Mastering Quantum Time Complexity: Insights from TQC 2024 π
Discover advanced techniques in quantum query complexity with experts Aleksandrs Belovs, Stacey Jeffery, and Duyal Yolcu at TQC 2024. Explore how quantum algorithms tackle complex problems efficiently!
Squid: Schools for Quantum Information Development
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Taming Quantum Time Complexity | Aleksandrs Belovs, Stacey Jeffery and Duyal Yolcu
Quantum query complexity has several nice properties with respect to composition. First, bounded-error quantum query algorithms can be composed without incurring log factors through error reduction (\emph{exactness}). Second, through careful accounting (\emph{thriftiness}), the total query complexity is smaller if subroutines are mostly run on cheaper inputs -- a property that is much less obvious in quantum algorithms than in their classical counterparts. While these properties were previously seen through the model of span programs (alternatively, the dual adversary bound), a recent work by two of the authors (Belovs, Yolcu 2023) showed how to achieve these benefits without converting to span programs, by defining \emph{quantum Las Vegas query complexity}. Independently, recent works, including by one of the authors (Jeffery 2022), have worked towards bringing thriftiness to the more practically significant setting of quantum \emph{time} complexity. In this work, we show how to achieve both exactness and thriftiness in the setting of time complexity. We generalize the quantum subroutine composition results of Jeffery 2022 so that, in particular, no error reduction is needed. We give a time complexity version of the well-known result in quantum query complexity, $Q(f\circ g)=\OO(Q(f)\cdot Q(g))$, without log factors. We achieve this by employing a novel approach to the design of quantum algorithms based on what we call \emph{transducers}, and which we think is of large independent interest. While a span program is a completely different computational model, a transducer is a direct generalisation of a quantum algorithm, which allows for much greater transparency and control. Transducers naturally characterize general state conversion, rather than only decision problems; provide a very simple treatment of other quantum primitives such as quantum walks; and lend themselves well to time complexity analysis.
TQC 2024 | 9-13 September 2024 at OIST, Japan
http://tqc-conference.org
19th Conference on the Theory of Quantum Computation, Communication and Cryptography.
TQC is a leading annual international conference for students and researchers working in the theoretical aspects of quantum information science. The scientific objective is to bring together the theoretical quantum information science community to present and discuss the latest advances in the field.
Organisation:
OIST: Okinawa Institute for Science and Technology
Squids: Schools for Quantum Information Development
Sponsors:
JPMorganChase
Google Quantum AI
Horizon Quantum Computing
Quantinuum
Japan National Tourism Organization
Quantum query complexity has several nice properties with respect to composition. First, bounded-error quantum query algorithms can be composed without incurring log factors through error reduction (\emph{exactness}). Second, through careful accounting (\emph{thriftiness}), the total query complexity is smaller if subroutines are mostly run on cheaper inputs -- a property that is much less obvious in quantum algorithms than in their classical counterparts. While these properties were previously seen through the model of span programs (alternatively, the dual adversary bound), a recent work by two of the authors (Belovs, Yolcu 2023) showed how to achieve these benefits without converting to span programs, by defining \emph{quantum Las Vegas query complexity}. Independently, recent works, including by one of the authors (Jeffery 2022), have worked towards bringing thriftiness to the more practically significant setting of quantum \emph{time} complexity. In this work, we show how to achieve both exactness and thriftiness in the setting of time complexity. We generalize the quantum subroutine composition results of Jeffery 2022 so that, in particular, no error reduction is needed. We give a time complexity version of the well-known result in quantum query complexity, $Q(f\circ g)=\OO(Q(f)\cdot Q(g))$, without log factors. We achieve this by employing a novel approach to the design of quantum algorithms based on what we call \emph{transducers}, and which we think is of large independent interest. While a span program is a completely different computational model, a transducer is a direct generalisation of a quantum algorithm, which allows for much greater transparency and control. Transducers naturally characterize general state conversion, rather than only decision problems; provide a very simple treatment of other quantum primitives such as quantum walks; and lend themselves well to time complexity analysis.
TQC 2024 | 9-13 September 2024 at OIST, Japan
http://tqc-conference.org
19th Conference on the Theory of Quantum Computation, Communication and Cryptography.
TQC is a leading annual international conference for students and researchers working in the theoretical aspects of quantum information science. The scientific objective is to bring together the theoretical quantum information science community to present and discuss the latest advances in the field.
Organisation:
OIST: Okinawa Institute for Science and Technology
Squids: Schools for Quantum Information Development
Sponsors:
JPMorganChase
Google Quantum AI
Horizon Quantum Computing
Quantinuum
Japan National Tourism Organization
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26:55
Published
Oct 8, 2024