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Sensitivity Modeling for LiteBIRD

Author: Ade PAR
Adler A
Allys E
Alonso D
Arnold K
Auguste D
Aumont J
Aurlien R
Austermann J
Azzoni S
Baccigalupi C
Banday AJ
Banerji R
Barreiro RB
Bartolo N
Basak S
Battistelli E
Bautista L
Beall J
Beck D
Beckman S
Benabed K
Bermejo-Ballesteros J
Bersanelli M
Bonis J
Borrill J
Bouchet F
Boulanger F
Bounissou S
Brilenkov M
Brown ML
Bucher M
Calabrese E
Calvo M
Campeti P
Carones A
Casas FJ
Catalano A
Challinor A
Chan V
Cheung K
Chinone Y
Cliche J
Columbro F
Coulton W
Cubas J
Cukierman A
Curtis D
D'Alessandro G
Dachlythra K
de Bernardis P
de Haan T
de la Hoz E
De Petris M
Della Torre S
Dickinson C
Diego-Palazuelos P
Dobbs M
Dotani T
Douillet D
Duband L
Ducout A
Duff S
Duval JM
Ebisawa K
Elleflot T
Eriksen HK
Errard J
Essinger-Hileman T
Finelli F
Flauger R
Franceschet C
Fuskeland U
Galli S
Galloway M
Ganga K
Gao JR
Genova-Santos RT
Gerbino M
Gervasi M
Ghigna T
Giardiello S
Gjerlow E
Gradziel ML
Grain J
Grandsire L
Grupp F
Gruppuso A
Gudmundsson JE
Halverson NW
Hamilton J
Hargrave P
Hasebe T
Hasegawa M
Hattori M
Hazumi M
Henrot-Versille S
Hergt LT
Herman D
Herranz D
Hill CA
Hilton G
Hivon E
Hlozek RA
Hoang TD
Hornsby AL
Hoshino Y
Hubmayr J
Ichiki K
Iida T
Imada H
Ishimura K
Ishino H
Jaehnig G
Jones M
Kaga T
Kashima S
Katayama N
Kato A
Kawasaki T
Keskitalo R
Kisner T
Kobayashi Y
Kogiso N
Kogut A
Kohri K
Komatsu E
Komatsu K
Konishi K
Krachmalnicoff N
Kreykenbohm I
Kuo CL
Kushino A
Lamagna L
Lanen JV
Laquaniello G
Lattanzi M
Lee AT
Leloup C
Levrier F
Linder E
Louis T
Luzzi G
Macias-Perez J
Maciaszek T
Maffei B
Maino D
Maki M
Mandelli S
Maris M
Martinez-Gonzalez E
Masi S
Massa M
Matarrese S
Matsuda FT
Matsumura T
Mele L
Mennella A
Migliaccio M
Minami Y
Mitsuda K
Moggi A
Monfardini A
Montgomery J
Montier L
Morgante G
Mot B
Murata Y
Murphy JA
Nagai M
Nagano Y
Nagasaki T
Nagata R
Nakamura S
Nakano R
Namikawa T
Nati F
Natoli P
Nerval S
Nishibori T
Nishino H
Noviello F
O'Sullivan C
Odagiri K
Ogawa H
Oguri S
Ohsaki H
Ohta IS
Okada N
Okada N
Pagano L
Paiella A
Paoletti D
Passerini A
Patanchon G
Pelgrim V
Peloton J
Piacentini F
Piat M
Pisano G
Polenta G
Poletti D
Prouve T
Puglisi G
Rambaud D
Raum C
Realini S
Reinecke M
Remazeilles M
Ritacco A
Roudil G
Rubino-Martin J
Russell M
Sakurai H
Sakurai Y
Sandri M
Sasaki M
Savini G
Scott D
Seibert J
Sekimoto Y
Sherwin B
Shinozaki K
Shiraishi M
Shirron P
Signorelli G
Smecher G
Spinella F
Stever S
Stompor R
Sugiyama S
Sullivan R
Suzuki A
Suzuki J
Svalheim TL
Switzer E
Takaku R
Takakura H
Takakura S
Takase Y
Takeda Y
Tartari A
Tavagnacco D
Taylor A
Taylor E
Terao Y
Thermeau J
Thommesen H
Thompson KL
Thorne B
Toda T
Tomasi M
Tominaga M
Trappe N
Tristram M
Tsuji M
Tsujimoto M
Tucker C
Ullom J
Vacher L
Vermeulen G
Vielva P
Villa F
Vissers M
Vittorio N
Wandelt B
Wang W
Watanuki K
Wehus IK
Weller J
Westbrook B
Wilms J
Winter B
Wollack EJ
Yamasaki NY
Yoshida T
Yumoto J
Zacchei A
Zannoni M
Zonca A
Publication venue: SPRINGER/PLENUM PUBLISHERS
Publication date: 01/01/2022
Field of study

