The LOFAR long baseline snapshot calibrator survey

J. Moldón; A. T. Deller; O. Wucknitz; N. Jackson; A. Drabent; T. Carozzi; J. Conway; A. D. Kapínska; J. P. Mckean; L. Morabito; E. Varenius; P. Zarka; J. Anderson; A. Asgekar; I. M. Avruch; M. E. Bell; M. J. Bentum; G. Bernardi; P. Best; L. BÎrzan; J. Bregman; F. Breitling; J. W. Broderick; M. Brüggen; H. R. Butcher; D. Carbone; B. Ciardi; F. De Gasperin; E. De Geus; S. Duscha; J. Eislöffe; D. Engels; H. Falcke; R. A. Fallows; R. Fender; C. Ferrari; W. Frieswijk; M. A. Garrett; J. Grießmeier; A. W. Gunst; J. P. Hamaker; T. E. Hassall; G. Heald; M. Hoeft; E. Juette; A. Karastergiou; V. I. Kondratiev; M. Kramer; M. Kuniyoshi; G. Kuper; P. Maat; G. Mann; S. Markoff; R. Mcfadden; D. Mckay-Bukowski; R. Morganti; H. Munk; M. J. Norden; A. R. Offringa; E. Orru; H. Paas; M. Pandey-Pommier; R. Pizzo; A. G. Polatidis; W. Reich; H. Röttgering; A. Rowlinson; A. M.M. Scaife; D. Schwarz; J. Sluman; O. Smirnov; B. W. Stappers; M. Steinmetz; M. Tagger; Y. Tang; C. Tasse; S. Thoudam; M. C. Toribio; R. Vermeulen; C. Vocks; R. J. Van Weeren; S. White; M. W. Wise; S. Yatawatta; A. Zensus

doi:10.1051/0004-6361/201425042

The LOFAR long baseline snapshot calibrator survey

J. Moldón
, A. T. Deller
, O. Wucknitz
, N. Jackson
, A. Drabent
, T. Carozzi
, J. Conway
, A. D. Kapínska
, J. P. Mckean
, L. Morabito
, E. Varenius
, P. Zarka
, J. Anderson
, A. Asgekar
, I. M. Avruch
, M. E. Bell
, M. J. Bentum
, G. Bernardi
, P. Best
, L. BÎrzan

J. Bregman, F. Breitling, J. W. Broderick, M. Brüggen, H. R. Butcher, D. Carbone, B. Ciardi, F. De Gasperin, E. De Geus, S. Duscha, J. Eislöffe, D. Engels, H. Falcke, R. A. Fallows, R. Fender, C. Ferrari, W. Frieswijk, M. A. Garrett, J. Grießmeier, A. W. Gunst, J. P. Hamaker, T. E. Hassall, G. Heald, M. Hoeft, E. Juette, A. Karastergiou, V. I. Kondratiev, M. Kramer, M. Kuniyoshi, G. Kuper, P. Maat, G. Mann, S. Markoff, R. Mcfadden, D. Mckay-Bukowski, R. Morganti, H. Munk, M. J. Norden, A. R. Offringa, E. Orru, H. Paas, M. Pandey-Pommier, R. Pizzo, A. G. Polatidis, W. Reich, H. Röttgering, A. Rowlinson, A. M.M. Scaife, D. Schwarz, J. Sluman, O. Smirnov, B. W. Stappers, M. Steinmetz, M. Tagger, Y. Tang, C. Tasse, S. Thoudam, M. C. Toribio, R. Vermeulen, C. Vocks, R. J. Van Weeren, S. White, M. W. Wise, S. Yatawatta, A. Zensus

Physics

Netherlands Institute of Radio Astronomy (ASTRON)
Max-Planck-Institut für Radioastronomie
University of Manchester
Thüringer Landessternwarte
Onsala Space Observatory
University of Portsmouth
University of Sydney
Curtin University
Leiden University
LESIA - Laboratoire d'Etudes Spatiales et d'Instrumentation en Astrophysique
GFZ German Research Centre for Geosciences
Shell Technology Center
SRON Netherlands Insitute for Space Research
University of Groningen
CSIRO Australia Telescope National Facility
University of Twente
Harvard-Smithsonian Center for Astrophysics
University of Edinburgh, Institute for Astronomy
Leibniz-Institut für Astrophysik Potsdam (AIP)
University of Oxford
University of Southampton
Universität Hamburg
Australian National University
University of Amsterdam
Max Planck Institute for Astrophysics
SmarterVision BV
Radboud University Nijmegen
Laboratoire Lagrange, UMR 7293, Université de Nice Sophia-Antipolis, CNRS, Observatoire de la Côte d'Azur
LPC2E - Univ. d'Orléans/cnrs
University of Bochum
P. N. Lebedev Physical Institute
Sodankylä Geophysical Observatory
Harwell Science and Innovation Campus
University Groningen
Observatoire de Lyon
Universität Bielefeld
Rhodes University
SKA South Africa
Observatoire de Paris

