On Tue 2021-12-28T14:40:43+0000 Poul-Henning Kamp hath writ: > You want a bright star as close to your latitudes Zenith as possible, > to get maximum apperant transit velocity.
Most precise time determination in history was by meridian telescopes which only had one axis of motion not counting the ability to reverse the tube as a way of checking for systematic errors. Near the zenith was best for the meridian telescopes. The Danjon "Impersonal" Astrolabe with its prism and mercury bath allowed selection of targets looking around the sky rather than waiting for something near overhead. The Danjon Astrolabes were widely deployed as part of preparations for the International Geophysical Year. That allowed dozens of folks to take up paid residence in funky places like Curacao for a year. The data from the IGY then took a decade to reduce and publish. At the point when the optical astronomy measures of the IGY were published all of the techniques which had been used were obsolete. (That was true of much of the rest of the IGY data because of the advancement of technology during the late 1950s and early 1960s.) The optical measurements suffered from the "personal equation" which was a systematic offset of how much each observer tended to be early or late. Many of the optical measurements were done by pulling a trigger. Some has a screw to be turned to match the motion of the star across the zenith and then measure by looking at the chart recording of the potentiometer. Stars pretty much at the zenith were required for Photographic Zenith Tubes. PZTs were unable to compare their results with anyone else because each one had a unique list of target stars. They were the most accurate optical measure of earth rotation. The evolution of precision of time measured by optical observatories was plotted by the Stoykos as they prepared to retire from BIH. https://www.ucolick.org/~sla/leapsecs/BHsHn05p142.html Note that mean difference between the best observatories never fell as low as a millisecond, and that was after the BIH had removed the persistent systematic differences which resulted from the fact that the observatories used conventional longitudes which were not self consistent. Note that the random error fell about as low as 0.4 millisecond for the best observatories. The longitudes and latitudes of everything changed in 1968 as the new recommendations for terrestrial reference frame were implemented. The USNO actually, and finally, removed the about 0.03 s offset to UT that had been in all US measures of time since the inception of USNO. Of course for non-stationary observatories the 18th through 20th century measurement to determine the offset of the chronometer was using a sextant to shoot a lunar and determine the time based on the angle between moon and star. -- Steve Allen <[email protected]> WGS-84 (GPS) UCO/Lick Observatory--ISB 260 Natural Sciences II, Room 165 Lat +36.99855 1156 High Street Voice: +1 831 459 3046 Lng -122.06015 Santa Cruz, CA 95064 https://www.ucolick.org/~sla/ Hgt +250 m _______________________________________________ time-nuts mailing list -- [email protected] -- To unsubscribe send an email to [email protected] To unsubscribe, go to and follow the instructions there.
