Spider optimization: Probing the systematics of a large-scale B-mode experiment

C. J. Mactavish; P. A.R. Ade; E. S. Battistelli; S. Benton; R. Bihary; J. J. Bock; J. R. Bond; J. Brevik; S. Bryan; C. R. Contaldi; B. P. Crill; O. Doré; L. Fissel; S. R. Golwala; M. Halpern; G. Hilton; W. Holmes; V. V. Hristov; K. Irwin; W. C. Jones; C. L. Kuo; A. E. Lange; C. Lawrie; T. G. Martin; P. Mason; T. E. Montroy; C. B. Netterfield; D. Riley; J. E. Ruhl; M. Runyan; A. Trangsrud; C. Tucker; A. Turner; M. Viero; D. Wiebe

doi:10.1086/592732

Spider optimization: Probing the systematics of a large-scale B-mode experiment

C. J. Mactavish, P. A.R. Ade, E. S. Battistelli, S. Benton, R. Bihary, J. J. Bock, J. R. Bond, J. Brevik, S. Bryan, C. R. Contaldi, B. P. Crill, O. Doré, L. Fissel, S. R. Golwala, M. Halpern, G. Hilton, W. Holmes, V. V. Hristov, K. Irwin, W. C. JonesC. L. Kuo, A. E. Lange, C. Lawrie, T. G. Martin, P. Mason, T. E. Montroy, C. B. Netterfield, D. Riley, J. E. Ruhl, M. Runyan, A. Trangsrud, C. Tucker, A. Turner, M. Viero, D. Wiebe

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

21 Scopus citations

Abstract

Spider is a long-duration, balloon-borne polarimeter designed to measure large-scale cosmic microwave background (CMB) polarization with very high sensitivity and control of systematics. The instrument will map over half the sky with degree angular resolution in the I, Q, and U Stokes parameters in four frequency bands from 96 to 275 GHz. Spider's ultimate goal is to detect the primordial gravity-wave signal imprinted on the CMB B-mode polarization. One of the challenges in achieving this goal is the minimization of the contamination of B-modes by systematic effects. This paper explores a number of instrument systematics and observing strategies in order to optimize B-mode sensitivity. This is done by injecting realistic-amplitude, time-varying systematics into a set of simulated time streams. Tests of the impact of detector noise characteristics, pointing jitter, payload pendulations, polarization angle offsets, beam systematics, and receiver gain drifts are shown. Spider's default observing strategy is to spin continuously in azimuth, with polarization modulation achieved by either a rapidly spinning half-wave plate or a rapidly spinning gondola and a slowly stepped half-wave plate. Although the latter is more susceptible to systematics, the results shown here indicate that either mode of operation can be used by Spider.

Original language	English (US)
Pages (from-to)	655-665
Number of pages	11
Journal	Astrophysical Journal
Volume	689
Issue number	2
DOIs	https://doi.org/10.1086/592732
State	Published - Dec 20 2008
Externally published	Yes

Keywords

Cosmic microwave background
Gravitational waves methods: data analysis
Polarization

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

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10.1086/592732

Cite this

Mactavish, C. J., Ade, P. A. R., Battistelli, E. S., Benton, S., Bihary, R., Bock, J. J., Bond, J. R., Brevik, J., Bryan, S., Contaldi, C. R., Crill, B. P., Doré, O., Fissel, L., Golwala, S. R., Halpern, M., Hilton, G., Holmes, W., Hristov, V. V., Irwin, K., ... Wiebe, D. (2008). Spider optimization: Probing the systematics of a large-scale B-mode experiment. Astrophysical Journal, 689(2), 655-665. https://doi.org/10.1086/592732

Mactavish, CJ, Ade, PAR, Battistelli, ES, Benton, S, Bihary, R, Bock, JJ, Bond, JR, Brevik, J, Bryan, S, Contaldi, CR, Crill, BP, Doré, O, Fissel, L, Golwala, SR, Halpern, M, Hilton, G, Holmes, W, Hristov, VV, Irwin, K, Jones, WC, Kuo, CL, Lange, AE, Lawrie, C, Martin, TG, Mason, P, Montroy, TE, Netterfield, CB, Riley, D, Ruhl, JE, Runyan, M, Trangsrud, A, Tucker, C, Turner, A, Viero, M & Wiebe, D 2008, 'Spider optimization: Probing the systematics of a large-scale B-mode experiment', Astrophysical Journal, vol. 689, no. 2, pp. 655-665. https://doi.org/10.1086/592732

