P. O'Connor ; P. Antilogus ; P. Doherty ; J. Haupt ; S. Herrmann, et al. " Integrated system tests of the LSST raft tower modules ", Proc. SPIE 9915, High Energy, Optical, and Infrared Detectors for Astronomy VII, 99150X (July 27, 2016); doi:10.1117/12.2232729; http://dx.doi.org/10.1117/12.2232729
Publication Date:
Wednesday, July 27, 2016
Type:
Conference Papers
SPIE
Citable:
no
SPIE Proceedings
Volume:
9915
Abstract:
The science focal plane of the LSST camera is made up of 21 fully autonomous 144 Mpixel imager units designated raft tower modules (RTM). These imagers incorporate nine 4K x 4K fully-depleted CCDs and 144 channels of readout electronics, including a dedicated CMOS video processing ASIC and components that provide CCD biasing and clocking, video digitization, thermal stabilization, and a high degree of monitoring and telemetry. The RTM achieves its performance goals for readout speed, read noise, linearity, and crosstalk with a power budget of less than 400mW/channel. Series production is underway on the first units and the production will run until 2018. We present the RTM final design, tests of the integrated signal chain, and performance results for the fully-integrated module with pre-production CCDs. © (2016) COPYRIGHT Society of Photo-Optical Instrumentation Engineers (SPIE). Downloading of the abstract is permitted for personal use only.
Reviewed Under:
LSST Project Publication Policy
Bibtex reference:
@proceeding{doi:10.1117/12.2232729,
author = {O'Connor, P. and Antilogus, P. and Doherty, P. and Haupt, J. and Herrmann, S. and Huffer, M. and Juramy-Giles, C. and Kuczewski, J. and Russo, S. and Stubbs, C. and Van Berg, R.},
title = {
Integrated system tests of the LSST raft tower modules
},
journal = {Proc. SPIE},
volume = {9915},
number = {},
pages = {99150X-99150X-12},
abstract = {
The science focal plane of the LSST camera is made up of 21 fully autonomous 144 Mpixel imager units designated raft tower modules (RTM). These imagers incorporate nine 4K x 4K fully-depleted CCDs and 144 channels of readout electronics, including a dedicated CMOS video processing ASIC and components that provide CCD biasing and clocking, video digitization, thermal stabilization, and a high degree of monitoring and telemetry. The RTM achieves its performance goals for readout speed, read noise, linearity, and crosstalk with a power budget of less than 400mW/channel. Series production is underway on the first units and the production will run until 2018. We present the RTM final design, tests of the integrated signal chain, and performance results for the fully-integrated module with pre-production CCDs.
},
year = {2016},
doi = {10.1117/12.2232729},
URL = { http://dx.doi.org/10.1117/12.2232729},
eprint = {}
}