The New Small Wheel electronics
Abstract
The increase in luminosity, and consequent higher backgrounds, of the LHC upgrades require improved rejection of fake tracks in the forward region of the ATLAS Muon Spectrometer. The New Small Wheel upgrade of the Muon Spectrometer aims to reduce the large background of fake triggers from track segments that are not originated from the interaction point. The New Small Wheel employs two detector technologies, the resistive strip Micromegas detectors and the "small" Thin Gap Chambers, with a total of 2.45 Million electrodes to be sensed. The two technologies require the design of a complex electronics system given that it consists of two different detector technologies and is required to provide both precision readout and a fast trigger. It will operate in a high background radiation region up to about 20 kHz/cm at the expected HL-LHC luminosity of =7.5cms. The architecture of the system is strongly defined by the GBTx data aggregation ASIC, the newly-introduced FELIX data router and the software based data handler of the ATLAS detector. The electronics complex of this new detector was designed and developed in the last ten years and consists of multiple radiation tolerant Application Specific Integrated Circuits, multiple front-end boards, dense boards with FPGA's and purpose-built Trigger Processor boards within the ATCA standard. The New Small Wheel has been installed in 2021 and is undergoing integration within ATLAS for LHC Run 3. It should operate through the end of Run 4 (December 2032). In this manuscript, the overall design of the New Small Wheel electronics is presented.
Cite
@article{arxiv.2303.12571,
title = {The New Small Wheel electronics},
author = {G. Iakovidis and L. Levinson and Y. Afik and C. Alexa and T. Alexopoulos and J. Ameel and D. Amidei and D. Antrim and A. Badea and C. Bakalis and H. Boterenbrood and R. S. Brener and S. Chan and J. Chapman and G. Chatzianastasiou and H. Chen and M. C. Chu and R. M. Coliban and T. Costa de Paiva and G. de Geronimo and R. Edgar and N. Felt and S. Francescato and M. Franklin and T. Geralis and K. Gigliotti and P. Giromini and P. Gkountoumis and I. Grayzman and L. Guan and J. Guimaraes da Costa and L. Han and S. Hou and X. Hu and K. Hu and J. Huth and M. Ivanovici and G. Jin and K. Johns and E. Kajomovitz and G. Kehris and I. Kiskiras and A. Koulouris and E. Kyriakis and A. Lankford and L. Lee and H. Leung and F. Li and Y. Liang and H. Lu and N. Lupu and V. Martinez and S. Martoiu and D. Matakias and I. Mehalev and I. Mesolongitis and P. Miao and G. Mikenberg and L. Moleri and P. Moschovakos and J. Narevicius and J. Oliver and D. Pietreanu and R. Pinkham and E. Politis and V. Polychronakos and S. Popa and M. M. Prapa and I. Ravinovich and A. Roich and R. A. Rojas Caballero and Y. Rozen and M. Schernau and T. Schwartz and G. Scott and O. Shaked and M. Solis and S. Sun and A. Taffard and S. Tang and Z. Tarem and W. Tse and Y. Tu and A. Tuna and P. Tzanis and S. Tzanos and R. Vari and M. Vasile and A. Vdovin and J. Vermeulen and J. Wang and X. Wang and A. Wang and R. Wang and X. Xiao and L. Yao and C. Yildiz and K. Zachariadou and B. Zhou and J. Zhu and S. U. Zimmermann and O. Zormpa},
journal= {arXiv preprint arXiv:2303.12571},
year = {2023}
}
Comments
61 pages