1. 6/17/2015August 2010, AstroStat, P. Protopapas Time Series Fitting Motivation: Solar system, occultation by outer solar system objects. Surveys: TAOS, Pan-STARRS, Whipple 1/64

2. 6/17/2015August 2010, AstroStat, P. Protopapas The Solar System comprises the Sun and the retinue of celestial objects gravitationally bound to it: the eight planets 162 known moons three currently identified dwarf planets and their known moons (Pluto, Ceres and Eris) thousands of small bodies. This last category includes asteroids, meteoroids, comets, and interplanetary dust. Mercury, Venus, Earth, Mars, Jupiter, Saturn, Uranus, Neptune. Solar System

3. 6/17/2015August 2010, AstroStat, P. Protopapas

4. Use occultations of background stars:

5. 6/17/2015August 2010, AstroStat, P. Protopapas 5/64

6. 6/17/2015August 2010, AstroStat, P. Protopapas A tantalizing example has been reported by Schlichting et al: the HST-FGS event:

7. 6/17/2015August 2010, AstroStat, P. Protopapas Whipple Indirect exploration of the outer solar system The primary goals of the Whipple mission are to detect and characterize objects in all of the major solar system populations beyond Neptune: –Kuiper Belt (and scattered disk …) –“Sedna region” (100 – 2,000 AU) –Oort Cloud (3,000 AU - ?) Achieve these goals by monitoring >10,000 stars to look for occultations by small objects 10,000 stars for 24 hours at 50Hz = 4*10^13 measurements 7/64

8. KBOsSedna Region Ooort Cloud ASTEROIDs PS1 Video GS ZONE PS1 limit LSST limit OCCULTATION EXLUSIVE ZONE Protopapas PS1@Belfast Schlicting 2010

9. 6/17/2015August 2010, AstroStat, P. Protopapas Original concept inspired by Kepler Schmidt-Cassegrain telescope design 37 square degree field of view Earth leading orbit: opposite direction from Spitzer & Kepler Whipple: a Discovery Class mission to search for occultations

10. 6/17/2015August 2010, AstroStat, P. Protopapas Whipple: a proposed spacecraft to search for occultations

11. 6/17/2015August 2010, AstroStat, P. Protopapas Whipple: a proposed spacecraft to search for occultations

12. 6/17/2015August 2010, AstroStat, P. Protopapas Hybrid CMOS focal plane array 10,000 (80,000) stars, 40 (5) Hz readout Whipple: a proposed spacecraft to search for occultations

13. 6/17/2015August 2010, AstroStat, P. Protopapas Anticipated Event Rates: Oort Cloud: –10 12 objects (D>3 km) each in Inner and Outer Oort Clouds –N(>D) ~ D -1.8 ; randomized eccentricities –10 – 100 events per year “Sedna” population: –Take guidance from the Caltech survey (Meg Schwamb’s talk) –100 AU 30 AU –1-1000 per year. Very uncertain! Kuiper Belt: –~5,000 events per year (Schlichting et al 2009 event)

14. 6/17/2015August 2010, AstroStat, P. Protopapas Comparison between TAOS, Pan- STARRS, IMACS and Whipple: TAOSMagellan/I MACS Pan_STARRS (video guide stars) Whipple Duration5 yearsFew days per year 3 years Number of targets followed 200100070~10,000 Efficiency of 100% at 50 AU 3KM0.5km1km0.5km StarHours at SNR>25 500020000100000/year10000/hour Events<1/year1-20/year2-40/year>4000 year

15. 6/17/2015August 2010, AstroStat, P. Protopapas Scan statistics Idea: Idea: Given a time series find the region [sub sequence of measurements] that are not consistent with noise. Original idea originates from epidemiology time series: f i the value at time t i 01020304050607080 w r fifi work with Dan Preston and Iara Cury

16. 6/17/2015August 2010, AstroStat, P. Protopapas Part a: Event detection/Event fitting First approach: Rank statistics. Second approach: Alex Blocker’s method What is the best method of fitting events 16/64

17. 6/17/2015August 2010, AstroStat, P. Protopapas 17 Don’t fit it too much I hear your hypo-thesis but I think I heard enough My sh** is dead and outdated top notch to the top, I’m rated while you till tikin I’m wrong I know, I gotta reason to be so 44 years old, and no one seems to see that I’m worth my weight in gold but still no clue on stati-stics Just gimme a chance, show the problem, you’ll see if ya f** with me ya f**in with the whole time -e - series.