The Pan-STARRS Moving Object Processing System

Denneau, L.; Jedicke, Robert; Grav, T.; Granvik, Mikael; Kubica, Jeremy; Milani, Andrea; Vereš, Peter; Wainscoat, R. J.; Chang, Daphne; Pierfederici, F.; Kaiser, Nick; Chambers, K.; Heasley, J. N.; Magnier, E. A.; Price, P. A.; Myers, Jonathan A.; Kleyna, Jan; Hsieh, Henry H.; Farnocchia, Davide; Waters, C.; Sweeney, W. H.; Green, Denver; Bolin, Bryce; Burgett, W. S.; Morgan, J. S.; Tonry, J.; Hodapp, Klaus W.; Chastel, S.; Chesley, S. R.; Fitzsimmons, A.; Holman, Matthew J.; Spahr, T.; Tholen, David J.; Williams, G. V.; Abe, Shinsuke; Armstrong, J. D.; Bressi, T. H.; Holmes, Robert R.; Lister, Tim; McMillan, R. S.; Micheli, M.; Ryan, E. V.; Ryan, W. H.; Scotti, J. V.

doi:10.1086/670337

Cited by 135 publications

(107 citation statements)

References 55 publications

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“…In the current baseline approach the data is processed through LSST's Moving Object Processing System (MOPS; see Denneau et al, 2013, for a description of the original Pan-STARRS MOPS) using the findtracklets and the linktracklets algorithms by Kubica et al (2007) followed by initial orbit computation. Detections in difference images will first be linked into single-night batches of observations colloquially known as tracklets using the findtracklets algorithm.…”

Section: Large Synoptic Survey Telescopementioning

confidence: 99%

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

Fedorets

Granvik

Jones

et al. 2020

Icarus

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Earth's temporarily-captured orbiters (TCOs) are a sub-population of near-Earth objects (NEOs). TCOs can provide constraints for NEO population models in the 1-10-metre-diameter range, and they are outstanding targets for in situ exploration of asteroids due to a low requirement on ∆v. So far there has only been a single serendipitous discovery of a TCO. Here we assess in detail the possibility of their discovery with the upcoming Large Synoptic Survey Telescope (LSST), previously identified as the primary facility for such discoveries. We simulated observations of TCOs by combining a synthetic TCO population with an LSST survey simulation. We then assessed the detection rates, detection linking and orbit computation, and sources for confusion. Typical velocities of detectable TCOs will range from 1˝/day to 50˝/day, and typical apparent V magnitudes from 21 to 23. Potentially-hazardous asteroids have observational characteristics similar to TCOs, but the two populations can be distinguished based on their orbits with LSST data alone. We predict that a TCO can be discovered once every year with the baseline moving-object processing system (MOPS). The rate can be increased to one TCO discovery every two months if tools complementary to the baseline MOPS are developed for the specific purpose of discovering these objects.

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Section: Large Synoptic Survey Telescopementioning

confidence: 99%

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

Fedorets

Granvik

Jones

et al. 2020

Icarus

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“…The MD survey visited a single field 8×/night with filter-dependent exposure times of 120-240 s in the p 3 filters. The solar system survey (SS) used 5%-6% of the survey time but was increased to 12% of the survey time after 2012 (Denneau et al 2013). It used the w P1 filter with 45 s exposures and mostly visited fields near opposition, or the "sweetspots" near the ecliptic at solar elongations of -  60 90 .…”

Section: Pan-starrs1mentioning

confidence: 99%

“…The Pan-STARRS1 MOPS can link multiple observations of the same object together within a night into "tracklets," combine tracklets from different nights into "tracks," calculate orbital elements, perform attribution of new tracklets to known objects, identify "precoveries" of historical tracklets associated with newly calculated orbits, and allow for manual vetting of all the data (Denneau et al 2013). We used MOPS to simulate the detection of our synthetic ISOs in Pan-STARRS1, CSS, and MLS fields.…”

Section: The Moving Object Processing System (Mops)mentioning

confidence: 99%

An Observational Upper Limit on the Interstellar Number Density of Asteroids and Comets