Research output: Contribution to journal › Article › peer-review

32 Scopus citations

Abstract

Aims. An efficient means of locating calibrator sources for international LOw Frequency ARray (LOFAR) is developed and used to determine the average density of usable calibrator sources on the sky for subarcsecond observations at 140 MHz. Methods. We used the multi-beaming capability of LOFAR to conduct a fast and computationally inexpensive survey with the full international LOFAR array. Sources were preselected on the basis of 325 MHz arcminute-scale flux density using existing catalogues. By observing 30 different sources in each of the 12 sets of pointings per hour, we were able to inspect 630 sources in two hours to determine if they possess a sufficiently bright compact component to be usable as LOFAR delay calibrators. Results. More than 40% of the observed sources are detected on multiple baselines between international stations and 86 are classified as satisfactory calibrators. We show that a flat low-frequency spectrum (from 74 to 325 MHz) is the best predictor of compactness at 140 MHz. We extrapolate from our sample to show that the sky density of calibrators that are sufficiently bright to calibrate dispersive and non-dispersive delays for the international LOFAR using existing methods is 1.0 per square degree. Conclusions. The observed density of satisfactory delay calibrator sources means that observations with international LOFAR should be possible at virtually any point in the sky provided that a fast and efficient search, using the methodology described here, is conducted prior to the observation to identify the best calibrator.

Original language	British English
Article number	A73
Journal	Astronomy and Astrophysics
Volume	574
DOIs	https://doi.org/10.1051/0004-6361/201425042
State	Published - 2015

Keywords

Catalogs
Instrumentation: High angular resolution
Instrumentation: Interferometers
Methods: Observational
Techniques: High angular resolution
Techniques: Interferometric

Access to Document

10.1051/0004-6361/201425042

OpenUrl availability

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Cite this

Moldón, J., Deller, A. T., Wucknitz, O., Jackson, N., Drabent, A., Carozzi, T., Conway, J., Kapínska, A. D., Mckean, J. P., Morabito, L., Varenius, E., Zarka, P., Anderson, J., Asgekar, A., Avruch, I. M., Bell, M. E., Bentum, M. J., Bernardi, G., Best, P., ... Zensus, A. (2015). The LOFAR long baseline snapshot calibrator survey. Astronomy and Astrophysics, 574, Article A73. https://doi.org/10.1051/0004-6361/201425042

@article{36f59a1a231d4cd3b1023d480a376093,

title = "The LOFAR long baseline snapshot calibrator survey",

abstract = "Aims. An efficient means of locating calibrator sources for international LOw Frequency ARray (LOFAR) is developed and used to determine the average density of usable calibrator sources on the sky for subarcsecond observations at 140 MHz. Methods. We used the multi-beaming capability of LOFAR to conduct a fast and computationally inexpensive survey with the full international LOFAR array. Sources were preselected on the basis of 325 MHz arcminute-scale flux density using existing catalogues. By observing 30 different sources in each of the 12 sets of pointings per hour, we were able to inspect 630 sources in two hours to determine if they possess a sufficiently bright compact component to be usable as LOFAR delay calibrators. Results. More than 40\% of the observed sources are detected on multiple baselines between international stations and 86 are classified as satisfactory calibrators. We show that a flat low-frequency spectrum (from 74 to 325 MHz) is the best predictor of compactness at 140 MHz. We extrapolate from our sample to show that the sky density of calibrators that are sufficiently bright to calibrate dispersive and non-dispersive delays for the international LOFAR using existing methods is 1.0 per square degree. Conclusions. The observed density of satisfactory delay calibrator sources means that observations with international LOFAR should be possible at virtually any point in the sky provided that a fast and efficient search, using the methodology described here, is conducted prior to the observation to identify the best calibrator.",