LiteBIRD is a future satellite mission designed to observe the polarization of the cosmic microwave background radiation in order to probe the inflationary universe. LiteBIRD is set to observe the sky using three telescopes with transition-edge sensor bolometers. In this work we estimated the LiteBIRD instrumental sensitivity using its current design. We estimated the detector noise due to the optical loadings using physical optics and ray-tracing simulations. The noise terms associated with thermal carrier and readout noise were modeled in the detector noise calculation. We calculated the observational sensitivities over fifteen bands designed for the LiteBIRD telescopes using assumed observation time efficiency

Archivio istituzionale della ricerca - Università di Padova

Optical Characterization of OMT-Coupled TES Bolometers for LiteBIRD

Author: Ade P.A.R.
Adler A.
Allys E.
Alonso D.
Arnold K.
Auguste D.
Aumont J.
Aurlien R.
Austermann J.E.
Azzoni S.
Baccigalupi C.
Banday A.J.
Banerji R.
Barreiro R.B.
Bartolo N.
Basak S.
Battistelli E.
Bautista L.
Beall J.A.
Beck D.
Beckman S.
Benabed K.
Bermejo-Ballesteros J.
Bersanelli M.
Bonis J.
Borrill J.
Bouchet F.
Boulanger F.
Bounissou S.
Brilenkov M.
Brown M.L.
Bucher M.
Calabrese E.
Calvo M.
Campeti P.
Carones A.
Casas F.J.
Catalano A.
Challinor A.
Chan V.
Cheung K.
Chinone Y.
Chiocchetta C.
Cisneros G. Pascual
Clark S.E.
Clermont L.
Clesse S.
Cliche J.
Columbro F.
Connors J.A.
Coppolecchia A.
Coulton W.
Cubas J.
Cukierman A.
Curtis D.
Cuttaia F.
d'Alessandro G.
Dachlythra K.
de Bernardis P.
de Haan T.
de la Hoz E.
de Petris M.
Della Torre S.
Dickinson C.
Diego-Palazuelos P.
Dobbs M.
Dotani T.
Douillet D.
Doumayrou E.
Duband L.
Ducout A.
Duf S.M.
Duval J.M.
Ebisawa K.
Ellefot T.
Eriksen H.K.
Errard J.
Essinger-Hileman T.
Farias N. Neto Godry
Farrens S.
Finelli F.
Flauger R.
Fleury-Frenette K.
Franceschet C.
Fuskeland U.
Galli L.
Galli S.
Galloway M.
Ganga K.
Gao J.R.
Garca J.J. Daz
Genova-Santos R.T.
Georges M.
Gerbino M.
Gervasi M.
Ghigna T.
Giardiello S.
Gjerlw E.
Gonzles R. Gonzlez
Gradziel M.L.
Grain J.
Grandsire L.
Grupp F.
Gruppuso A.
Gudmundsson J.E.
Halverson N.W.
Hamilton J.
Hargrave P.
Hasebe T.
Hasegawa M.
Hattori M.
Hazumi M.
Henrot-Versill S.
Hensley B.
Herman D.
Herranz D.
Hilton G.C.
Hivon E.
Hlozek R.A.
Hoang D.
Hornsby A.L.
