铷
原子钟
理论(学习稳定性)
异常(物理)
物理
可靠性(半导体)
卫星
频率漂移
计算物理学
异常检测
时钟频率
芯(光纤)
频率标准
时频分析
计算机科学
时滞与积分
原子物理学
原子序数
作者
X. Y. Li,Zihao Huang,Gang Ming,Xiaolong Zhu,Zhiming Zhan
标识
DOI:10.1088/1748-0221/20/09/p09022
摘要
Abstract The rubidium atomic clock serves as the core equipment in satellite navigation, directly influencing the timing and positioning accuracy of the satellite navigation system. The clock's frequency stability and accuracy play a crucial role in time measurement. However, anomalies in frequency, such as glitches, steps, and cycles, can impact clock performance. This article delves into the causes and effects of these anomalies by analyzing and detecting frequency irregularities in rubidium atomic clocks. Through experimental measurements of the rubidium clock (with interpolated 1-second data) and simulations of anomaly scenarios, Burrs may occur in the clock's frequency, leading to instantaneous fluctuations. Step anomalies, on the other hand, may arise from system errors or external interference, significantly affecting frequency stability. Period abnormalities manifest as regular and periodic changes in clock frequency. In this article, we propose corresponding analysis and detection methods. By precisely processing data and conducting timing analysis, these anomalies can be effectively identified and corrected, improving the performance and reliability of rubidium atomic clocks.
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