Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results

Kishalay De; Matthew J. Hankins; Mansi M. Kasliwal; Anna M. Moore; Eran O. Ofek; Scott M. Adams; Michael C.B. Ashley; Aliya Nur Babul; Ashot Bagdasaryan; Kevin B. Burdge; Jill Burnham; Richard G. Dekany; Alexander Declacroix; Antony Galla; Tim Greffe; David Hale; Jacob E. Jencson; Ryan M. Lau; Ashish Mahabal; Daniel McKenna; Manasi Sharma; Patrick L. Shopbell; Roger M. Smith; Jamie Soon; Jennifer Sokoloski; Roberto Soria; Tony Travouillon

doi:10.1088/1538-3873/ab6069

Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results

Kishalay De, Matthew J. Hankins, Mansi M. Kasliwal, Anna M. Moore, Eran O. Ofek, Scott M. Adams, Michael C.B. Ashley, Aliya Nur Babul, Ashot Bagdasaryan, Kevin B. Burdge, Jill Burnham, Richard G. Dekany, Alexander Declacroix, Antony Galla, Tim Greffe, David Hale, Jacob E. Jencson, Ryan M. Lau, Ashish Mahabal, Daniel McKennaManasi Sharma, Patrick L. Shopbell, Roger M. Smith, Jamie Soon, Jennifer Sokoloski, Roberto Soria, Tony Travouillon

Department of Particle Physics and Astrophysics

Weizmann Institute of Science

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Abstract

Palomar Gattini-IR is a new wide-field, near-infrared (NIR) robotic time domain survey operating at Palomar Observatory. Using a 30 cm telescope mounted with a H2RG detector, Gattini-IR achieves a field of view (FOV) of 25 sq. deg. with a pixel scale of 8 7inJ-band. Here, we describe the system design, survey operations, data processing system and on-sky performance of Palomar Gattini-IR. As a part of the nominal survey, Gattini-IR scans ≈7500 square degrees of the sky every night to a median 5σ depth of 15.7 AB mag outside the Galactic plane. The survey covers ≈15,000 square degrees of the sky visible from Palomar with a median cadence of 2 days. A real-time data processing system produces stacked science images from dithered raw images taken on sky, together with point-spread function (PSF)-fit source catalogs and transient candidates identified from subtractions within a median delay of ≈4hr from the time of observation. The calibrated data products achieve an astrometric accuracy (rms) of ≈0 7 with respect to Gaia DR2 for sources with signal-to-noise ratio>10, and better than ≈0 35 for sources brighter than ≈12 Vega mag. The photometric accuracy (rms) achievedinthe PSF-fit source catalogs is better than ≈3% for sources brighter than ≈12 Vega mag and fainter than the saturation magnitude of ≈8.5 Vega mag, as calibrated against the Two Micron All Sky Survey catalog. The detection efficiency of transient candidates injected into the images is better than 90% for sources brighter than the 5σ limiting magnitude. The photometric recovery precision of injected sources is 3% for sources brighter than 13 mag, and the astrometric recovery rms is ≈0 9. Reference images generated by stacking several field visits achieve depths of >16.5 AB mag over 60% of the sky, while it is limited by confusion in the Galactic plane. With a FOV ≈40× larger than any other existing NIR imaging instrument, Gattini-IR is probing the reddest and dustiest transients in the local universe such as dust obscured supernovae in nearby galaxies, novae behind large columns of extinction within the galaxy, reddened microlensing events in the Galactic plane and variability from cool and dust obscured stars. We present results from transients and variables identified since the start of the commissioning period.