Engelhardt¹,

Jedicke²,

Vereš³

et al. 2017

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125

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We derived 90% confidence limits (CLs) on the interstellar number density (r IS CL ) of interstellar objects (ISOs; comets and asteroids) as a function of the slope of their size-frequency distribution (SFD) and limiting absolute magnitude. To account for gravitational focusing, we first generated a quasi-realistic ISO population to~750 au from the Sun and propagated it forward in time to generate a steady state population of ISOs with heliocentric distance <50 au. We then simulated the detection of the synthetic ISOs using pointing data for each image and average detection efficiencies for each of three contemporary solar system surveys-Pan-STARRS1, the Mt. Lemmon Survey, and the Catalina Sky Survey. These simulations allowed us to determine the surveys' combined ISO detection efficiency under several different but realistic modes of identifying ISOs in the survey data. Some of the synthetic detected ISOs had eccentricities as small as 1.01, which is in the range of the largest eccentricities of several known comets. Our best CL of r =´- 3 implies that the expectation that extra-solar systems form like our solar system, eject planetesimals in the same way, and then distribute them throughout the Galaxy, is too simplistic, or that the SFD or behavior of ISOs as they pass through our solar system is far from expectation.

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“…Based on the result of the search as well as Weryk's comments, we conclude that P/Blanpain was already in outburst at least 1 day before the official rediscovery on 2013 July 4, but the 49-day gap between the 2013 July 3 detection and the last image that covers the predicted position of P/Blanpain (2013 May 15) makes it difficult to pinpoint the exact onset time of the outburst. The non-detections on 2013 May 15, August 24 and September 9 sets an upper limit of V ≈ 22.5 of the comet, based on the typical survey depth of Pan-STARRS (Denneau et al 2013).…”

Section: Onset Of the Outburstmentioning

confidence: 95%

Rising from Ashes or Dying Flash? The Mega Outburst of Small Comet 289P/Blanpain in 2013^∗

Clark

2019

ApJL

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Jupiter-family comet 289P/Blanpain was first discovered in 1819 and was then lost for ∼ 200 years, only to be rediscovered in 2003 as a small, weakly active comet. The comet is associated with the Phoenicids, an otherwise minor meteor shower that produced significant outbursts in 1956 and 2014. The shower points to the existence of significant mass-loss events of P/Blanpain in recent history. P/Blanpain was recovered during an apparent large outburst in 2013 July at an appreciable heliocentric distance of 3.9 au, with brightness increase of 9 mag, making it one of the largest comet outbursts ever observed. Here we present an analysis of archival data taken by several telescopes. We find that the 2013 outburst has produced ∼ 10 8 kg of dust, which accounts for a modest fraction (∼ 1%) of the mass of P/Blanpain's nucleus as measured in 2004. Based on analysis of long-term lightcurve and modeling of coma morphology, we conclude that the 2013 outburst was most likely driven by the crystallization of amorphous water ice triggered by a spin-up disruption of the nucleus. Dust dynamical model shows that a small fraction of the dust ejecta will reach the Earth in 2036 and 2041, but are only expected to produce minor enhancements to the Phoenicid meteor shower. The 2013 outburst of P/Blanpain, though remarkable for a comet at small sizes, does not necessary imply a catastrophic disruption of the nucleus. The upcoming close encounter of P/Blanpain in 2020 January will provide an opportunity to examine the current state of the comet.

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The Pan-STARRS Moving Object Processing System

Cited by 135 publications

References 55 publications

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

An Observational Upper Limit on the Interstellar Number Density of Asteroids and Comets

Rising from Ashes or Dying Flash? The Mega Outburst of Small Comet 289P/Blanpain in 2013^∗

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The Pan-STARRS Moving Object Processing System

Cited by 135 publications

References 55 publications

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

Discovering Earth’s transient moons with the Large Synoptic Survey Telescope

An Observational Upper Limit on the Interstellar Number Density of Asteroids and Comets

Rising from Ashes or Dying Flash? The Mega Outburst of Small Comet 289P/Blanpain in 2013∗

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Rising from Ashes or Dying Flash? The Mega Outburst of Small Comet 289P/Blanpain in 2013^∗