keywords = "Catalogs, Instrumentation: High angular resolution, Instrumentation: Interferometers, Methods: Observational, Techniques: High angular resolution, Techniques: Interferometric",

author = "J. Mold{\'o}n and Deller, \{A. T.\} and O. Wucknitz and N. Jackson and A. Drabent and T. Carozzi and J. Conway and Kap{\'i}nska, \{A. D.\} and Mckean, \{J. P.\} and L. Morabito and E. Varenius and P. Zarka and J. Anderson and A. Asgekar and Avruch, \{I. M.\} and Bell, \{M. E.\} and Bentum, \{M. J.\} and G. Bernardi and P. Best and L. B{\^I}rzan and J. Bregman and F. Breitling and Broderick, \{J. W.\} and M. Br{\"u}ggen and Butcher, \{H. R.\} and D. Carbone and B. Ciardi and \{De Gasperin\}, F. and \{De Geus\}, E. and S. Duscha and J. Eisl{\"o}ffe and D. Engels and H. Falcke and Fallows, \{R. A.\} and R. Fender and C. Ferrari and W. Frieswijk and Garrett, \{M. A.\} and J. Grie{\ss}meier and Gunst, \{A. W.\} and Hamaker, \{J. P.\} and Hassall, \{T. E.\} and G. Heald and M. Hoeft and E. Juette and A. Karastergiou and Kondratiev, \{V. I.\} and M. Kramer and M. Kuniyoshi and G. Kuper and P. Maat and G. Mann and S. Markoff and R. Mcfadden and D. Mckay-Bukowski and R. Morganti and H. Munk and Norden, \{M. J.\} and Offringa, \{A. R.\} and E. Orru and H. Paas and M. Pandey-Pommier and R. Pizzo and Polatidis, \{A. G.\} and W. Reich and H. R{\"o}ttgering and A. Rowlinson and Scaife, \{A. M.M.\} and D. Schwarz and J. Sluman and O. Smirnov and Stappers, \{B. W.\} and M. Steinmetz and M. Tagger and Y. Tang and C. Tasse and S. Thoudam and Toribio, \{M. C.\} and R. Vermeulen and C. Vocks and \{Van Weeren\}, \{R. J.\} and S. White and Wise, \{M. W.\} and S. Yatawatta and A. Zensus",

note = "Funding Information: Acknowledgements. LOFAR, the Low Frequency Array designed and constructed by ASTRON, has facilities in several countries that are owned by various parties (each with their own funding sources), and that are collectively operated by the international LOFAR Telescope (ILT) foundation under a joint scientific policy. A.T.D. is supported by a Veni Fellowship from NWO. A.D.K. acknowledges support from the Australian Research Council Centre of Excellence for All-sky Astrophysics (CAASTRO), through project number CE110001020. LKM acknowledges financial support from NWO Top LOFAR project, project n. 614.001.006. CF acknowledges financial support by the Agence Nationale de la Recherche through grant ANR-09-JCJC-0001-01. Funding Information: LOFAR, the Low Frequency Array designed and constructed by ASTRON, has facilities in several countries that are owned by various parties (each with their own funding sources), and that are collectively operated by the international LOFAR Telescope (ILT) foundation under a joint scientific policy. A.T.D. is supported by a Veni Fellowship from NWO. A.D.K. acknowledges support from the Australian Research Council Centre of Excellence for All-sky Astrophysics (CAASTRO), through project number CE110001020. LKM acknowledges financial support from NWO Top LOFAR project, project n. 614.001.006. CF acknowledges financial support by the Agence Nationale de la Recherche through grant ANR-09-JCJC-0001-01. Publisher Copyright: {\textcopyright} ESO 2015.",

