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@PHDTHESIS{Vliex:903224,
author = {Vliex, Patrick Norbert},
title = {{M}odelling, implementation and characterization of a
{B}ias-{DAC} in {CMOS} as a building block for scalable
cryogenic control electronics for future quantum computers},
volume = {74},
school = {RWTH Aachen},
type = {Dissertation},
address = {Jülich},
publisher = {Forschungszentrum Jülich GmbH Zentralbibliothek, Verlag},
reportid = {FZJ-2021-04931},
isbn = {978-3-95806-588-8},
series = {Schriften des Forschungszentrums Jülich. Reihe Information
/ Information},
pages = {xiv, 107, xv-xxviii S.},
year = {2021},
note = {RWTH Aachen, Diss., 2021},
abstract = {Quantum computing is a research field of increasing
attention and popularity, which has steadily gained momentum
in the recent years. The promises made for universal QC are
vast in terms of their predicted impact to science, economy
and society. A universal quantum computer will be able to
solve specific tasks up to exponentially faster than any
modern supercomputer. Applications range from quantum
chemistry in catalyst research and protein folding
simulations to search algorithms for unordered databases and
cryptography. Quantum bits are typically operated inside a
dilution refrigerator at temperatures close to absolute
zero, i.e. < 1K. The majority of the QC scientific research
community agrees that an estimated number of $\gtrapprox$
10$^{6}$ quantum bits are required to build an universal
quantum computer. This number leads to foreseeable
connectivity bottlenecks to fed all the required biasing,
control and read-out signals into the cryostat. This work is
using a TSMC 65 nm CMOS technology to integrate classical
control electronics closer with the quantum bits and thus
pave a way for scalability. Other publications showed the
feasibility of operating CMOS technologies at deep cryogenic
temperatures. Whereas various papers presented
implementations of cryogenic electronics for quantum bit
control, a scalable solution for quantum bit biasing is
missing and is the focus of this work. A capacitive
digital-to-analog converter (DAC) for biasing of quantum
bits is modeled, implemented and characterized at cryogenic
temperatures. Special emphasis is placed upon achieving a
systematically scalable and ultra-low power DAC design. The
DAC design includes a reference voltage coarse tuning scheme
in order to lower power consumption and increase resolution.
Two calibration procedures to mitigate gain error induced
output voltage jumps are described and the most promising
approach is verifiedat cryogenic temperatures. Auxiliary
circuitry is added to enable DAC characterization, i.e.
operational amplifiers and a ΣΔ modulator. System level
considerations as well as implementation details and
measurement results for of all these circuit blocks are
presented. The design and implementation of a bandgap
reference and a linear regulator, which are investigated as
building blocks for cryogenic supply and reference voltage
regulation, are also described. Measurement results of these
circuit blocks at cryogenic temperatures are also part of
this work. All circuit designs are aimed at optimum
robustness and high configurability in order to cope with
cryogenic CMOS effects and the lack of valid device models
in the temperature regime of interest.},
cin = {ZEA-2},
cid = {I:(DE-Juel1)ZEA-2-20090406},
pnm = {899 - ohne Topic (POF4-899)},
pid = {G:(DE-HGF)POF4-899},
typ = {PUB:(DE-HGF)3 / PUB:(DE-HGF)11},
url = {https://juser.fz-juelich.de/record/903224},
}
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