Characterizing a Four-Qubit Planar Lattice for Arbitrary Error Detection
Abstract
Quantum error correction will be a necessary component towards realizing scalable quantum computers with physical qubits. Theoretically, it is possible to perform arbitrarily long computations if the error rate is below a threshold value. The two-dimensional surface code permits relatively high fault-tolerant thresholds at the ~1% level, and only requires a latticed network of qubits with nearest-neighbor interactions. Superconducting qubits have continued to steadily improve in coherence, gate, and readout fidelities, to become a leading candidate for implementation into larger quantum networks. Here we describe characterization experiments and calibration of a system of four superconducting qubits arranged in a planar lattice, amenable to the surface code. Insights into the particular qubit design and comparison between simulated parameters and experimentally determined parameters are given. Single- and two-qubit gate tune-up procedures are described and results for simultaneously benchmarking pairs of two-qubit gates are given. All controls are eventually used for an arbitrary error detection protocol described in separate work [Corcoles et al., Nature Communications, 6, 2015]
Cite
@article{arxiv.1509.02815,
title = {Characterizing a Four-Qubit Planar Lattice for Arbitrary Error Detection},
author = {Jerry M. Chow and Srikanth J. Srinivasan and Easwar Magesan and A D. Corcoles and David W. Abraham and Jay M. Gambetta and Matthias Steffen},
journal= {arXiv preprint arXiv:1509.02815},
year = {2015}
}
Comments
9 pages, 3 figures in Proc. SPIE 9500, Quantum Information and Computation XIII, 95001G (May 21, 2015)