FPGA-based trigger system for the LUX dark matter experiment

D. S. Akerib,H.M. Araújo,X. Bai,A.J. Bailey,J. Balajthy,P. Beltrame,E. P. Bernard,A. Bernstein,T. P. Biesiadzinski,E. M. Boulton,A. Bradley,R. Bramante,S.B. Cahn,M.C. Carmona-Benitez,C. Chan,J.J. Chapman,A.A. Chiller,C. Chiller,A. Currie,J. E. Cutter,T. J. R. Davison,L. de Viveiros,A. Dobi,J Dobson,E. Druszkiewicz,B. Edwards,C.H. Faham,S. Fiorucci,R. J. Gaitskell,V.M. Gehman,C. Ghag,K.R. Gibson,Mgd Gilchriese,C. Hall,M. Hanhardt,S. J. Haselschwardt,S.A. Hertel,D. P. Hogan,M. Horn,D.Q. Huang,C. M. Ignarra,M. Ihm,R. G. Jacobsen,W. Ji,K. Kazkaz,D. Khaitan,R. Knoche,N.A. Larsen,C. Lee,B. Lenardo,Kt Lesko,A. Lindote,M.I. Lopes,D.C. Malling,A. Manalaysay,R. Mannino,M. F. Marzioni,D. N. McKinsey,Dongming Mei,J. Mock,M. Moongweluwan,J. A. Morad,A. St. J. Murphy,C. Nehrkorn,Harry Norman Nelson,F. Neves,K. O’Sullivan,K. C. Oliver-Mallory,R.A. Ott,K. J. Palladino,M. Pangilinan,E.K. Pease,P. Phelps,L. Reichhart,C. Rhyne,S. Shaw,T. Shutt,Catarina Silva,W. Skulski,V. Solovov,P. Sorensen,S. Stephenson,T. J. Sumner,M. Szydagis,D. Taylor,W. C. Taylor,B. P. Tennyson,P. A. Terman,D.R. Tiedt,W. H. To,M. Tripathi,L. Tvrznikova,S. Uvarov,J.R. Verbus,R. Webb,J. T. White,T.J. Whitis,Michael S. Witherell,F.L.H. Wolfs,J. Yin,S. K. Young,C. Zhang

FPGA-based trigger system for the LUX dark matter experiment

2016

D. S. Akerib
H.M. Araújo
X. Bai
A.J. Bailey
J. Balajthy
P. Beltrame
E. P. Bernard
A. Bernstein
T. P. Biesiadzinski
E. M. Boulton
A. Bradley
R. Bramante
S.B. Cahn
M.C. Carmona-Benitez
C. Chan
J.J. Chapman
A.A. Chiller
C. Chiller
A. Currie
J. E. Cutter
T. J. R. Davison
L. de Viveiros
A. Dobi
J Dobson
E. Druszkiewicz
B. Edwards
C.H. Faham
S. Fiorucci
R. J. Gaitskell
V.M. Gehman
C. Ghag
K.R. Gibson
Mgd Gilchriese
C. Hall
M. Hanhardt
S. J. Haselschwardt
S.A. Hertel
D. P. Hogan
M. Horn
D.Q. Huang
C. M. Ignarra
M. Ihm
R. G. Jacobsen
W. Ji
K. Kazkaz
D. Khaitan
R. Knoche
N.A. Larsen
C. Lee
B. Lenardo
Kt Lesko
A. Lindote
M.I. Lopes
D.C. Malling
A. Manalaysay
R. Mannino
M. F. Marzioni
D. N. McKinsey
Dongming Mei
J. Mock
M. Moongweluwan
J. A. Morad
A. St. J. Murphy
C. Nehrkorn
Harry Norman Nelson
F. Neves
K. O’Sullivan
K. C. Oliver-Mallory
R.A. Ott
K. J. Palladino
M. Pangilinan
E.K. Pease
P. Phelps
L. Reichhart
C. Rhyne
S. Shaw
T. Shutt
Catarina Silva
W. Skulski
V. Solovov
P. Sorensen
S. Stephenson
T. J. Sumner
M. Szydagis
D. Taylor
W. C. Taylor
B. P. Tennyson
P. A. Terman
D.R. Tiedt
W. H. To
M. Tripathi
L. Tvrznikova
S. Uvarov
J.R. Verbus
R. Webb
J. T. White
T.J. Whitis
Michael S. Witherell
F.L.H. Wolfs
J. Yin
S. K. Young
C. Zhang

Abstract LUX is a two-phase (liquid/gas) xenon time projection chamber designed to detect nuclear recoils resulting from interactions with dark matter particles. Signals from the detector are processed with an FPGA-based digital trigger system that analyzes the incoming data in real-time, with just a few microsecond latency. The system enables first pass selection of events of interest based on their pulse shape characteristics and 3D localization of the interactions. It has been shown to be > 99 % efficient in triggering on S2 signals induced by only few extracted liquid electrons. It is continuously and reliably operating since its full underground deployment in early 2013. This document is an overview of the systems capabilities, its inner workings, and its performance.

Keywords:

Optics
Microsecond
Digital signal processing
Nuclear physics
Physics
Dark matter
Detector
Time projection chamber
Pulse (signal processing)
Latency (engineering)
Data acquisition
Electronic engineering
Field-programmable gate array
Xenon

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