year = "2015",

doi = "10.1051/0004-6361/201425042",

language = "British English",

volume = "574",

journal = "Astronomy and Astrophysics",

issn = "0004-6361",

publisher = "EDP Sciences",

}

Moldón, J, Deller, AT, Wucknitz, O, Jackson, N, Drabent, A, Carozzi, T, Conway, J, Kapínska, AD, Mckean, JP, Morabito, L, Varenius, E, Zarka, P, Anderson, J, Asgekar, A, Avruch, IM, Bell, ME, Bentum, MJ, Bernardi, G, Best, P, BÎrzan, L, Bregman, J, Breitling, F, Broderick, JW, Brüggen, M, Butcher, HR, Carbone, D, Ciardi, B, De Gasperin, F, De Geus, E, Duscha, S, Eislöffe, J, Engels, D, Falcke, H, Fallows, RA, Fender, R, Ferrari, C, Frieswijk, W, Garrett, MA, Grießmeier, J, Gunst, AW, Hamaker, JP, Hassall, TE, Heald, G, Hoeft, M, Juette, E, Karastergiou, A, Kondratiev, VI, Kramer, M, Kuniyoshi, M, Kuper, G, Maat, P, Mann, G, Markoff, S, Mcfadden, R, Mckay-Bukowski, D, Morganti, R, Munk, H, Norden, MJ, Offringa, AR, Orru, E, Paas, H, Pandey-Pommier, M, Pizzo, R, Polatidis, AG, Reich, W, Röttgering, H, Rowlinson, A, Scaife, AMM, Schwarz, D, Sluman, J, Smirnov, O, Stappers, BW, Steinmetz, M, Tagger, M, Tang, Y, Tasse, C, Thoudam, S, Toribio, MC, Vermeulen, R, Vocks, C, Van Weeren, RJ, White, S, Wise, MW, Yatawatta, S & Zensus, A 2015, 'The LOFAR long baseline snapshot calibrator survey', Astronomy and Astrophysics, vol. 574, A73. https://doi.org/10.1051/0004-6361/201425042

TY - JOUR

T1 - The LOFAR long baseline snapshot calibrator survey

AU - Moldón, J.

AU - Deller, A. T.

AU - Wucknitz, O.

AU - Jackson, N.

AU - Drabent, A.

AU - Carozzi, T.

AU - Conway, J.

AU - Kapínska, A. D.

AU - Mckean, J. P.

AU - Morabito, L.

AU - Varenius, E.

AU - Zarka, P.

AU - Anderson, J.

AU - Asgekar, A.

AU - Avruch, I. M.

AU - Bell, M. E.

AU - Bentum, M. J.

AU - Bernardi, G.

AU - Best, P.

AU - BÎrzan, L.

AU - Bregman, J.

AU - Breitling, F.

AU - Broderick, J. W.

AU - Brüggen, M.

AU - Butcher, H. R.

AU - Carbone, D.

AU - Ciardi, B.

AU - De Gasperin, F.

AU - De Geus, E.

AU - Duscha, S.

AU - Eislöffe, J.

AU - Engels, D.

AU - Falcke, H.

AU - Fallows, R. A.

AU - Fender, R.

AU - Ferrari, C.

AU - Frieswijk, W.

AU - Garrett, M. A.

AU - Grießmeier, J.

AU - Gunst, A. W.

AU - Hamaker, J. P.

AU - Hassall, T. E.

AU - Heald, G.

AU - Hoeft, M.

AU - Juette, E.

AU - Karastergiou, A.

AU - Kondratiev, V. I.

AU - Kramer, M.

AU - Kuniyoshi, M.

AU - Kuper, G.

AU - Maat, P.

AU - Mann, G.

AU - Markoff, S.

AU - Mcfadden, R.

AU - Mckay-Bukowski, D.

AU - Morganti, R.

AU - Munk, H.

AU - Norden, M. J.

AU - Offringa, A. R.

AU - Orru, E.

AU - Paas, H.

AU - Pandey-Pommier, M.

AU - Pizzo, R.

AU - Polatidis, A. G.

AU - Reich, W.

AU - Röttgering, H.

AU - Rowlinson, A.

AU - Scaife, A. M.M.

AU - Schwarz, D.

AU - Sluman, J.

AU - Smirnov, O.

AU - Stappers, B. W.

AU - Steinmetz, M.

AU - Tagger, M.

AU - Tang, Y.

AU - Tasse, C.

AU - Thoudam, S.

AU - Toribio, M. C.

AU - Vermeulen, R.

AU - Vocks, C.

AU - Van Weeren, R. J.

AU - White, S.

AU - Wise, M. W.

AU - Yatawatta, S.

AU - Zensus, A.

