Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data

Geoff G. Murphy; Philip Bull; Mario G. Santos; Zara Abdurashidova; Tyrone Adams; James E. Aguirre; Paul Alexander; Zaki S. Ali; Rushelle Baartman; Yanga Balfour; Adam P. Beardsley; Gianni Bernardi; Tashalee S. Billings; Judd D. Bowman; Richard F. Bradley; Jacob Burba; Christopher Cain; Steven Carey; Chris L. Carilli; Carina Cheng; David R. Deboer; Eloy de Lera Acedo; Matt Dexter; Joshua S. Dillon; Nico Eksteen; John Ely; Aaron Ewall-Wice; Nicolas Fagnoni; Randall Fritz; Steven R. Furlanetto; Kingsley Gale-Sides; Brian Glendenning; Deepthi Gorthi; Bradley Greig; Jasper Grobbelaar; Ziyaad Halday; Bryna J. Hazelton; Jacqueline N. Hewitt; Jack Hickish; Daniel C. Jacobs; Austin Julius; MacCalvin Kariseb; Nicholas S. Kern; Joshua Kerrigan; Piyanat Kittiwisit; Saul A. Kohn; Matthew Kolopanis; Adam Lanman; Paul La Plante; Adrian Liu; Anita Loots; David Harold Edward Macmahon; Lourence Malan; Cresshim Malgas; Keith Malgas; Bradley Marero; Zachary E. Martinot; Andrei Mesinger; Mathakane Molewa; Miguel F. Morales; Tshegofalang Mosiane; Steven G. Murray; Abraham R. Neben; Bojan Nikolic; Hans Nuwegeld; Aaron R. Parsons; Nipanjana Patra; Samantha Pieterse; Nima Razavi-Ghods; James Robnett; Kathryn Rosie; Peter Sims; Jackson Sipple; Craig Smith; Hilton Swarts; Nithyanandan Thyagarajan; Pieter Van Wyngaarden; Peter K.G. Williams; Haoxuan Zheng

doi:10.1093/mnras/stae2242

Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data

Geoff G. Murphy, Philip Bull, Mario G. Santos, Zara Abdurashidova, Tyrone Adams, James E. Aguirre, Paul Alexander, Zaki S. Ali, Rushelle Baartman, Yanga Balfour, Adam P. Beardsley, Gianni Bernardi, Tashalee S. Billings, Judd D. Bowman, Richard F. Bradley, Jacob Burba, Christopher Cain, Steven Carey, Chris L. Carilli, Carina ChengDavid R. Deboer, Eloy de Lera Acedo, Matt Dexter, Joshua S. Dillon, Nico Eksteen, John Ely, Aaron Ewall-Wice, Nicolas Fagnoni, Randall Fritz, Steven R. Furlanetto, Kingsley Gale-Sides, Brian Glendenning, Deepthi Gorthi, Bradley Greig, Jasper Grobbelaar, Ziyaad Halday, Bryna J. Hazelton, Jacqueline N. Hewitt, Jack Hickish, Daniel C. Jacobs, Austin Julius, MacCalvin Kariseb, Nicholas S. Kern, Joshua Kerrigan, Piyanat Kittiwisit, Saul A. Kohn, Matthew Kolopanis, Adam Lanman, Paul La Plante, Adrian Liu, Anita Loots, David Harold Edward Macmahon, Lourence Malan, Cresshim Malgas, Keith Malgas, Bradley Marero, Zachary E. Martinot, Andrei Mesinger, Mathakane Molewa, Miguel F. Morales, Tshegofalang Mosiane, Steven G. Murray, Abraham R. Neben, Bojan Nikolic, Hans Nuwegeld, Aaron R. Parsons, Nipanjana Patra, Samantha Pieterse, Nima Razavi-Ghods, James Robnett, Kathryn Rosie, Peter Sims, Jackson Sipple, Craig Smith, Hilton Swarts, Nithyanandan Thyagarajan, Pieter Van Wyngaarden, Peter K.G. Williams, Haoxuan Zheng

Earth and Space Exploration, School of (SESE)