Original language	English
Article number	025001
Journal	Publications of the Astronomical Society of the Pacific
Volume	132
Issue number	1008
DOIs	https://doi.org/10.1088/1538-3873/ab6069
State	Published - 13 Jan 2020

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Astronomy and Astrophysics
Space and Planetary Science

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10.1088/1538-3873/ab6069

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De, K., Hankins, M. J., Kasliwal, M. M., Moore, A. M., Ofek, E. O., Adams, S. M., Ashley, M. C. B., Babul, A. N., Bagdasaryan, A., Burdge, K. B., Burnham, J., Dekany, R. G., Declacroix, A., Galla, A., Greffe, T., Hale, D., Jencson, J. E., Lau, R. M., Mahabal, A., ... Travouillon, T. (2020). Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results. Publications of the Astronomical Society of the Pacific, 132(1008), Article 025001. https://doi.org/10.1088/1538-3873/ab6069

@article{e061cc569ecf435fa38ca84ca7ac0b1b,

title = "Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results",

abstract = "Palomar Gattini-IR is a new wide-field, near-infrared (NIR) robotic time domain survey operating at Palomar Observatory. Using a 30 cm telescope mounted with a H2RG detector, Gattini-IR achieves a field of view (FOV) of 25 sq. deg. with a pixel scale of 8 7inJ-band. Here, we describe the system design, survey operations, data processing system and on-sky performance of Palomar Gattini-IR. As a part of the nominal survey, Gattini-IR scans ≈7500 square degrees of the sky every night to a median 5σ depth of 15.7 AB mag outside the Galactic plane. The survey covers ≈15,000 square degrees of the sky visible from Palomar with a median cadence of 2 days. A real-time data processing system produces stacked science images from dithered raw images taken on sky, together with point-spread function (PSF)-fit source catalogs and transient candidates identified from subtractions within a median delay of ≈4hr from the time of observation. The calibrated data products achieve an astrometric accuracy (rms) of ≈0 7 with respect to Gaia DR2 for sources with signal-to-noise ratio>10, and better than ≈0 35 for sources brighter than ≈12 Vega mag. The photometric accuracy (rms) achievedinthe PSF-fit source catalogs is better than ≈3\% for sources brighter than ≈12 Vega mag and fainter than the saturation magnitude of ≈8.5 Vega mag, as calibrated against the Two Micron All Sky Survey catalog. The detection efficiency of transient candidates injected into the images is better than 90\% for sources brighter than the 5σ limiting magnitude. The photometric recovery precision of injected sources is 3\% for sources brighter than 13 mag, and the astrometric recovery rms is ≈0 9. Reference images generated by stacking several field visits achieve depths of >16.5 AB mag over 60\% of the sky, while it is limited by confusion in the Galactic plane. With a FOV ≈40× larger than any other existing NIR imaging instrument, Gattini-IR is probing the reddest and dustiest transients in the local universe such as dust obscured supernovae in nearby galaxies, novae behind large columns of extinction within the galaxy, reddened microlensing events in the Galactic plane and variability from cool and dust obscured stars. We present results from transients and variables identified since the start of the commissioning period.",

author = "Kishalay De and Hankins, \{Matthew J.\} and Kasliwal, \{Mansi M.\} and Moore, \{Anna M.\} and Ofek, \{Eran O.\} and Adams, \{Scott M.\} and Ashley, \{Michael C.B.\} and Babul, \{Aliya Nur\} and Ashot Bagdasaryan and Burdge, \{Kevin B.\} and Jill Burnham and Dekany, \{Richard G.\} and Alexander Declacroix and Antony Galla and Tim Greffe and David Hale and Jencson, \{Jacob E.\} and Lau, \{Ryan M.\} and Ashish Mahabal and Daniel McKenna and Manasi Sharma and Shopbell, \{Patrick L.\} and Smith, \{Roger M.\} and Jamie Soon and Jennifer Sokoloski and Roberto Soria and Tony Travouillon",