N1 - Funding Information: Acknowledgements. LOFAR, the Low Frequency Array designed and constructed by ASTRON, has facilities in several countries that are owned by various parties (each with their own funding sources), and that are collectively operated by the international LOFAR Telescope (ILT) foundation under a joint scientific policy. A.T.D. is supported by a Veni Fellowship from NWO. A.D.K. acknowledges support from the Australian Research Council Centre of Excellence for All-sky Astrophysics (CAASTRO), through project number CE110001020. LKM acknowledges financial support from NWO Top LOFAR project, project n. 614.001.006. CF acknowledges financial support by the Agence Nationale de la Recherche through grant ANR-09-JCJC-0001-01. Funding Information: LOFAR, the Low Frequency Array designed and constructed by ASTRON, has facilities in several countries that are owned by various parties (each with their own funding sources), and that are collectively operated by the international LOFAR Telescope (ILT) foundation under a joint scientific policy. A.T.D. is supported by a Veni Fellowship from NWO. A.D.K. acknowledges support from the Australian Research Council Centre of Excellence for All-sky Astrophysics (CAASTRO), through project number CE110001020. LKM acknowledges financial support from NWO Top LOFAR project, project n. 614.001.006. CF acknowledges financial support by the Agence Nationale de la Recherche through grant ANR-09-JCJC-0001-01. Publisher Copyright: © ESO 2015.

PY - 2015

Y1 - 2015

N2 - Aims. An efficient means of locating calibrator sources for international LOw Frequency ARray (LOFAR) is developed and used to determine the average density of usable calibrator sources on the sky for subarcsecond observations at 140 MHz. Methods. We used the multi-beaming capability of LOFAR to conduct a fast and computationally inexpensive survey with the full international LOFAR array. Sources were preselected on the basis of 325 MHz arcminute-scale flux density using existing catalogues. By observing 30 different sources in each of the 12 sets of pointings per hour, we were able to inspect 630 sources in two hours to determine if they possess a sufficiently bright compact component to be usable as LOFAR delay calibrators. Results. More than 40% of the observed sources are detected on multiple baselines between international stations and 86 are classified as satisfactory calibrators. We show that a flat low-frequency spectrum (from 74 to 325 MHz) is the best predictor of compactness at 140 MHz. We extrapolate from our sample to show that the sky density of calibrators that are sufficiently bright to calibrate dispersive and non-dispersive delays for the international LOFAR using existing methods is 1.0 per square degree. Conclusions. The observed density of satisfactory delay calibrator sources means that observations with international LOFAR should be possible at virtually any point in the sky provided that a fast and efficient search, using the methodology described here, is conducted prior to the observation to identify the best calibrator.

AB - Aims. An efficient means of locating calibrator sources for international LOw Frequency ARray (LOFAR) is developed and used to determine the average density of usable calibrator sources on the sky for subarcsecond observations at 140 MHz. Methods. We used the multi-beaming capability of LOFAR to conduct a fast and computationally inexpensive survey with the full international LOFAR array. Sources were preselected on the basis of 325 MHz arcminute-scale flux density using existing catalogues. By observing 30 different sources in each of the 12 sets of pointings per hour, we were able to inspect 630 sources in two hours to determine if they possess a sufficiently bright compact component to be usable as LOFAR delay calibrators. Results. More than 40% of the observed sources are detected on multiple baselines between international stations and 86 are classified as satisfactory calibrators. We show that a flat low-frequency spectrum (from 74 to 325 MHz) is the best predictor of compactness at 140 MHz. We extrapolate from our sample to show that the sky density of calibrators that are sufficiently bright to calibrate dispersive and non-dispersive delays for the international LOFAR using existing methods is 1.0 per square degree. Conclusions. The observed density of satisfactory delay calibrator sources means that observations with international LOFAR should be possible at virtually any point in the sky provided that a fast and efficient search, using the methodology described here, is conducted prior to the observation to identify the best calibrator.

KW - Catalogs

KW - Instrumentation: High angular resolution

KW - Instrumentation: Interferometers

KW - Methods: Observational

KW - Techniques: High angular resolution

KW - Techniques: Interferometric

UR - https://www.scopus.com/pages/publications/85006437595

U2 - 10.1051/0004-6361/201425042

DO - 10.1051/0004-6361/201425042

M3 - Article

AN - SCOPUS:85006437595

SN - 0004-6361

VL - 574

JO - Astronomy and Astrophysics

JF - Astronomy and Astrophysics

M1 - A73

ER -

The LOFAR long baseline snapshot calibrator survey

Abstract

Keywords

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