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

1 Scopus citations

Abstract

Observations with radio arrays that target the 21-cm signal originating from the early Universe suffer from a variety of systematic effects. An important class of these is reflections and spurious couplings between antennas. We apply a Hamiltonian Monte Carlo sampler to the modelling and mitigation of these systematics in simulated Hydrogen Epoch of Reionization Array (HERA) data. This method allows us to form statistical uncertainty estimates for both our models and the recovered visibilities, which is an important ingredient in establishing robust upper limits on the epoch of reionization (EoR) power spectrum. In cases where the noise is large compared to the EoR signal, this approach can constrain the systematics well enough to mitigate them down to the noise level for both systematics studied. Incoherently averaging the recovered power spectra can further reduce the noise and improve recovery. Where the noise level is lower than the EoR, our modelling can mitigate the majority of the reflections and coupling with there being only a minor level of residual systematics. Our approach performs similarly to existing filtering/fitting techniques used in the HERA pipeline, but with the added benefit of rigorously propagating uncertainties. In all cases it does not significantly attenuate the underlying signal.

Original language	English (US)
Pages (from-to)	2653-2673
Number of pages	21
Journal	Monthly Notices of the Royal Astronomical Society
Volume	534
Issue number	3
DOIs	https://doi.org/10.1093/mnras/stae2242
State	Published - Nov 1 2024

Keywords

dark ages, reionization, first stars
methods: data analysis
methods: statisticals
techniques: interferometric

ASJC Scopus subject areas

Astronomy and Astrophysics
Space and Planetary Science

Access to Document

10.1093/mnras/stae2242

Cite this

Murphy, G. G., Bull, P., Santos, M. G., Abdurashidova, Z., Adams, T., Aguirre, J. E., Alexander, P., Ali, Z. S., Baartman, R., Balfour, Y., Beardsley, A. P., Bernardi, G., Billings, T. S., Bowman, J. D., Bradley, R. F., Burba, J., Cain, C., Carey, S., Carilli, C. L., ... Zheng, H. (2024). Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data. Monthly Notices of the Royal Astronomical Society, 534(3), 2653-2673. https://doi.org/10.1093/mnras/stae2242

Murphy, GG, Bull, P, Santos, MG, Abdurashidova, Z, Adams, T, Aguirre, JE, Alexander, P, Ali, ZS, Baartman, R, Balfour, Y, Beardsley, AP, Bernardi, G, Billings, TS, Bowman, JD, Bradley, RF, Burba, J, Cain, C, Carey, S, Carilli, CL, Cheng, C, Deboer, DR, Acedo, EDL, Dexter, M, Dillon, JS, Eksteen, N, Ely, J, Ewall-Wice, A, Fagnoni, N, Fritz, R, Furlanetto, SR, Gale-Sides, K, Glendenning, B, Gorthi, D, Greig, B, Grobbelaar, J, Halday, Z, Hazelton, BJ, Hewitt, JN, Hickish, J, Jacobs, DC, Julius, A, Kariseb, M, Kern, NS, Kerrigan, J, Kittiwisit, P, Kohn, SA, Kolopanis, M, Lanman, A, Plante, PL, Liu, A, Loots, A, Macmahon, DHE, Malan, L, Malgas, C, Malgas, K, Marero, B, Martinot, ZE, Mesinger, A, Molewa, M, Morales, MF, Mosiane, T, Murray, SG, Neben, AR, Nikolic, B, Nuwegeld, H, Parsons, AR, Patra, N, Pieterse, S, Razavi-Ghods, N, Robnett, J, Rosie, K, Sims, P, Sipple, J, Smith, C, Swarts, H, Thyagarajan, N, Van Wyngaarden, P, Williams, PKG & Zheng, H 2024, 'Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data', Monthly Notices of the Royal Astronomical Society, vol. 534, no. 3, pp. 2653-2673. https://doi.org/10.1093/mnras/stae2242

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title = "Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data",

abstract = "Observations with radio arrays that target the 21-cm signal originating from the early Universe suffer from a variety of systematic effects. An important class of these is reflections and spurious couplings between antennas. We apply a Hamiltonian Monte Carlo sampler to the modelling and mitigation of these systematics in simulated Hydrogen Epoch of Reionization Array (HERA) data. This method allows us to form statistical uncertainty estimates for both our models and the recovered visibilities, which is an important ingredient in establishing robust upper limits on the epoch of reionization (EoR) power spectrum. In cases where the noise is large compared to the EoR signal, this approach can constrain the systematics well enough to mitigate them down to the noise level for both systematics studied. Incoherently averaging the recovered power spectra can further reduce the noise and improve recovery. Where the noise level is lower than the EoR, our modelling can mitigate the majority of the reflections and coupling with there being only a minor level of residual systematics. Our approach performs similarly to existing filtering/fitting techniques used in the HERA pipeline, but with the added benefit of rigorously propagating uncertainties. In all cases it does not significantly attenuate the underlying signal.",

