Research on secondary frequency standards control algorithm based on linear quadratic regulator

Jinyu Wang; Zongnan Li; Jing Peng; Ming Ma; Xin Yang; Hang Gong

doi:10.1117/12.3052347

30 December 2024 Research on secondary frequency standards control algorithm based on linear quadratic regulator

Jinyu Wang, Zongnan Li, Jing Peng, Ming Ma, Xin Yang, Hang Gong

Author Affiliations +

Proceedings Volume 13394, International Workshop on Automation, Control, and Communication Engineering (IWACCE 2024); 133940M (2024) https://doi.org/10.1117/12.3052347
Event: International Workshop on Automation, Control, and Communication Engineering (IWACCE 2024), 2024, Hohhot, China

Abstract

With the development of Low Earth Orbit (LEO) satellite internet, the number of satellites in LEO constellations has been increasing. To reduce the construction costs of LEO satellites, they are often equipped with secondary frequency standards (primarily crystal oscillators and rubidium atomic clocks) as their time-frequency sources. In order to enhance the performance of these time-frequency sources, many scholars have been investigating methods to optimize secondary frequency standards. Concerning clock control algorithms, classical methods such as PID and Ping-Pong (PP) suffer from slow tuning and uncertainty about optimization. This paper introduces a clock control algorithm based on the Linear Quadratic Regulator (LQR), which determines the optimal adjustment through a designed cost function. The advantages of this algorithm include a clear optimization strategy and ease of parameter tuning. The algorithm proposed in this paper achieves superior performance in terms of both time deviation standard deviation and frequency stability when compared to the PID and Ping-Pong algorithms. After control, for the PID, PP, and LQR algorithms, the standard deviations of the crystal oscillator are 4.2E-9, 2.7E-9 and 1.8E-9, and it’s frequency stability (10000s) has improved to 8.1E-14, 6.1E-14 and 2.8E-14, and the rubidium clock's standard deviations enhanced to 2.6E-9, 5.2E-10 and 3.4E-10, the rubidium clock's frequency stability (10000s) has improved to 6.8E-14, 2.1E-14 and 2.1E-15.

(2024) Published by SPIE. Downloading of the abstract is permitted for personal use only.

Citation Download Citation

Jinyu Wang, Zongnan Li, Jing Peng, Ming Ma, Xin Yang, and Hang Gong "Research on secondary frequency standards control algorithm based on linear quadratic regulator", Proc. SPIE 13394, International Workshop on Automation, Control, and Communication Engineering (IWACCE 2024), 133940M (30 December 2024); https://doi.org/10.1117/12.3052347

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KEYWORDS

Clocks

Matrices

Rubidium

Crystals

Oscillators

Satellites

Standards development

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