Tomás Bagala, Adam Fibich, P. Kubinec, V. Stofanik
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引用次数: 4
摘要
芯片级原子钟(CSAC)的使用为需要卓越的长期频率稳定性的广泛战略系统提供了巨大的潜力。与CSAC相比,OCXO具有较大的长期频率不稳定性(老化率)、较长的预热时间和较高的功耗等缺点。另一方面,CSAC的主要缺点是相位噪声较高。本文介绍了一种利用与CSAC同步的外部OCXO (MTI 230-0827)改善CSAC sa .45短期频率稳定性(相位噪声)的方法。在低功耗模式下,CSAC SA.45s的功耗小于20mw;然而,它作为简单的TCXO工作,在整个工作温度范围内,频率稳定性限制在±1 ppm。在论文的最后一部分,我们介绍了组合式低功耗时钟系统,该系统可以在较宽的温度范围内实现±0.01 ppm的频率稳定,而功耗相似。
Improvement of short-term frequency stability of the Chip Scale Atomic Clock
Utilization of the Chip Scale Atomic Clock (CSAC) today gives great potential for wide range of strategic systems requiring superior long-term frequency stability. Compared to CSAC, an OCXO has many drawbacks, e.g. it has larger long-term frequency instabilities (aging rate), longer warm-up time and higher power consumption. On the other hand, the main disadvantage of the CSAC is the higher phase noise. In this paper we describe a method of improvement of the CSAC SA.45s short-term frequency stability (phase-noise) using an external OCXO (MTI 230-0827) syntonized to the CSAC. In the low power mode, the CSAC SA.45s consumes less than 20 mW of power; however it operates as simple TCXO and over a full operating temperature range, the frequency stability is limited to ±1 ppm. In the last part of the paper we introduce combined low power clock system that can achieve frequency stability ±0.01 ppm over a wide temperature range, while consuming similar power.
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