COMAP Early Science. III. CO Data Processing

Marie K. Foss; Håvard T. Ihle; Jowita Borowska; Kieran A. Cleary; Hans Kristian Eriksen; Stuart E. Harper; Junhan Kim; James W. Lamb; Jonas G. S. Lunde; Liju Philip; Maren Rasmussen; Nils-Ole Stutzer; Bade D. Uzgil; Duncan J. Watts; Ingunn K. Wehus; David P. Woody; J. Richard Bond; Patrick C. Breysse; Morgan Catha; Sarah E. Church; Dongwoo T. Chung; Clive Dickinson; Delaney A. Dunne; Todd Gaier; Joshua Ott Gundersen; Andrew I. Harris; Richard Hobbs; Charles R. Lawrence; Norman Murray; Anthony C. S. Readhead; Hamsa Padmanabhan; Timothy J. Pearson; Thomas J. Rennie; Comap Collaboration

doi:10.3847/1538-4357/ac63ca

COMAP Early Science. III. CO Data Processing

Marie K. Foss
, Håvard T. Ihle
, Jowita Borowska
, Kieran A. Cleary
, Hans Kristian Eriksen
, Stuart E. Harper
, Junhan Kim
, James W. Lamb
, Jonas G. S. Lunde
, Liju Philip
, Maren Rasmussen
, Nils-Ole Stutzer
, Bade D. Uzgil
, Duncan J. Watts
, Ingunn K. Wehus
, David P. Woody
, J. Richard Bond
, Patrick C. Breysse
, Morgan Catha
, Sarah E. Church

Dongwoo T. Chung, Clive Dickinson, Delaney A. Dunne, Todd Gaier, Joshua Ott Gundersen, Andrew I. Harris, Richard Hobbs, Charles R. Lawrence, Norman Murray, Anthony C. S. Readhead, Hamsa Padmanabhan, Timothy J. Pearson, Thomas J. Rennie, Comap Collaboration

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

Abstract

We describe the first-season CO Mapping Array Project (COMAP) analysis pipeline that converts raw detector readouts to calibrated sky maps. This pipeline implements four main steps: gain calibration, filtering, data selection, and mapmaking. Absolute gain calibration relies on a combination of instrumental and astrophysical sources, while relative gain calibration exploits real-time total-power variations. High-efficiency filtering is achieved through spectroscopic common-mode rejection within and across receivers, resulting in nearly uncorrelated white noise within single-frequency channels. Consequently, near-optimal but biased maps are produced by binning the filtered time stream into pixelized maps; the corresponding signal bias transfer function is estimated through simulations. Data selection is performed automatically through a series of goodness-of-fit statistics, including χ ² and multiscale correlation tests. Applying this pipeline to the first-season COMAP data, we produce a data set with very low levels of correlated noise. We find that one of our two scanning strategies (the Lissajous type) is sensitive to residual instrumental systematics. As a result, we no longer use this type of scan and exclude data taken this way from our Season 1 power spectrum estimates. We perform a careful analysis of our data processing and observing efficiencies and take account of planned improvements to estimate our future performance. Power spectrum results derived from the first-season COMAP maps are presented and discussed in companion papers.

Original language	English
Journal	The Astrophysical Journal
Volume	933
DOIs	https://doi.org/10.3847/1538-4357/ac63ca
Publication status	Published - 1 Jul 2022

Keywords

Cosmological evolution
CO line emission
High-redshift galaxies
Molecular gas
Radio astronomy
336
262
734
1073
1338
Astrophysics - Instrumentation and Methods for Astrophysics
Astrophysics - Cosmology and Nongalactic Astrophysics
Astrophysics - Astrophysics of Galaxies

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10.3847/1538-4357/ac63ca

https://ui.adsabs.harvard.edu/abs/2022ApJ...933..184F

Cite this

Foss, M. K., Ihle, H. T., Borowska, J., Cleary, K. A., Eriksen, H. K., Harper, S. E., Kim, J., Lamb, J. W., Lunde, J. G. S., Philip, L., Rasmussen, M., Stutzer, N.-O., Uzgil, B. D., Watts, D. J., Wehus, I. K., Woody, D. P., Bond, J. R., Breysse, P. C., Catha, M., ... Collaboration, C. (2022). COMAP Early Science. III. CO Data Processing. The Astrophysical Journal, 933. https://doi.org/10.3847/1538-4357/ac63ca