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title = "Spider optimization: Probing the systematics of a large-scale B-mode experiment",

abstract = "Spider is a long-duration, balloon-borne polarimeter designed to measure large-scale cosmic microwave background (CMB) polarization with very high sensitivity and control of systematics. The instrument will map over half the sky with degree angular resolution in the I, Q, and U Stokes parameters in four frequency bands from 96 to 275 GHz. Spider's ultimate goal is to detect the primordial gravity-wave signal imprinted on the CMB B-mode polarization. One of the challenges in achieving this goal is the minimization of the contamination of B-modes by systematic effects. This paper explores a number of instrument systematics and observing strategies in order to optimize B-mode sensitivity. This is done by injecting realistic-amplitude, time-varying systematics into a set of simulated time streams. Tests of the impact of detector noise characteristics, pointing jitter, payload pendulations, polarization angle offsets, beam systematics, and receiver gain drifts are shown. Spider's default observing strategy is to spin continuously in azimuth, with polarization modulation achieved by either a rapidly spinning half-wave plate or a rapidly spinning gondola and a slowly stepped half-wave plate. Although the latter is more susceptible to systematics, the results shown here indicate that either mode of operation can be used by Spider.",

keywords = "Cosmic microwave background, Gravitational waves methods: data analysis, Polarization",

author = "Mactavish, {C. J.} and Ade, {P. A.R.} and Battistelli, {E. S.} and S. Benton and R. Bihary and Bock, {J. J.} and Bond, {J. R.} and J. Brevik and S. Bryan and Contaldi, {C. R.} and Crill, {B. P.} and O. Dor{\'e} and L. Fissel and Golwala, {S. R.} and M. Halpern and G. Hilton and W. Holmes and Hristov, {V. V.} and K. Irwin and Jones, {W. C.} and Kuo, {C. L.} and Lange, {A. E.} and C. Lawrie and Martin, {T. G.} and P. Mason and Montroy, {T. E.} and Netterfield, {C. B.} and D. Riley and Ruhl, {J. E.} and M. Runyan and A. Trangsrud and C. Tucker and A. Turner and M. Viero and D. Wiebe",

year = "2008",

month = dec,

day = "20",

doi = "10.1086/592732",

language = "English (US)",

volume = "689",

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TY - JOUR

T1 - Spider optimization

T2 - Probing the systematics of a large-scale B-mode experiment

AU - Mactavish, C. J.

AU - Ade, P. A.R.

AU - Battistelli, E. S.

AU - Benton, S.

AU - Bihary, R.

AU - Bock, J. J.

AU - Bond, J. R.

AU - Brevik, J.

AU - Bryan, S.

AU - Contaldi, C. R.

AU - Crill, B. P.

AU - Doré, O.

AU - Fissel, L.

AU - Golwala, S. R.

AU - Halpern, M.

AU - Hilton, G.

AU - Holmes, W.

AU - Hristov, V. V.

AU - Irwin, K.

AU - Jones, W. C.

AU - Kuo, C. L.

AU - Lange, A. E.

AU - Lawrie, C.

AU - Martin, T. G.

AU - Mason, P.

AU - Montroy, T. E.

AU - Netterfield, C. B.

AU - Riley, D.

AU - Ruhl, J. E.

AU - Runyan, M.

AU - Trangsrud, A.

AU - Tucker, C.

AU - Turner, A.

AU - Viero, M.

AU - Wiebe, D.

PY - 2008/12/20

Y1 - 2008/12/20

N2 - Spider is a long-duration, balloon-borne polarimeter designed to measure large-scale cosmic microwave background (CMB) polarization with very high sensitivity and control of systematics. The instrument will map over half the sky with degree angular resolution in the I, Q, and U Stokes parameters in four frequency bands from 96 to 275 GHz. Spider's ultimate goal is to detect the primordial gravity-wave signal imprinted on the CMB B-mode polarization. One of the challenges in achieving this goal is the minimization of the contamination of B-modes by systematic effects. This paper explores a number of instrument systematics and observing strategies in order to optimize B-mode sensitivity. This is done by injecting realistic-amplitude, time-varying systematics into a set of simulated time streams. Tests of the impact of detector noise characteristics, pointing jitter, payload pendulations, polarization angle offsets, beam systematics, and receiver gain drifts are shown. Spider's default observing strategy is to spin continuously in azimuth, with polarization modulation achieved by either a rapidly spinning half-wave plate or a rapidly spinning gondola and a slowly stepped half-wave plate. Although the latter is more susceptible to systematics, the results shown here indicate that either mode of operation can be used by Spider.

AB - Spider is a long-duration, balloon-borne polarimeter designed to measure large-scale cosmic microwave background (CMB) polarization with very high sensitivity and control of systematics. The instrument will map over half the sky with degree angular resolution in the I, Q, and U Stokes parameters in four frequency bands from 96 to 275 GHz. Spider's ultimate goal is to detect the primordial gravity-wave signal imprinted on the CMB B-mode polarization. One of the challenges in achieving this goal is the minimization of the contamination of B-modes by systematic effects. This paper explores a number of instrument systematics and observing strategies in order to optimize B-mode sensitivity. This is done by injecting realistic-amplitude, time-varying systematics into a set of simulated time streams. Tests of the impact of detector noise characteristics, pointing jitter, payload pendulations, polarization angle offsets, beam systematics, and receiver gain drifts are shown. Spider's default observing strategy is to spin continuously in azimuth, with polarization modulation achieved by either a rapidly spinning half-wave plate or a rapidly spinning gondola and a slowly stepped half-wave plate. Although the latter is more susceptible to systematics, the results shown here indicate that either mode of operation can be used by Spider.

KW - Cosmic microwave background

KW - Gravitational waves methods: data analysis

KW - Polarization

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JF - Astrophysical Journal

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ER -

Spider optimization: Probing the systematics of a large-scale B-mode experiment

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