Precision charge amplification and digitization system for a scintillating and lead glass array

Authors :: Spyros Tzamarias
Q. Shen
R. P. Smith
A. Simard
A. Marchionni
M. Haire
Michael Wayne Arenton
L. Turnbull
D. Judd
A. Manousakis-Katsikakis
R. Tesarek
S. Delchamps
Christine Kourkoumelis
D. E. Wagoner
K.W. Lai
Leonard Spiegel
G. Zioulas
Chao Wang
G. Voulgaris
T. Turkington
R. A. Rameika
P. Ioannu
C.M. Jenkins
J. Koutentakis
B. Etemadi
F. Turkot
P.O. Mazur
Bradley Cox
S. Conetti
J. L. Rosen
M. Vassiliou
K. Guffey
C. T. Murphy
L. K. Resvanis
J. Kuzminski
L.R. Fortney
W. Tucker
C.H. Shen
Dg Stairs
N. J. Zhang
He Mao
T.Y. Chen
W. Yang
N. Yao
T. Pramantiotis
M. Rosati
Xiang Zhang
Source :: IEEE Transactions on Nuclear Science. 36:680-686
Publication Year :: 1989
Publisher :: Institute of Electrical and Electronics Engineers (IEEE), 1989.
Abstract: A 544-channel low-noise, high-rate precision charge-amplification and ADC (analog/digital converter) system was constructed for the Fermilab Experiment 705 electromagnetic calorimeter, which uses SCG1-C scintillating glass and SF5 lead glass instrumented with photomultiplier tubes. A general discussion of the system is given, and the charge amplification, fast-trigger-pulse generation, and analog/digital conversion aspects of the system are presented in more detail. Performance is evaluated using data from Experiment 705 and from offline tests. Short- and long-term pedestal stability, baseline recovery and rate capability, linearity of response, and crosstalk between channels are discussed. >

Subjects :: Nuclear and High Energy Physics
Engineering
Photomultiplier
Physics::Instrumentation and Detectors
business.industry
Amplifier
Linearity
Particle detector
Lead glass
Optics
Nuclear Energy and Engineering
visual_art
Nuclear electronics
visual_art.visual_art_medium
Electronic engineering
Measuring instrument
Electrical and Electronic Engineering
business
Electronic circuit

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