Hoshino Y.
Hubmayr J.
Ichiki K.
Iida T.
Ikemoto T.
Imada H.
Ishimura K.
Ishino H.
Jaehnig G.
Jones M.
Kaga T.
Kashima S.
Katayama N.
Kato A.
Kawasaki T.
Keskitalo R.
Kintziger C.
Kisner T.
Kobayashi Y.
Kogiso N.
Kogut A.
Kohri K.
Komatsu E.
Komatsu K.
Konishi K.
Krachmalnicof N.
Kreykenbohm I.
Kuo C.L.
Kushino A.
Lamagna L.
Lanen J.V.
Laquaniello G.
Lattanzi M.
Lee A.T.
Leloup C.
Levrier F.
Linder E.
Link M.J.
Lonappan A.I.
Louis T.
Luzzi G.
Macias-Perez J.
Maciaszek T.
Mafei B.
Maino D.
Maki M.
Mandelli S.
Maris M.
Marquet B.
Martire F.A.
Martnez-Gonzlez E.
Masi S.
Massa M.
Masuzawa M.
Matarrese S.
Matsuda F.T.
Matsumura T.
Mele L.
Mennella A.
Migliaccio M.
Minami Y.
Mitsuda K.
Moggi A.
Monelli M.
Monfardini A.
Montgomery J.
Montier L.
Morgante G.
Mot B.
Murata Y.
Murphy J.A.
Nagai M.
Nagano Y.
Nagasaki T.
Nagata R.
Nakamura S.
Nakano R.
Namikawa T.
Nati F.
Natoli P.
Nerval S.
Nishibori T.
Nishino H.
Noviello F.
O'Neil G.C.
O'Sullivan C.
Ochi H.
Odagiri K.
Ogawa H.
Ogawa H.
Oguri S.
Ohsaki H.
Ohta I.S.
Okada N.
Pagano L.
Paiella A.
Paoletti D.
Passerini A.
Patanchon G.
Pelgrim V.
Peloton J.
Pettorino V.
Piacentini F.
Piat M.
Piccirilli G.
Pinsard F.
Pisano G.
Plesseria J.
Polenta G.
Poletti D.
Prouv T.
Puglisi G.
Rambaud D.
Raum C.
Realini S.
Reinecke M.
Reintsema C.D.
Remazeilles M.
Ritacco A.
Rosier P.
Roudil G.
Rubino-Martin J.
Russell M.
Sakurai H.
Sakurai Y.
Sandri M.
Sasaki M.
Savini G.
Scott D.
Seibert J.
Sekimoto Y.
Sherwin B.
Shinozaki K.
Shiraishi M.
Shirron P.
Shitvov A.
Signorelli G.
Smecher G.
Spinella F.
Starck J.
Stever S.
Stompor R.
Sudiwala R.
Sugiyama S.
Sullivan R.
Suzuki A.
Suzuki J.
Suzuki T.
Svalheim T.L.
Switzer E.
Takaku R.
Takakura H.
Takakura S.
Takase Y.
Takeda Y.
Tartari A.
Tavagnacco D.
Taylor A.
Taylor E.
Terao Y.
Terenzi L.
Thermeau J.
Thommesen H.
Thompson K.L.
Thorne B.
Toda T.
Tomasi M.
Tominaga M.
Trappe N.
Tristram M.
Tsuji M.
Tsujimoto M.
Tucker C.
Ueki R.
Ullom J.N.
Umemori K.
Vacher L.
van Lanen J.
Vermeulen G.
Vielva P.
Villa F.
Vissers M.R.
Vittorio N.
Wandelt B.
Wang W.
Watanuki K.
Wehus I.K.
Weller J.
Westbrook B.
Weymann-Despres G.
Wilms J.
Winter B.
Wollack E.J.
Yamasaki N.Y.
Yoshida T.
Yumoto J.
Zacchei A.
Zannoni M.
Zonca A.
Publication venue: 'Springer Science and Business Media LLC'
Publication date: 01/01/2022
Field of study

