We happen to have on consignment a C Plath sextant made for the Kriegsmarine in 1939 Germany. It is a prized collector's item, but we wanted to demonstrate that it remains a top of the line instrument for practical celestial navigation, and likely will for another generation or two, and there is no better way to do this than to show it can be used for lunar distance measurements, considered the epitome of sextant sights.
I did two sets of sights. One with the 4x40 scope that is stock for the instrument and one set where I replaced that with a 6x30 monocular scope (made by the modern C Plath company), which is preferred for this measurement, because it makes the edge of the moon sharper. The spread in the data were smaller with the 6x30 scope, but the resulting UTC and Lon found from the measurements was actually better with the 4x40. That was just an accident, as there is always some luck involved with these sights. The higher power scope should in the longer run get better results.
This early C Plath sextant is ideal for lunars in that it is high precision and very light weight (2 lb 10z), being made from an aluminum alloy that C Plath pioneered for sextant manufacture in that era. Lunar sights take longer than conventional sights, which reminded me of the ludicrous presumptions we periodically see in advertising claiming heavy brass sextants weighing almost twice as much are preferred for their inertia and stability doing sights! Those sextants weigh more than a half a gallon of milk. Hold a full milk carton up to your nose with your head leaned back a bit for a minute or so to get the picture. The lighter sextant is always preferred and always the top of line in sextants.
For these sights, we even want more support if we can rig it. With an eye cup that lets us press the head against the sextant, and ideally a support to lean your elbow on. Then tune the scope to show the moon's edge as sharp as possible. The star or planet, however, will always be a point of light... in principle. In fact, that point of light will have a fuzzy halo around it when looking as close as we can, and that puts a limit on the accuracy. This could be optics or it could be we just needed some eye drops!
Here are results of the first set of sights taken from a pocket beach on Puget Sound (47º 40.5'N, 122º 24.5'W), 0.4 nmi due west of our office. These sights used the stock 4x40 scope from 1939.
These were typed into Excel then plotted, and then fit with a straight line, which we can add with a button click, called "Add trend line." This produces a least squares fit of the data, with the equation showing.