keywords = "dark ages, reionization, first stars, methods: data analysis, methods: statisticals, techniques: interferometric",

author = "Murphy, {Geoff G.} and Philip Bull and Santos, {Mario G.} and Zara Abdurashidova and Tyrone Adams and Aguirre, {James E.} and Paul Alexander and Ali, {Zaki S.} and Rushelle Baartman and Yanga Balfour and Beardsley, {Adam P.} and Gianni Bernardi and Billings, {Tashalee S.} and Bowman, {Judd D.} and Bradley, {Richard F.} and Jacob Burba and Christopher Cain and Steven Carey and Carilli, {Chris L.} and Carina Cheng and Deboer, {David R.} and Acedo, {Eloy de Lera} and Matt Dexter and Dillon, {Joshua S.} and Nico Eksteen and John Ely and Aaron Ewall-Wice and Nicolas Fagnoni and Randall Fritz and Furlanetto, {Steven R.} and Kingsley Gale-Sides and Brian Glendenning and Deepthi Gorthi and Bradley Greig and Jasper Grobbelaar and Ziyaad Halday and Hazelton, {Bryna J.} and Hewitt, {Jacqueline N.} and Jack Hickish and Jacobs, {Daniel C.} and Austin Julius and MacCalvin Kariseb and Kern, {Nicholas S.} and Joshua Kerrigan and Piyanat Kittiwisit and Kohn, {Saul A.} and Matthew Kolopanis and Adam Lanman and Plante, {Paul La} and Adrian Liu and Anita Loots and Macmahon, {David Harold Edward} and Lourence Malan and Cresshim Malgas and Keith Malgas and Bradley Marero and Martinot, {Zachary E.} and Andrei Mesinger and Mathakane Molewa and Morales, {Miguel F.} and Tshegofalang Mosiane and Murray, {Steven G.} and Neben, {Abraham R.} and Bojan Nikolic and Hans Nuwegeld and Parsons, {Aaron R.} and Nipanjana Patra and Samantha Pieterse and Nima Razavi-Ghods and James Robnett and Kathryn Rosie and Peter Sims and Jackson Sipple and Craig Smith and Hilton Swarts and Nithyanandan Thyagarajan and {Van Wyngaarden}, Pieter and Williams, {Peter K.G.} and Haoxuan Zheng",

note = "Publisher Copyright: {\textcopyright} 2024 The Author(s).",

year = "2024",

month = nov,

day = "1",

doi = "10.1093/mnras/stae2242",

language = "English (US)",

volume = "534",

pages = "2653--2673",

journal = "Monthly Notices of the Royal Astronomical Society",

issn = "0035-8711",

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TY - JOUR

T1 - Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data

AU - Murphy, Geoff G.

AU - Bull, Philip

AU - Santos, Mario G.

AU - Abdurashidova, Zara

AU - Adams, Tyrone

AU - Aguirre, James E.

AU - Alexander, Paul

AU - Ali, Zaki S.

AU - Baartman, Rushelle

AU - Balfour, Yanga

AU - Beardsley, Adam P.

AU - Bernardi, Gianni

AU - Billings, Tashalee S.

AU - Bowman, Judd D.

AU - Bradley, Richard F.

AU - Burba, Jacob

AU - Cain, Christopher

AU - Carey, Steven

AU - Carilli, Chris L.

AU - Cheng, Carina

AU - Deboer, David R.

AU - Acedo, Eloy de Lera

AU - Dexter, Matt

AU - Dillon, Joshua S.

AU - Eksteen, Nico

AU - Ely, John

AU - Ewall-Wice, Aaron

AU - Fagnoni, Nicolas

AU - Fritz, Randall

AU - Furlanetto, Steven R.

AU - Gale-Sides, Kingsley

AU - Glendenning, Brian

AU - Gorthi, Deepthi

AU - Greig, Bradley

AU - Grobbelaar, Jasper

AU - Halday, Ziyaad

AU - Hazelton, Bryna J.

AU - Hewitt, Jacqueline N.