note = "We thank A. Fruchter, F. Masci, S. R. Kulkarni, C. Steidel and M. J. Graham for valuable discussions on this work. We thank the anonymous referee for a careful reading of the manuscript that significantly helped improve the quality of the manuscript. M.M.K. and E.O. acknowledge the US-Israel Binational Science Foundation Grant 2016227. M.M.K. and J.L.S. acknowledge the Heising-Simons foundation for support via a Scialog fellowship of the Research Corporation. M.M.K. and A.M.M. acknowledge the Mt Cuba foundation. J. Soon is supported by an Australian Government Research Training Program (RTP) Scholarship. SED Machine is based upon work supported by the National Science Foundation under Grant No. 1106171. Funding Information: K.D. and M.J.H. thank the hospitality of the astrophysics group at the Weizmann Institute of Science, Rehovot, Israel, where part of this work was carried out. This work was supported by the GROWTH (Global Relay of Observatories Watching Transients Happen) project funded by the National Science Foundation under PIRE Grant No 1545949. GROWTH is a collaborative project among the California Institute of Technology (USA), University of Maryland College Park (USA), University of Wisconsin Milwaukee (USA), Texas Tech University (USA), San Diego State University (USA), University of Washington (USA), Los Alamos National Laboratory (USA), Tokyo Institute of Technology (Japan), National Central University (Taiwan), Indian Institute of Astrophysics (India), Indian Institute of Technology Bombay (India), Weizmann Institute of Science (Israel), The Oskar Klein Centre at Stockholm University (Sweden), Humboldt University (Germany), Liverpool John Moores University (UK) and University of Sydney (Australia). Funding Information: The High Performance Wireless Research \& Education Network (HPWREN;https://hpwren.ucsd.edu) is a project at the University of California, San Diego and the National Science Foundation (grant numbers 0087344 (in 2000), 0426879 (in 2004), and 0944131 (in 2009)). This publication makes use of data products from the Two Micron All Sky Survey, which is a joint project of the University of Massachusetts and the Infrared Processing and Analysis Center/California Institute of Technology, funded by NASA and the National Science Foundation. This work has made use of data from the European Space Agency (ESA) mission Gaia (https://www.cosmos.esa.int/gaia), processed by the Gaia Data Processing and Analysis Consortium (DPAC,https://www. cosmos.esa.int/web/gaia/dpac/consortium). Funding for the DPAC has been provided by national institutions, in particular the institutions participating in the Gaia Multilateral Agreement. This work has also made use of the Pan-STARRS1 (PS1) Surveys (http://www.ifa.hawaii.edu/pswww/) and the PS1 public science archive (https://panstarrs.stsci.edu).",

year = "2020",

month = jan,

day = "13",

doi = "10.1088/1538-3873/ab6069",

language = "الإنجليزيّة",

volume = "132",

journal = "Publications of the Astronomical Society of the Pacific",

issn = "0004-6280",

publisher = "Institute of Physics Publishing",

number = "1008",

}

De, K, Hankins, MJ, Kasliwal, MM, Moore, AM, Ofek, EO, Adams, SM, Ashley, MCB, Babul, AN, Bagdasaryan, A, Burdge, KB, Burnham, J, Dekany, RG, Declacroix, A, Galla, A, Greffe, T, Hale, D, Jencson, JE, Lau, RM, Mahabal, A, McKenna, D, Sharma, M, Shopbell, PL, Smith, RM, Soon, J, Sokoloski, J, Soria, R & Travouillon, T 2020, 'Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results', Publications of the Astronomical Society of the Pacific, vol. 132, no. 1008, 025001. https://doi.org/10.1088/1538-3873/ab6069

TY - JOUR

T1 - Palomar gattini-ir

T2 - Survey overview, data processing system, on-sky performance and first results

AU - De, Kishalay

AU - Hankins, Matthew J.

AU - Kasliwal, Mansi M.

AU - Moore, Anna M.

AU - Ofek, Eran O.

AU - Adams, Scott M.

AU - Ashley, Michael C.B.

AU - Babul, Aliya Nur

AU - Bagdasaryan, Ashot

AU - Burdge, Kevin B.

AU - Burnham, Jill

AU - Dekany, Richard G.

