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Complete 3-Qubit Grover Search on a Programmable Quantum Computer

Quantum Physics 2017-12-05 v1 Emerging Technologies

Abstract

Searching large databases is an important problem with broad applications. The Grover search algorithm provides a powerful method for quantum computers to perform searches with a quadratic speedup in the number of required database queries over classical computers. It is an optimal search algorithm for a quantum computer, and has further applications as a subroutine for other quantum algorithms. Searches with two qubits have been demonstrated on a variety of platforms and proposed for others, but larger search spaces have only been demonstrated on a non-scalable NMR system. Here, we report results for a complete three-qubit Grover search algorithm using the scalable quantum computing technology of trapped atomic ions, with better-than-classical performance. The algorithm is performed for all 8 possible single-result oracles and all 28 possible two-result oracles. Two methods of state marking are used for the oracles: a phase-flip method employed by other experimental demonstrations, and a Boolean method requiring an ancilla qubit that is directly equivalent to the state-marking scheme required to perform a classical search. All quantum solutions are shown to outperform their classical counterparts. We also report the first implementation of a Toffoli-4 gate, which is used along with Toffoli-3 gates to construct the algorithms; these gates have process fidelities of 70.5% and 89.6%, respectively.

Keywords

Cite

@article{arxiv.1703.10535,
  title  = {Complete 3-Qubit Grover Search on a Programmable Quantum Computer},
  author = {C. Figgatt and D. Maslov and K. A. Landsman and N. M. Linke and S. Debnath and C. Monroe},
  journal= {arXiv preprint arXiv:1703.10535},
  year   = {2017}
}

Comments

11 pages, 10 figures, 2 tables

R2 v1 2026-06-22T19:02:27.075Z