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Training Session, Tucson

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Title: Training Session, Tucson


1
Training Session, Tucson
The Pan-STARRS Moving Object Processing System
2
Thanks
  • LSSTC

3
Introductions
4
Policies
  • Tuesday
  • No cell phones, laptops, etc.
  • Wednesday, Thursday, Friday
  • Whatever
  • Parking Passes

5
Schedule
  • Tuesday Morning
  • MOPS Overview
  • Tuesday Afternoon
  • MOPS Simulation Training
  • Wednesday, Thursday, Friday
  • MOPS Simulation running

6
MOPS Collaborating Institutions
  • Institute for Astronomy (IfA)
  • Large Synoptic Survey Telescope (LSST)
  • University of Pisa
  • Jet Propulsion Lab (JPL)
  • Carnegie Mellon University, Robotics Institute
    AUTON Laboratory
  • Minor Planet Center (MPC)
  • Spacewatch
  • University of Helsinki

7
MOUs (existent)
  • JPLDifferential Orbit Determination Ephemeris
    Generation
  • LSSTTwo year software engineer (Pierfederici)
  • NEODysIOD and 2-night linking
  • SpacewatchTargeted follow-up of interesting
    objects

8
MOUs (in negotiations)
  • MROTargeted follow-up of interesting objects

9
The MOPS Team (IfA)
Larry DenneauSenior Software Engineer
Tommy GravJunior Scientific Researcher
now at JHU
Joe MasieroGraduate Student
Robert JedickeMOPS Manager, IfA Specialist
10
The MOPS Team (IfA)
Jim HeasleySenior Professor
David TholenSenior Professor
Richard WainscoatSpecialist, UH Telescope
Support, Associate Chair
11
The MOPS Team (extended)
Francesco PierfedericiLSST Software Engineer
Daniel ChangUH ICS Graduate Student
12
The MOPS Team (External)
Steven ChesleyJet Propulson Laboratory
Jeremy KubicaCarnegie Mellon Robotics Institute
Mikko KaasalainenUniversity of Helsinki
Andrea MilaniUniversity of Pisa
13
MOPS Workload
Pan-STARRS Management
14
Pan-STARRS Solar System
15
Asteroids
  • PS4 will find as many asteroids in one lunation
    as have been identified since the discovery of
    Ceres in 1801

16
PS4 NEOs
  • Tens of thousands of NEOs

17
PS4 the Main Belt
  • 10,000,000 MB objects in ten years

18
PS4 Comets
  • Pan-STARRS will find 10X as many comets per year
    as all existing surveys
  • 1,000s of comets in ten years operation
  • INTERSTELLAR ! ! !

19
PS4 TNOs
  • 20,000 TNOs

20
PS4 Distant Planets
Jewitt 2003, Project Pan-STARRS and the Outer
Solar System, EMP
New Plutos320AU
New Earths620AU (50AU)
New Neptunes1230AU (130AU)
New Jupiters2140AU (340AU)
21
PS4 Minor Planet Summary
TNOs
Comets
Centaurs
Main Belt
NEO / PHO
Companions
Other Trojans
Jovian Trojans
Interstellar Visitors
Wide TNO Binaries
22
MOPS Overview
  • Identify known objects
  • Discover new objects
  • Derive observable parameters
  • Catalogue objects
  • Enable solar system science

23
Terminology Review
  • Single Occurrence Transient SOT
  • A detection that is not at the same position as
    any other known stationary object in the past 30
    (TBR) days
  • High S/N (HSD) Detection
  • A detection that has a high probability of being
    a real object (gt5?)
  • Low S/N (LSD) Detection
  • A detection that has a low probability of being a
    real object (gt3?)
  • Data Collection DC DB Database
  • A generalized database

24
Terminology Review
  • Observing Cycle OC
  • Integer number incrementing _at_ 0 UT on day
    closest to full moon
  • Synthetic Object
  • An artificial object with orbital and shape
    parameters
  • Derived Object
  • A synthetic or real object and its parameters
    derived from observations

25
Terminology Review
  • Detection (not an SOT)
  • A statistically significant collection of pixels
    after image convolution with a shape kernel
  • Tracklet
  • A set of ?2 detections that may be observations
    of the same object
  • Track
  • A set of ?2 tracklets that may be observations
    of the same object
  • Orbit
  • A six parameter representation of the
    heliocentric path of an object

