Share Email Print

Proceedings Paper

Optical and quasi-optical analysis of system components for a far-infrared space interferometer
Author(s): C. Bracken; C. O'Sullivan; A. Donohoe; A. Murphy; G. Savini; R. Juanola-Parramon; Nicola Baccichet; A. Guisseau; P. Ade; E. Pascale; L. Spencer; I. Walker; K. Dohlen; John F. Lightfoot; W. Holland; Martyn Jones; D. D. Walker; Alison McMillan
Format Member Price Non-Member Price
PDF $17.00 $21.00

Paper Abstract

Many important astrophysical processes occur at wavelengths that fall within the far-infrared band of the EM spectrum, and over distance scales that require sub-arc second spatial resolution. It is clear that in order to achieve sub-arc second resolution at these relatively long wavelengths (compared to optical/near-IR), which are strongly absorbed by the atmosphere, a space-based far-IR interferometer will be required. We present analysis of the optical system for a proposed spatial-spectral interferometer, discussing the challenges that arise when designing such a system and the simulation techniques employed that aim to resolve these issues. Many of these specific challenges relate to combining the beams from multiple telescopes where the wavelengths involved are relatively short (compared to radio interferometry), meaning that care must be taken with mirror surface quality, where surface form errors not only present potential degradation of the single system beams, but also serve to reduce fringe visibility when multiple telescope beams are combined. Also, the long baselines required for sub-arc second resolution present challenges when considering propagation of the relatively long wavelengths of the signal beam, where beam divergence becomes significant if the beam demagnification of the telescopes is not carefully considered. Furthermore, detection of the extremely weak far-IR signals demands ultra-sensitive detectors and instruments capable of operating at maximum efficiency. Thus, as will be shown, care must be taken when designing each component of such a complex quasioptical system.

Paper Details

Date Published: 14 March 2015
PDF: 12 pages
Proc. SPIE 9362, Terahertz, RF, Millimeter, and Submillimeter-Wave Technology and Applications VIII, 93620N (14 March 2015); doi: 10.1117/12.2076385
Show Author Affiliations
C. Bracken, National Univ. of Ireland, Maynooth (Ireland)
C. O'Sullivan, National Univ. of Ireland, Maynooth (Ireland)
A. Donohoe, National Univ. of Ireland, Maynooth (Ireland)
A. Murphy, National Univ. of Ireland, Maynooth (Ireland)
G. Savini, Univ. College London (United Kingdom)
R. Juanola-Parramon, Univ. College London (United Kingdom)
Nicola Baccichet, Univ. College London (United Kingdom)
A. Guisseau, Univ. College London (United Kingdom)
P. Ade, Cardiff Univ. (United Kingdom)
E. Pascale, Cardiff Univ. (United Kingdom)
L. Spencer, Cardiff Univ. (Canada)
I. Walker, Cardiff Univ. (United Kingdom)
K. Dohlen, Lab. d'Astrophysique de Marseille (France)
John F. Lightfoot, Science and Technology Facilities Council (United Kingdom)
W. Holland, Science and Technology Facilities Council (United Kingdom)
Martyn Jones, Glyndwr Univ. (United Kingdom)
D. D. Walker, Glyndwr Univ. (United Kingdom)
Alison McMillan, Glyndwr Univ. (United Kingdom)

Published in SPIE Proceedings Vol. 9362:
Terahertz, RF, Millimeter, and Submillimeter-Wave Technology and Applications VIII
Laurence P. Sadwick; Tianxin Yang, Editor(s)

© SPIE. Terms of Use
Back to Top
Sign in to read the full article
Create a free SPIE account to get access to
premium articles and original research
Forgot your username?