|
|
|
|
15.
Kikuchi K. Effect of l/f-type FM noise on semiconductor-laser linewidth residual in high-power limit.
IEEE Journal of Quantum Electronics,1989,25(4):684-688
|
被引
5
次
|
|
|
|
16.
Newbury N R. Coherent transfer of an optical carrier over 251 km.
Optics Letters,2007,32(21):3056-3058
|
被引
16
次
|
|
|
|
17.
Lau K Y. Ultra-stable RF-over-fiber transport in NASA antennas,phased arrays and radars.
Journal of Lightwave Technology,2014,32(20):3440-3451
|
被引
6
次
|
|
|
|
|