Publication details for Dr Vivien KendonProctor, Timothy, Giulian, Melissa, Korolkova, Natalia, Andersson, Erika & Kendon, Viv (2017). Ancilla-driven quantum computation for qudits and continuous variables. Physical Review A 95(5): 052317.
- Publication type: Journal Article
- ISSN/ISBN: 2469-9926 (print), 2469-9934 (electronic)
- DOI: 10.1103/PhysRevA.95.052317
- Further publication details on publisher web site
- Durham Research Online (DRO) - may include full text
Author(s) from Durham
Although qubits are the leading candidate for the basic elements in a quantum computer, there are also a range of reasons to consider using higher-dimensional qudits or quantum continuous variables (QCVs). In this paper, we use a general “quantum variable” formalism to propose a method of quantum computation in which ancillas are used to mediate gates on a well-isolated “quantum memory” register and which may be applied to the setting of qubits, qudits (for
), or QCVs. More specifically, we present a model in which universal quantum computation may be implemented on a register using only repeated applications of a single fixed two-body ancilla-register interaction gate, ancillas prepared in a single state, and local measurements of these ancillas. In order to maintain determinism in the computation, adaptive measurements via a classical feed forward of measurement outcomes are used, with the method similar to that in measurement-based quantum computation (MBQC). We show that our model has the same hybrid quantum-classical processing advantages as MBQC, including the power to implement any Clifford circuit in essentially one layer of quantum computation. In some physical settings, high-quality measurements of the ancillas may be highly challenging or not possible, and hence we also present a globally unitary model which replaces the need for measurements of the ancillas with the requirement for ancillas to be prepared in states from a fixed orthonormal basis. Finally, we discuss settings in which these models may be of practical interest.