AU - Declacroix, Alexander

AU - Galla, Antony

AU - Greffe, Tim

AU - Hale, David

AU - Jencson, Jacob E.

AU - Lau, Ryan M.

AU - Mahabal, Ashish

AU - McKenna, Daniel

AU - Sharma, Manasi

AU - Shopbell, Patrick L.

AU - Smith, Roger M.

AU - Soon, Jamie

AU - Sokoloski, Jennifer

AU - Soria, Roberto

AU - Travouillon, Tony

N1 - We thank A. Fruchter, F. Masci, S. R. Kulkarni, C. Steidel and M. J. Graham for valuable discussions on this work. We thank the anonymous referee for a careful reading of the manuscript that significantly helped improve the quality of the manuscript. M.M.K. and E.O. acknowledge the US-Israel Binational Science Foundation Grant 2016227. M.M.K. and J.L.S. acknowledge the Heising-Simons foundation for support via a Scialog fellowship of the Research Corporation. M.M.K. and A.M.M. acknowledge the Mt Cuba foundation. J. Soon is supported by an Australian Government Research Training Program (RTP) Scholarship. SED Machine is based upon work supported by the National Science Foundation under Grant No. 1106171. Funding Information: K.D. and M.J.H. thank the hospitality of the astrophysics group at the Weizmann Institute of Science, Rehovot, Israel, where part of this work was carried out. This work was supported by the GROWTH (Global Relay of Observatories Watching Transients Happen) project funded by the National Science Foundation under PIRE Grant No 1545949. GROWTH is a collaborative project among the California Institute of Technology (USA), University of Maryland College Park (USA), University of Wisconsin Milwaukee (USA), Texas Tech University (USA), San Diego State University (USA), University of Washington (USA), Los Alamos National Laboratory (USA), Tokyo Institute of Technology (Japan), National Central University (Taiwan), Indian Institute of Astrophysics (India), Indian Institute of Technology Bombay (India), Weizmann Institute of Science (Israel), The Oskar Klein Centre at Stockholm University (Sweden), Humboldt University (Germany), Liverpool John Moores University (UK) and University of Sydney (Australia). Funding Information: The High Performance Wireless Research & Education Network (HPWREN;https://hpwren.ucsd.edu) is a project at the University of California, San Diego and the National Science Foundation (grant numbers 0087344 (in 2000), 0426879 (in 2004), and 0944131 (in 2009)). This publication makes use of data products from the Two Micron All Sky Survey, which is a joint project of the University of Massachusetts and the Infrared Processing and Analysis Center/California Institute of Technology, funded by NASA and the National Science Foundation. This work has made use of data from the European Space Agency (ESA) mission Gaia (https://www.cosmos.esa.int/gaia), processed by the Gaia Data Processing and Analysis Consortium (DPAC,https://www. cosmos.esa.int/web/gaia/dpac/consortium). Funding for the DPAC has been provided by national institutions, in particular the institutions participating in the Gaia Multilateral Agreement. This work has also made use of the Pan-STARRS1 (PS1) Surveys (http://www.ifa.hawaii.edu/pswww/) and the PS1 public science archive (https://panstarrs.stsci.edu).