@article{65ea923c2d4b4c50808ce717b6ef7a44,

title = "COMAP Early Science. III. CO Data Processing",

abstract = "We describe the first-season CO Mapping Array Project (COMAP) analysis pipeline that converts raw detector readouts to calibrated sky maps. This pipeline implements four main steps: gain calibration, filtering, data selection, and mapmaking. Absolute gain calibration relies on a combination of instrumental and astrophysical sources, while relative gain calibration exploits real-time total-power variations. High-efficiency filtering is achieved through spectroscopic common-mode rejection within and across receivers, resulting in nearly uncorrelated white noise within single-frequency channels. Consequently, near-optimal but biased maps are produced by binning the filtered time stream into pixelized maps; the corresponding signal bias transfer function is estimated through simulations. Data selection is performed automatically through a series of goodness-of-fit statistics, including χ 2 and multiscale correlation tests. Applying this pipeline to the first-season COMAP data, we produce a data set with very low levels of correlated noise. We find that one of our two scanning strategies (the Lissajous type) is sensitive to residual instrumental systematics. As a result, we no longer use this type of scan and exclude data taken this way from our Season 1 power spectrum estimates. We perform a careful analysis of our data processing and observing efficiencies and take account of planned improvements to estimate our future performance. Power spectrum results derived from the first-season COMAP maps are presented and discussed in companion papers.",

keywords = "Cosmological evolution, CO line emission, High-redshift galaxies, Molecular gas, Radio astronomy, 336, 262, 734, 1073, 1338, Astrophysics - Instrumentation and Methods for Astrophysics, Astrophysics - Cosmology and Nongalactic Astrophysics, Astrophysics - Astrophysics of Galaxies",

author = "Foss, \{Marie K.\} and Ihle, \{H{\aa}vard T.\} and Jowita Borowska and Cleary, \{Kieran A.\} and Eriksen, \{Hans Kristian\} and Harper, \{Stuart E.\} and Junhan Kim and Lamb, \{James W.\} and Lunde, \{Jonas G. S.\} and Liju Philip and Maren Rasmussen and Nils-Ole Stutzer and Uzgil, \{Bade D.\} and Watts, \{Duncan J.\} and Wehus, \{Ingunn K.\} and Woody, \{David P.\} and Bond, \{J. Richard\} and Breysse, \{Patrick C.\} and Morgan Catha and Church, \{Sarah E.\} and Chung, \{Dongwoo T.\} and Clive Dickinson and Dunne, \{Delaney A.\} and Todd Gaier and Gundersen, \{Joshua Ott\} and Harris, \{Andrew I.\} and Richard Hobbs and Lawrence, \{Charles R.\} and Norman Murray and Readhead, \{Anthony C. S.\} and Hamsa Padmanabhan and Pearson, \{Timothy J.\} and Rennie, \{Thomas J.\} and Comap Collaboration",

year = "2022",

month = jul,

day = "1",

doi = "10.3847/1538-4357/ac63ca",

language = "English",

volume = "933",

journal = "The Astrophysical Journal",

issn = "0004-637X",

publisher = "American Astronomical Society",

}

Foss, MK, Ihle, HT, Borowska, J, Cleary, KA, Eriksen, HK, Harper, SE, Kim, J, Lamb, JW, Lunde, JGS, Philip, L, Rasmussen, M, Stutzer, N-O, Uzgil, BD, Watts, DJ, Wehus, IK, Woody, DP, Bond, JR, Breysse, PC, Catha, M, Church, SE, Chung, DT, Dickinson, C, Dunne, DA, Gaier, T, Gundersen, JO, Harris, AI, Hobbs, R, Lawrence, CR, Murray, N, Readhead, ACS, Padmanabhan, H, Pearson, TJ, Rennie, TJ & Collaboration, C 2022, 'COMAP Early Science. III. CO Data Processing', The Astrophysical Journal, vol. 933. https://doi.org/10.3847/1538-4357/ac63ca

TY - JOUR

T1 - COMAP Early Science. III. CO Data Processing

AU - Foss, Marie K.

AU - Ihle, Håvard T.

AU - Borowska, Jowita

AU - Cleary, Kieran A.