International audienceFeedhorn- and orthomode transducer- (OMT) coupled transition edge sensor (TES) bolometers have been designed and micro-fabricated to meet the optical specifications of the LiteBIRD high frequency telescope (HFT) focal plane. We discuss the design and optical characterization of two LiteBIRD HFT detector types: dual-polarization, dual-frequency-band pixels with 195/280 GHz and 235/337 GHz band centers. Results show well-matched passbands between orthogonal polarization channels and frequency centers within 3% of the design values. The optical efficiency of each frequency channel is conservatively reported to be within the range 0.64-0.72, determined from the response to a cryogenic, temperature-controlled thermal source. These values are in good agreement with expectations and either exceed or are within 10% of the values used in the LiteBIRD sensitivity forecast. Lastly, we report a measurement of loss in Nb/SiN x/Nb microstrip at 100 mK and over the frequency range 200-350 GHz, which is comparable to values previously reported in the literature

HAL-IN2P3

Hal - Université Grenoble Alpes

HAL-INSU

Sissa Digital Library

Open Repository and Bibliography - Liège

Archivio istituzionale della ricerca - Università di Padova

Sensitivity Modeling for LiteBIRD

Author: Ade P. A. R.
Adler A.
Allys E.
Alonso D.
Arnold K.
Auguste D.
Aumont J.
Aurlien R.
Austermann J.
Azzoni S.
Baccigalupi C.
Banday A. J.
Banerji R.
Barreiro R. B.
Bartolo N.
Basak S.
Battistelli E.
Bautista L.
Beall J.
Beck D.
Beckman S.
Benabed K.
Bermejo-Ballesteros J.
Bersanelli M.
Bonis J.
Borrill J.
Bouchet F.
Boulanger F.
Bounissou S.
Brilenkov M.
Brown M. L.
Bucher M.
Calabrese E.
Calvo M.
Campeti P.
Carones A.
Casas F. J.
Catalano A.
Challinor A.
Chan V.
Cheung K.
Chinone Y.
Cliche J.
Columbro F.
Coulton W.
Cubas J.
Cukierman A.
Curtis D.
d'Alessandro G.
Dachlythra K.
de Bernardis P.
de Haan T.
de la Hoz E.
de Petris M.
Dickinson C.
Diego-Palazuelos P.
Dobbs M.
Dotani T.
Douillet D.
Duband L.
Ducout A.
Duff S.
Duval J. M.
Ebisawa K.
Elleflot T.
Eriksen H. K.
Errard J.
Essinger-Hileman T.
Finelli F.
Flauger R.
Franceschet C.
Fuskeland U.
Galli S.
Galloway M.
Ganga K.
Gao J. R.
Genova-Santos R. T.
Gerbino M.
Gervasi M.
Ghigna T.
Giardiello S.
Gjerløw E.
Gradziel M. L.
Grain J.
Grandsire L.
Grupp F.
Gruppuso A.
Gudmundsson J. E.
Halverson N. W.
Hamilton J.
Hargrave P.
Hasebe T.
Hasegawa M.
Hattori M.
Hazumi M.
Henrot-Versillé S.
Hergt L. T.
Herman D.
Herranz D.
Hill C. A.
Hilton G.
Hivon E.
Hlozek R. A.
Hoang T. D.
Hornsby A. L.
Hoshino Y.
Hubmayr J.
Ichiki K.
Iida T.
Imada H.
Ishimura K.
Ishino H.
Jaehnig G.
Jones M.
Kaga T.
Kashima S.
Katayama N.
Kato A.
Kawasaki T.
