# Could stellar occultations be used to survey Kuiper belt objects?

The first hint we had as to the shape of Ultima Thule was via an occultation study using an array of small telescopes. Has anyone investigated the feasibility and effectiveness of conducting a survey campaign using the same technique?

Given that this was managed for an arbitrarily selected object in a window of few years, it would seem that, if you just wanted to do the same thing for as many Kuiper belt objects as you can manage, that you should be able to get similar data for a significant number of objects a year at relatively low cost.

Edit: the kind of project I'm wondering about would be targeted at getting detailed shape (e.g. what fraction of KBOs are contact binaries?) and size data. For example a line of a few hundred 0.5m class interments at 100m to km spacing.

Edit 2: I guess I kind of didn't actually say what the target of the survey would be. To clarify, the objective would be to collect fine detail on the shape of KBOs. E.g. how common are contact binaries?

In the case of trying to time-resolve occultations by KBOs, your exposure time is set by the event timescale which depends on the velocity of the KBO across the line of sight and the diameter of the KBO. For typical KBO velocities of 20 km/s, this means that a Pluto (approx 2000km diameter) occultation lasts $$2000\,km/20\, kms^{-1}=100\,s$$. If you wanted to find small 20 km KBOs similar to 2014 MU69/Ultima Thule, then the events are $$20\,km/20\, kms^{-1}=1\,s$$ long (both of these calculations assume the occultation goes over the largest part of the KBO and isn't grazing).
As discussed in the reply comments to the question author, scientific CMOS sensors such as the Andor Marana (a commercially available closeish match to the custom detectors used by TAOS-II with ~$31k pricetag; Jan 2019) will be better at both the 'signal' part (due to higher quantum efficiency) and the 'noise' parts (larger, less noisy pixels, cooling and temperature stabilization) than a consumer DSLR sensor. Looking at a study of DSLR dark current by Photonics.com, the dark current is ~50 counts/pixel/second (the Photonics.com figure is for 30s exposures and assuming 1500DN) rising to ~100 counts/pixel/second (averaging at ~3000DN for 3 of the pixels) after 100 frames as the sensor heats. For the Marana, the figure is 0.26 counts/pixel/second (taking datasheet value of 0.2 electrons/pix/s and assuming a gain of 1.3 to match the full well capacity of 85k electrons to the 16 bit ADC (65536 levels)), an almost 400x lower value. (The ADC data range is another area of difference; the Marana can do 16bit digitization whereas DSLRs are typically 12 or 14bit, giving only 4096 or 16,384 levels to record all the signal levels in the image) The other use of occultations is to monitor predicted occultations by known asteroids and Kuiper Belt Objects. This can be used to get a better idea on the size and shape of the object (as you note for Ultima Thule/2014 MU69), search for additional satellites or rings around the object (as has been done for the KBO Haumea (Nat Geo article) and the Centaur Chariklo (Space.com article)) and look for and monitor changes in the atmosphere (as has been done for Pluto since the first occultation in 1988). • Interesting. TAOS-II seems similar, but using fewer larger interments. I was thinking more along the lines of a few hundred 0.5m class interments at 100m to km spacing. – BCS Jan 4 at 22:52 • Several hundred telescopes with cameras operating at 20 frames per second would be a very expensive project and a very large data processing project.... – astrosnapper Jan 5 at 0:11 • – uhoh Jan 5 at 4:54 • An article in Nature Astronomy today (2018/1/29) has the first candidate occultation event of a roughly 1km sized KBO detected with commercial CMOS cameras. This used two systems, based in Japan, and consisting of a 11" Celestron f2.2 astrograph, ZWO ASI1600 CMOS cameras (no familiarity with those) and a Matabones focal reducer. Cost per system is quoted as 16k US$. Observes ~2k stars down to V~13 in a 2.3x1.8deg field at 15.4Hz. 60hr data run=50TB of data – astrosnapper Jan 28 at 17:13