The Herschel-SPIRE instrument and its in-flight performance

M. J. Griffin; A. Abergel; A. Abreu; P. A. R. Ade; P. Andr\'e; J.-L.; Augueres; T. Babbedge; Y. Bae; T. Baillie; J.-P. Baluteau; M. J. Barlow; G.; Bendo; D. Benielli; J. J. Bock; P. Bonhomme; D. Brisbin; C. Brockley-Blatt,; M. Caldwell; C. Cara; N. Castro-Rodriguez; R. Cerulli; P. Chanial; S. Chen,; E. Clark; D. L. Clements; L. Clerc; J. Coker; D. Communal; L. Conversi; P.; Cox; D. Crumb; C. Cunningham; F. Daly; G. R. Davis; P. De Antoni; J.; Delderfield; N. Devin; A. Di Giorgio; I. Didschuns; K. Dohlen; M. Donati; A.; Dowell; C. D. Dowell; L. Duband; L. Dumaye; R. J. Emery; M. Ferlet; D.; Ferrand; J. Fontignie; M. Fox; A. Franceschini; M. Frerking; T. Fulton; J.; Garcia; R. Gastaud; W. K. Gear; J. Glenn; A. Goizel; D. K. Griffin; T.; Grundy; S. Guest; L. Guillemet; P. C. Hargrave; M. Harwit; P. Hastings; E.; Hatziminaoglou; M. Herman; B. Hinde; V. Hristov; M. Huang; P. Imhof; K. J.; Isaak; U. Israelsson; R. J. Ivison; D. Jennings; B. Kiernan; K. J. King; A.; E. Lange; W. Latter; G. Laurent; P. Laurent; S. J. Leeks; E. Lellouch; L.; Levenson; B. Li; J. Li; J. Lilienthal; T. Lim; J. Liu; N. Lu; S. Madden; G.; Mainetti; P. Marliani; D. McKay; K. Mercier; S. Molinari; H. Morris; H.; Moseley; J. Mulder; M. Mur; D. A. Naylor; H. Nguyen; B. O'Halloran; S.; Oliver; G. Olofsson; H.-G. Olofsson; R. Orfei; M. J. Page; I. Pain; P.; Panuzzo; A. Papageorgiou; G. Parks; P. Parr-Burman; A. Pearce; C. Pearson; I.; P\'erez-Fournon; F. Pinsard; G. Pisano; J. Podosek; M. Pohlen; E. T.; Polehampton; D. Pouliquen; D. Rigopoulou; D. Rizzo; I. G. Roseboom; H.; Roussel; M. Rowan-Robinson; B. Rownd; P. Saraceno; M. Sauvage; R. Savage; G.; Savini; E. Sawyer; C. Scharmberg; D. Schmitt; N. Schneider; B. Schulz; A.; Schwartz; R. Shafer; D. L. Shupe; B. Sibthorpe; S. Sidher; A. Smith; A. J.; Smith; D. Smith; L. Spencer; B. Stobie; R. Sudiwala; K. Sukhatme; C. Surace,; J. A. Stevens; B. M. Swinyard; M. Trichas; T. Tourette; H. Triou; S. Tseng,; C. Tucker; A. Turner; M. Vaccari; I. Valtchanov; L. Vigroux; E. Virique; G.; Voellmer; H. Walker; R. Ward; T. Waskett; M. Weilert; R. Wesson; G. J. White,; N. Whitehouse; C. D. Wilson; B. Winter; A. L. Woodcraft; G. S. Wright; C. K.; Xu; A. Zavagno; M. Zemcov; L. Zhang; and E. Zonca

arXiv:1005.5123·astro-ph.IM·May 19, 2015

The Herschel-SPIRE instrument and its in-flight performance

M. J. Griffin, A. Abergel, A. Abreu, P. A. R. Ade, P. Andr\'e, J.-L., Augueres, T. Babbedge, Y. Bae, T. Baillie, J.-P. Baluteau, M. J. Barlow, G., Bendo, D. Benielli, J. J. Bock, P. Bonhomme, D. Brisbin, C. Brockley-Blatt,, M. Caldwell, C. Cara, N. Castro-Rodriguez, R. Cerulli

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TL;DR

The Herschel-SPIRE instrument, a submillimetre camera and spectrometer, demonstrated in-flight performance that meets or exceeds pre-launch predictions, enabling advanced astronomical observations in the far-infrared and submillimetre range.

Contribution

This paper provides a comprehensive overview of the SPIRE instrument's design, capabilities, and in-flight performance, highlighting its successful operation and improved sensitivity.

Findings

01

Photometer sensitivity matches or exceeds predictions

02

Spectrometer sensitivity is 1.5-2 times better than expected

03

Instrument performance enables high-quality submillimetre observations

Abstract

The Spectral and Photometric Imaging Receiver (SPIRE), is the Herschel Space Observatory`s submillimetre camera and spectrometer. It contains a three-band imaging photometer operating at 250, 350 and 500 microns, and an imaging Fourier Transform Spectrometer (FTS) which covers simultaneously its whole operating range of 194-671 microns (447-1550 GHz). The SPIRE detectors are arrays of feedhorn-coupled bolometers cooled to 0.3 K. The photometer has a field of view of 4' x 8', observed simultaneously in the three spectral bands. Its main operating mode is scan-mapping, whereby the field of view is scanned across the sky to achieve full spatial sampling and to cover large areas if desired. The spectrometer has an approximately circular field of view with a diameter of 2.6'. The spectral resolution can be adjusted between 1.2 and 25 GHz by changing the stroke length of the FTS scan mirror.…

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