Thesis (Ph. D.)--University of Rochester. Department of Electrical and Computer Engineering, 2017.
With a wealth of astrophysical evidence that confirms that the baryonic matter
we understand accounts for only 5% of the matter and energy in the universe,
the search is on for the mysterious dark matter, that is said to account for
25% of the universe composition. The leading candidate for dark matter is
the Weakly Interacting Massive Particle (WIMP).
Large Underground Xenon (LUX), a 370 kg two-phase (liquid/gas) xenon
time projection chamber operating at 4850 feet underground at the Sanford
Underground Research Facility (SURF), has recently completed its operation,
setting the world’s best limit on the WIMP-nucleon cross section. This thesis
presents the author’s research and development of a novel, FPGA-based,
triggering system. This system has operated at SURF since 2011 and through
digital signal processing techniques identified events of interest in real-time.
The system processes the incoming data at its filter stages with a rate of 5,100
MB/s and does so consuming a total of only 15 W. The firmware and software
were entirely developed by the author, while the custom-built hardware was
developed in close collaboration with the author. The system offers great flexibility
through the reconfigurability feature of FPGAs, which was exercised
often during the course of the experiment. The system allows for fully remote
operation, minimizing the personnel needs one mile underground. For
this type of detectors, this triggering system has shown to offer the highest
efficiency in detecting signals as small as few liquid electrons. An FIR digital
filter implementation is presented, that has been tailored for this application
and offers an up to 99% and 97% savings in scalars and summers utilization, respectively.
LUX-Zepplin (LZ) is a next-generation dark matter detector, that is scheduled
to start probing the remainder of the uncharted WIMP-nucleon cross section
in 2020. It is a significantly larger successor of LUX, with a total xenon
mass of 10 tonne. It will be instrumented with 745 photomultipliers, totaling
1,359 digitizing channels. The author is developing the LZ Data Acquisition
and Data Sparsification system. This system is going to handle a continuous
input rate of over 200 GB/s and its key elements have already been shown
to meet and exceed the LZ requirements. Techniques are presented for allowing
data volume footprint reduction, such as efficient digitized pulse storage,
offering up to 45% reduction in the effective pulse storage size.