26
Terminology Review
27
Terminology Review
Evening Sweet Spot
Morning Sweet Spot
Opposition
28
MOPS Top Level Design
Seamlessly combine existing softwareinto an
operational system.
29
MOPS Top Level Design
TransientDetections
Intra-night Linking
OrbitDetermination
Inter-night Linking
Meta-data
SyntheticSolar System
Identification
Database
Attribution
Precovery
Two-Night Linking
PublishedObjects
Impact RiskAnalysis
GUI
Users
MPC
30
Transient Detection (IPP)
4 Telescopes



31
Intra-Night Linking (Tracklets)
First exposure
Second exposure
  • 250 real detections / deg2
  • 250 false detections / deg2

32
Attributions
Legend
Tracklets
Known Objects
33
Inter-Night Tracklet Linking (tracks)
Legend
FirstNight
SecondNight
ThirdNight
FourthNight
FifthNight
34
Multiple Hypothesis Testing
O(n2)
35
kd-tree solution
O(n log n)
36
Initial Orbit Determination
Good IOD
Bad IOD
Legend
First Night
Second Night
Third Night
37
Differential Orbit Determination
OD
IOD
Legend
First Night
Second Night
Third Night
38
Orbit Identification
39
PS1 Review DRM Surveys
DRM PS1Design Reference Mission
40
PS1 Review DRM Surveys
? gt61 of time amenable to discovery of solar
system objects.
Some of the other surveys can also identify solar
system objects.
41
PS1 Review Filters
g
r
i
z
y
42
PS1 Review w filter
wgri
g
r
i
43
PS1 Review Bandpasses
44
PS1 Review Sensitivities
The trailed NEO single exposure sensitivityis
equivalent to V23 in g, r, and i bands.
The discovery of tracklets is equivalentto a 5
sigma limiting magnitude of V22.8
45
PS1 Review Sky-Plane Tesselation
Outside view of the celestial sky tesselated into
6252 fields. Of these fields, 5464 have boresight
centers gt -30 Declination.
The 3 field of view of PS1 with an inscribed
hexagon of 5.84 square degrees.
The twenty percent overlap from a single
tesselation due to the circular field of view.
46
PS1 Review Sky-Plane Tesselation
Outside view of the celestial sky tesselated into
6252 fields. Of these fields, 5464 have boresight
centers gt -30 Declination.
The 3 field of view of PS1 with an inscribed
hexagon of 5.84 square degrees.
The twenty percent overlap from a single
tesselation due to the circular field of view.
47
PS1 Review Sky-Plane Tesselation
Outside view of the celestial sky tesselated into
6252 fields. Of these fields, 5464 have boresight
centers gt -30 Declination.
The 3 field of view of PS1 with an inscribed
hexagon of 5.84 square degrees.
The twenty percent overlap from a single
tesselation due to the circular field of view.
48
Observing Strategy
  • Every survey mode obtains at least twoimages at
    each location separated by a Transient Time
    Interval (15-30 minutes)
  • serendipitous positions colours
  • Solar system survey re-visits each location after
    3-6 days
  • obtain 3-4 nights/month
  • 12 day arc

