SuperSpec: design concept and circuit simulations
Abstract
SuperSpec is a pathfinder for future lithographic spectrometer cameras, which promise to energize extra-galactic astrophysics at (sub)millimeter wavelengths: delivering 200--500 km/s spectral velocity resolution over an octave bandwidth for every pixel in a telescope's field of view. We present circuit simulations that prove the concept, which enables complete millimeter-band spectrometer devices in just a few square-millimeter footprint. We evaluate both single-stage and two-stage channelizing filter designs, which separate channels into an array of broad-band detectors, such as bolometers or kinetic inductance detector (KID) devices. We discuss to what degree losses (by radiation or by absorption in the dielectric) and fabrication tolerances affect the resolution or performance of such devices, and what steps we can take to mitigate the degradation. Such design studies help us formulate critical requirements on the materials and fabrication process, and help understand what practical limits currently exist to the capabilities these devices can deliver today or over the next few years.
Keywords
Cite
@article{arxiv.1211.0934,
title = {SuperSpec: design concept and circuit simulations},
author = {Attila Kovács and Peter S. Barry and Charles M. Bradford and Goutam Chattopadhyay and Peter Day and Simon Doyle and Steve Hailey-Dunsheath and Matthew Hollister and Christopher McKenney and Henry G. LeDuc and Nuria Llombart and Daniel P. Marrone and Philip Mauskopf and Roger O'Brient and Stephen Padin and Loren J. Swenson and Jonas Zmuidzinas},
journal= {arXiv preprint arXiv:1211.0934},
year = {2012}
}
Comments
10 pages, 8 figures