Keskitalo R.
Kisner T.
Kobayashi Y.
Kogiso N.
Kogut A.
Kohri K.
Komatsu E.
Komatsu K.
Konishi K.
Krachmalnicoff N.
Kreykenbohm I.
Kuo C. L.
Kushino A.
Lamagna L.
Lanen J. V.
Laquaniello G.
Lattanzi M.
Lee A. T.
Leloup C.
Levrier F.
Linder E.
Louis T.
Luzzi G.
Macias-Perez J.
Maciaszek T.
Maffei B.
Maino D.
Maki M.
Mandelli S.
Maris M.
Martínez-González E.
Masi S.
Massa M.
Matarrese S.
Matsuda F. T.
Matsumura T.
Mele L.
Mennella A.
Migliaccio M.
Minami Y.
Mitsuda K.
Moggi A.
Monfardini A.
Montgomery J.
Montier L.
Morgante G.
Mot B.
Murata Y.
Murphy J. A.
Nagai M.
Nagano Y.
Nagasaki T.
Nagata R.
Nakamura S.
Nakano R.
Namikawa T.
Nati F.
Natoli P.
Nerval S.
Nishibori T.
Nishino H.
Noviello F.
O'Sullivan C.
Odagiri K.
Ogawa H.
Ogawa H.
Oguri S.
Ohsaki H.
Ohta I. S.
Okada N.
Okada N.
Pagano L.
Paiella A.
Paoletti D.
Passerini A.
Patanchon G.
Pelgrim V.
Peloton J.
Piacentini F.
Piat M.
Pisano G.
Polenta G.
Poletti D.
Prouvé T.
Puglisi G.
Rambaud D.
Raum C.
Realini S.
Reinecke M.
Remazeilles M.
Ritacco A.
Roudil G.
Rubino-Martin J.
Russell M.
Sakurai H.
Sakurai Y.
Sandri M.
Sasaki M.
Savini G.
Scott D.
Seibert J.
Sekimoto Y.
Sherwin B.
Shinozaki K.
Shiraishi M.
Shirron P.
Signorelli G.
Smecher G.
Spinella F.
Stever S.
Stompor R.
Sugiyama S.
Sullivan R.
Suzuki A.
Suzuki J.
Svalheim T. L.
Switzer E.
Takaku R.
Takakura H.
Takakura S.
Takase Y.
Takeda Y.
Tartari A.
Tavagnacco D.
Taylor A.
Taylor E.
Terao Y.
Thermeau J.
Thommesen H.
Thompson K. L.
Thorne B.
Toda T.
Tomasi M.
Tominaga M.
Torre S. Della
Trappe N.
Tristram M.
Tsuji M.
Tsujimoto M.
Tucker C.
Ullom J.
Vacher L.
Vermeulen G.
Vielva P.
Villa F.
Vissers M.
Vittorio N.
Wandelt B.
Wang W.
Watanuki K.
Wehus I. K.
Weller J.
Westbrook B.
Wilms J.
Winter B.
Wollack E. J.
Yamasaki N. Y.
Yoshida T.
Yumoto J.
Zacchei A.
Zannoni M.
Zonca A.
Publication venue: 'Springer Science and Business Media LLC'
Publication date: 01/01/2022
Field of study

International audienceLiteBIRD is a future satellite mission designed to observe the polarization of the cosmic microwave background radiation in order to probe the inflationary universe. LiteBIRD is set to observe the sky using three telescopes with transition-edge sensor bolometers. In this work we estimated the LiteBIRD instrumental sensitivity using its current design. We estimated the detector noise due to the optical loadings using physical optics and ray-tracing simulations. The noise terms associated with thermal carrier and readout noise were modeled in the detector noise calculation. We calculated the observational sensitivities over fifteen bands designed for the LiteBIRD telescopes using assumed observation time efficiency

Hal - Université Grenoble Alpes