Abstract :
The stability of an atomic clock can change with time due to several factors, such as temperature, humidity, radiations, aging, and sudden breakdowns. The dynamic Allan variance, or DAVAR, is a representation of the time-varying stability of an atomic clock, and it can be used to monitor the clock behavior. Unfortunately, the computational time of the DAVAR grows very quickly with the length of the analyzed time series. In this article, we present a fast algorithm for the computation of the DAVAR, and we also extend it to the case of missing data. Numerical simulations show that the fast algorithm dramatically reduces the computational time. The fast algorithm is useful when the analyzed time series is long, or when many clocks must be monitored, or when the computational power is low, as happens onboard satellites and space probes.
Keywords :
artificial satellites; atomic clocks; stability; time series; time-varying systems; aging; atomic clock stability; clock behavior monitoring; computational algorithm; computational time; dynamic Allan variance; humidity; numerical simulation; radiation; satellite; space probe; sudden breakdown; temperature; time series; time-varying stability; Aging; Algorithm design and analysis; Atomic clocks; Electric breakdown; Humidity; Monitoring; Numerical simulation; Stability; Temperature; Time series analysis; Algorithms; Computer Communication Networks; Computer Simulation; Models, Theoretical; Time Factors;
Journal_Title :
Ultrasonics, Ferroelectrics, and Frequency Control, IEEE Transactions on