49
PS1 Review 3p Survey
210 deg 14 hrs
Opposition
15 deg 1 hr
90 dec
Equator
-30 dec
50
PS1 Review 3p Survey
51
PS1 Review 3p Survey
52
PS1 Review 3p Survey
53
PS1 Review 3p Survey
54
PS1 Review 3p Survey
55
PS1 Review 3p Survey
56
PS1 Review 3p Survey
57
PS1 Review 3p Survey Annual
58
PS1 Review Solar System Survey
60120 3p survey
61 solar system surveying (gri) 5 sweet spot
surveying (w?)
PA SweetSpots w/ TTI paired images
Dark and grey time
All photometric non-photometric nights
multiple filters
59
MOPS TAO Survey Simulations
TOTAL 828 fields 5,460 deg2
Ecliptic Latitude
Ecliptic Longitude w.r.t. Opposition
60
Next Generation Solar System Survey Simulation
NEO rates of motion
61
Next Generation Solar System Survey Simulation
NEO longitudinal rates0.65/day in
sweet-spots -0.30/day at edge of opp.
62
Next Generation Solar System Survey Simulation
0.65/day
First night
Second night
Third night
Declination
Sweet-Spot
RA
63
Next Generation Solar System Survey Simulation
-0.3/day
First night
Second night
Third night
Declination
Opposition
RA
64
Next Generation Solar System Survey Simulation
65
Next Generation Solar System Survey Simulation
Scheduling Efficiency
Region
66
MOPS Synthetic Solar System
250,000 Near Earth Objects (w/ IEOs, Hlt25)
10,000,000 Main Belt
320,000 Trojans (Jupiter)
100,000 Trojans (Mars,Saturn,Uranus)
60,000 Centaurs
72,000 Trans-Neptunian Objects
20,000 Scattered Disk Objects
Jupiter Family Comets
Halley Family Comets
10,000 Long Period Comets
0 Xtreme Objects
10,842,000 TOTAL
10,000
67
NEO Sky-Plane Density
68
Sweet-Spot Motion Vectors
69
MOPS Sub-System Efficiency
TransientDetections
gt99
gt98
gt90
Intra-night Linking
OrbitDetermination
Inter-night Linking
Meta-data
SyntheticSolar System
??
Identification
Database
Attribution
gt90
gt90
Precovery
Two-Night Linking
??
PublishedObjects
Impact RiskAnalysis
GUI
Users
MPC
70
MOPS Sub-System Inter-communication
working
designed
TransientDetections
Intra-night Linking
OrbitDetermination
Inter-night Linking
Meta-data
SyntheticSolar System
Identification
Database
Attribution
Precovery
Two-Night Linking
PublishedObjects
Impact RiskAnalysis
GUI
Users
MPC
71
MOPS Data Collection Interface
  • http//mopsdc.ifa.hawaii.edu/

Synthetic or Real Data
72
MOPS Data Collection Interface
73
MOPS Data Collection Interface
74
MOPS Data Collection Interface
75
MOPS Data Collection Interface
76
Spacewatch Data
77
Spacewatch Data
78
MOPS Software Documentation
)
79
MOPS Unit Simulation Testing
)
80
MOPS Wiki (http//ps1sc.ifa.hawaii.edu/PS1wiki/ind
ex.php/MOPS)
81
MOPS Timeline
  • Operational Readiness Review (ORR)in six months?
  • PS1 ORRin eight months?

82
MOPS Documentation
  • Critical Systems Engineering Documentation
  • Complete Evolving
  • PSDC-510-001 System Concept Definition
  • PSDC-530-001 Software Requirement
    Specification
  • PSDC-530-002 Algorithm Design Description
  • PSDC-530-003 Software Design Description
  • PSDC-940-005 MOPS-IPP Interface Control
    Document
  • PSDC-940-007 MOPS-PSPS Interface Control
    Document
  • PSDC-930-007 MOPS-PSPS Interface Requirement
    Specification
  • Not started
  • Software Version Description
  • Sub-system Test Plan
  • Sub-system Maintenance Plan
  • Software User Manual

83
MOPS Documentation
  • Supplementary Documentation
  • PSDC-500-001 - Orbit Determination Ephemeris
    Software
  • PSDC-500-003 - Solar System Survey Simulation
  • PSDC-500-003 Revised Solar System Survey
    Simulation
  • PSDC-500-004 - Solar System Model
  • PSDC-500-006 - Sour Spots
  • PSDC-NNN-MMM - Efficiency Determinator
    Desirements
  • PSDC-NNN-MMM - Efficiency Determinator Design
  • PSDC-NNN-MMM - Installation
  • PSDC-NNN-MMM - Rare Objects
  • PSDC-NNN-MMM - Trail Fitting
  • PSDC-NNN-MMM - Unit and Simulation Testing
  • PSDC-NNN-MMM - Comet Fitting
  • PSDC-NNN-MMM Data Exchange Standard

84
MOPS Publications Published
85
MOPS Publications In Prep
86
MOPS Publications Future
  • Pan-STARRS Moving Object Processing System

87
Thanks!
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