AU - Hickish, Jack

AU - Jacobs, Daniel C.

AU - Julius, Austin

AU - Kariseb, MacCalvin

AU - Kern, Nicholas S.

AU - Kerrigan, Joshua

AU - Kittiwisit, Piyanat

AU - Kohn, Saul A.

AU - Kolopanis, Matthew

AU - Lanman, Adam

AU - Plante, Paul La

AU - Liu, Adrian

AU - Loots, Anita

AU - Macmahon, David Harold Edward

AU - Malan, Lourence

AU - Malgas, Cresshim

AU - Malgas, Keith

AU - Marero, Bradley

AU - Martinot, Zachary E.

AU - Mesinger, Andrei

AU - Molewa, Mathakane

AU - Morales, Miguel F.

AU - Mosiane, Tshegofalang

AU - Murray, Steven G.

AU - Neben, Abraham R.

AU - Nikolic, Bojan

AU - Nuwegeld, Hans

AU - Parsons, Aaron R.

AU - Patra, Nipanjana

AU - Pieterse, Samantha

AU - Razavi-Ghods, Nima

AU - Robnett, James

AU - Rosie, Kathryn

AU - Sims, Peter

AU - Sipple, Jackson

AU - Smith, Craig

AU - Swarts, Hilton

AU - Thyagarajan, Nithyanandan

AU - Van Wyngaarden, Pieter

AU - Williams, Peter K.G.

AU - Zheng, Haoxuan

PY - 2024/11/1

Y1 - 2024/11/1

N2 - Observations with radio arrays that target the 21-cm signal originating from the early Universe suffer from a variety of systematic effects. An important class of these is reflections and spurious couplings between antennas. We apply a Hamiltonian Monte Carlo sampler to the modelling and mitigation of these systematics in simulated Hydrogen Epoch of Reionization Array (HERA) data. This method allows us to form statistical uncertainty estimates for both our models and the recovered visibilities, which is an important ingredient in establishing robust upper limits on the epoch of reionization (EoR) power spectrum. In cases where the noise is large compared to the EoR signal, this approach can constrain the systematics well enough to mitigate them down to the noise level for both systematics studied. Incoherently averaging the recovered power spectra can further reduce the noise and improve recovery. Where the noise level is lower than the EoR, our modelling can mitigate the majority of the reflections and coupling with there being only a minor level of residual systematics. Our approach performs similarly to existing filtering/fitting techniques used in the HERA pipeline, but with the added benefit of rigorously propagating uncertainties. In all cases it does not significantly attenuate the underlying signal.

AB - Observations with radio arrays that target the 21-cm signal originating from the early Universe suffer from a variety of systematic effects. An important class of these is reflections and spurious couplings between antennas. We apply a Hamiltonian Monte Carlo sampler to the modelling and mitigation of these systematics in simulated Hydrogen Epoch of Reionization Array (HERA) data. This method allows us to form statistical uncertainty estimates for both our models and the recovered visibilities, which is an important ingredient in establishing robust upper limits on the epoch of reionization (EoR) power spectrum. In cases where the noise is large compared to the EoR signal, this approach can constrain the systematics well enough to mitigate them down to the noise level for both systematics studied. Incoherently averaging the recovered power spectra can further reduce the noise and improve recovery. Where the noise level is lower than the EoR, our modelling can mitigate the majority of the reflections and coupling with there being only a minor level of residual systematics. Our approach performs similarly to existing filtering/fitting techniques used in the HERA pipeline, but with the added benefit of rigorously propagating uncertainties. In all cases it does not significantly attenuate the underlying signal.

KW - dark ages, reionization, first stars

KW - methods: data analysis

KW - methods: statisticals

KW - techniques: interferometric

UR - http://www.scopus.com/inward/record.url?scp=85207815323&partnerID=8YFLogxK

UR - http://www.scopus.com/inward/citedby.url?scp=85207815323&partnerID=8YFLogxK

U2 - 10.1093/mnras/stae2242

DO - 10.1093/mnras/stae2242

M3 - Article

AN - SCOPUS:85207815323

SN - 0035-8711

VL - 534

SP - 2653

EP - 2673

JO - Monthly Notices of the Royal Astronomical Society

JF - Monthly Notices of the Royal Astronomical Society

IS - 3

ER -

Bayesian estimation of cross-coupling and reflection systematics in 21cm array visibility data

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