More information is available in literature upon request. Time Service Dept., U.S. Naval Observatory, Washington, DC. This excellent governmental agency can provide up-to-date and accurate information to anyone who is interested
Regarding the performance of pocket or wrist crystal watches, the most important disturbance comes from the temperature variations to which the watch is exposed. As a rule of thumb, crystals have a temperature coefficient of about 1 part per million. That amounts to a rate change of 0.1s per day per degree temperature change.
All measurements of clock performance, or clock stability, start with a set of regularly executed measurements of the clock correction With these measurements a table is constructed with the time of measurement (or the day number in the series), the measurement, and first and second differences.
The squares column will be needed in a moment. We have assumed that we observe a quartz crystal clock which is temperature controlled. The units are milliseconds and the rates are given in ms/day. In the case of atomic clocks, the unit would probably be in nanoseconds because of the much greater stability of these clocks.
Our example clock would be a very good crystal clock because the rate variations as shown in the 4th column are small. Nevertheless, the rate shows a systematic increase of 20ms in 14 days, i.e., the clock has a noticeable drift. This drift is also visible as the average second difference (sum = 20, divide by 14 ---> average drift = 20/14 = 1.43ms/d/d).