AU - Eriksen, Hans Kristian

AU - Harper, Stuart E.

AU - Kim, Junhan

AU - Lamb, James W.

AU - Lunde, Jonas G. S.

AU - Philip, Liju

AU - Rasmussen, Maren

AU - Stutzer, Nils-Ole

AU - Uzgil, Bade D.

AU - Watts, Duncan J.

AU - Wehus, Ingunn K.

AU - Woody, David P.

AU - Bond, J. Richard

AU - Breysse, Patrick C.

AU - Catha, Morgan

AU - Church, Sarah E.

AU - Chung, Dongwoo T.

AU - Dickinson, Clive

AU - Dunne, Delaney A.

AU - Gaier, Todd

AU - Gundersen, Joshua Ott

AU - Harris, Andrew I.

AU - Hobbs, Richard

AU - Lawrence, Charles R.

AU - Murray, Norman

AU - Readhead, Anthony C. S.

AU - Padmanabhan, Hamsa

AU - Pearson, Timothy J.

AU - Rennie, Thomas J.

AU - Collaboration, Comap

PY - 2022/7/1

Y1 - 2022/7/1

N2 - We describe the first-season CO Mapping Array Project (COMAP) analysis pipeline that converts raw detector readouts to calibrated sky maps. This pipeline implements four main steps: gain calibration, filtering, data selection, and mapmaking. Absolute gain calibration relies on a combination of instrumental and astrophysical sources, while relative gain calibration exploits real-time total-power variations. High-efficiency filtering is achieved through spectroscopic common-mode rejection within and across receivers, resulting in nearly uncorrelated white noise within single-frequency channels. Consequently, near-optimal but biased maps are produced by binning the filtered time stream into pixelized maps; the corresponding signal bias transfer function is estimated through simulations. Data selection is performed automatically through a series of goodness-of-fit statistics, including χ 2 and multiscale correlation tests. Applying this pipeline to the first-season COMAP data, we produce a data set with very low levels of correlated noise. We find that one of our two scanning strategies (the Lissajous type) is sensitive to residual instrumental systematics. As a result, we no longer use this type of scan and exclude data taken this way from our Season 1 power spectrum estimates. We perform a careful analysis of our data processing and observing efficiencies and take account of planned improvements to estimate our future performance. Power spectrum results derived from the first-season COMAP maps are presented and discussed in companion papers.

AB - We describe the first-season CO Mapping Array Project (COMAP) analysis pipeline that converts raw detector readouts to calibrated sky maps. This pipeline implements four main steps: gain calibration, filtering, data selection, and mapmaking. Absolute gain calibration relies on a combination of instrumental and astrophysical sources, while relative gain calibration exploits real-time total-power variations. High-efficiency filtering is achieved through spectroscopic common-mode rejection within and across receivers, resulting in nearly uncorrelated white noise within single-frequency channels. Consequently, near-optimal but biased maps are produced by binning the filtered time stream into pixelized maps; the corresponding signal bias transfer function is estimated through simulations. Data selection is performed automatically through a series of goodness-of-fit statistics, including χ 2 and multiscale correlation tests. Applying this pipeline to the first-season COMAP data, we produce a data set with very low levels of correlated noise. We find that one of our two scanning strategies (the Lissajous type) is sensitive to residual instrumental systematics. As a result, we no longer use this type of scan and exclude data taken this way from our Season 1 power spectrum estimates. We perform a careful analysis of our data processing and observing efficiencies and take account of planned improvements to estimate our future performance. Power spectrum results derived from the first-season COMAP maps are presented and discussed in companion papers.

KW - Cosmological evolution

KW - CO line emission

KW - High-redshift galaxies

KW - Molecular gas

KW - Radio astronomy

KW - 336

KW - 262

KW - 734

KW - 1073

KW - 1338

KW - Astrophysics - Instrumentation and Methods for Astrophysics

KW - Astrophysics - Cosmology and Nongalactic Astrophysics

KW - Astrophysics - Astrophysics of Galaxies

U2 - 10.3847/1538-4357/ac63ca

DO - 10.3847/1538-4357/ac63ca

M3 - Article

SN - 0004-637X

VL - 933

JO - The Astrophysical Journal

JF - The Astrophysical Journal

ER -

COMAP Early Science. III. CO Data Processing

Abstract

Keywords

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