This is correct. If the battery is removed the gps takes much longer to start up.

I have a dual port leo that I will be putting through the same testing as a reference.

@@ZenwizardStudios Look forward to the video.

Check the time-nut archives. The Leo Bodnar units test pretty poorly compared to something like a Trimble Thunderbolt. It may meet your needs tho.

My testing agrees to the Time-nuts results (video will be out shortly) I was kind of curious if there was an abnormality but this does tend to confirm the results. One critical note on the leo is is NOT a fixed output. My is adjustable from 10 Hz to 400 Mhz with 2 ports. With that range of adjustment I would expect there to be some stability degradation when tested with a fixed and tuned for stability 10Mhz.

Allen Deviation is a really good way to sum together all the “Noise sources” and roll them in to a number for easy comparison. The lower the Allen Deviation the better the oscillator “typically” The gate time is a way to control the sample window of interest. Some equipment has a long measurement time and the more the oscillator moves around the less stable the measurement. Changing the gate time longer also gets some of the slowing drifting from peak to peak. A gate time of 1ms will be far less sensitive to the oscillator walking over the course of several minutes then one of 100 to 200 seconds. At the longest gate time the measurements took 2.5 hours to complete Where as a longer gate time will average out the high frequency noise and make an oscillator look more stable then it really is. Hence why I built the Excel sheet with several gate times, but ALL gate times were sampled 100 times. So there is a sampling of high speed as well as low speed stability. This comes in to play if measurements of interest are 1 to 10 seconds or is something is being monitored for weeks, months, years.

Everything is a cost effective option vs cesium standard. ;-)