PY - 2020/1/13

Y1 - 2020/1/13

N2 - Palomar Gattini-IR is a new wide-field, near-infrared (NIR) robotic time domain survey operating at Palomar Observatory. Using a 30 cm telescope mounted with a H2RG detector, Gattini-IR achieves a field of view (FOV) of 25 sq. deg. with a pixel scale of 8 7inJ-band. Here, we describe the system design, survey operations, data processing system and on-sky performance of Palomar Gattini-IR. As a part of the nominal survey, Gattini-IR scans ≈7500 square degrees of the sky every night to a median 5σ depth of 15.7 AB mag outside the Galactic plane. The survey covers ≈15,000 square degrees of the sky visible from Palomar with a median cadence of 2 days. A real-time data processing system produces stacked science images from dithered raw images taken on sky, together with point-spread function (PSF)-fit source catalogs and transient candidates identified from subtractions within a median delay of ≈4hr from the time of observation. The calibrated data products achieve an astrometric accuracy (rms) of ≈0 7 with respect to Gaia DR2 for sources with signal-to-noise ratio>10, and better than ≈0 35 for sources brighter than ≈12 Vega mag. The photometric accuracy (rms) achievedinthe PSF-fit source catalogs is better than ≈3% for sources brighter than ≈12 Vega mag and fainter than the saturation magnitude of ≈8.5 Vega mag, as calibrated against the Two Micron All Sky Survey catalog. The detection efficiency of transient candidates injected into the images is better than 90% for sources brighter than the 5σ limiting magnitude. The photometric recovery precision of injected sources is 3% for sources brighter than 13 mag, and the astrometric recovery rms is ≈0 9. Reference images generated by stacking several field visits achieve depths of >16.5 AB mag over 60% of the sky, while it is limited by confusion in the Galactic plane. With a FOV ≈40× larger than any other existing NIR imaging instrument, Gattini-IR is probing the reddest and dustiest transients in the local universe such as dust obscured supernovae in nearby galaxies, novae behind large columns of extinction within the galaxy, reddened microlensing events in the Galactic plane and variability from cool and dust obscured stars. We present results from transients and variables identified since the start of the commissioning period.

AB - Palomar Gattini-IR is a new wide-field, near-infrared (NIR) robotic time domain survey operating at Palomar Observatory. Using a 30 cm telescope mounted with a H2RG detector, Gattini-IR achieves a field of view (FOV) of 25 sq. deg. with a pixel scale of 8 7inJ-band. Here, we describe the system design, survey operations, data processing system and on-sky performance of Palomar Gattini-IR. As a part of the nominal survey, Gattini-IR scans ≈7500 square degrees of the sky every night to a median 5σ depth of 15.7 AB mag outside the Galactic plane. The survey covers ≈15,000 square degrees of the sky visible from Palomar with a median cadence of 2 days. A real-time data processing system produces stacked science images from dithered raw images taken on sky, together with point-spread function (PSF)-fit source catalogs and transient candidates identified from subtractions within a median delay of ≈4hr from the time of observation. The calibrated data products achieve an astrometric accuracy (rms) of ≈0 7 with respect to Gaia DR2 for sources with signal-to-noise ratio>10, and better than ≈0 35 for sources brighter than ≈12 Vega mag. The photometric accuracy (rms) achievedinthe PSF-fit source catalogs is better than ≈3% for sources brighter than ≈12 Vega mag and fainter than the saturation magnitude of ≈8.5 Vega mag, as calibrated against the Two Micron All Sky Survey catalog. The detection efficiency of transient candidates injected into the images is better than 90% for sources brighter than the 5σ limiting magnitude. The photometric recovery precision of injected sources is 3% for sources brighter than 13 mag, and the astrometric recovery rms is ≈0 9. Reference images generated by stacking several field visits achieve depths of >16.5 AB mag over 60% of the sky, while it is limited by confusion in the Galactic plane. With a FOV ≈40× larger than any other existing NIR imaging instrument, Gattini-IR is probing the reddest and dustiest transients in the local universe such as dust obscured supernovae in nearby galaxies, novae behind large columns of extinction within the galaxy, reddened microlensing events in the Galactic plane and variability from cool and dust obscured stars. We present results from transients and variables identified since the start of the commissioning period.

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U2 - 10.1088/1538-3873/ab6069

DO - 10.1088/1538-3873/ab6069

M3 - مقالة

SN - 0004-6280

VL - 132

JO - Publications of the Astronomical Society of the Pacific

JF - Publications of the Astronomical Society of the Pacific

IS - 1008

M1 - 025001

ER -

Palomar gattini-ir: Survey overview, data processing system, on-sky performance and first results

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