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QI: Fachverband Quanteninformation

QI 29: Quantum Information: Concept and Methods II

QI 29.9: Vortrag

Donnerstag, 21. März 2024, 17:15–17:30, HFT-TA 441

Hardware-Tailored Mutually Unbiased Bases — •Kyano Levi^1,2, Eric Kuehnke², Daniel Miller², and Jens Eisert² — ¹Technische Universität Berlin — ²Freie Universität Berlin

Gathering sufficient statistics for quantum state tomography poses a bottleneck for applications on current quantum hardware. In our work, we address this bottleneck by constructing hardware-tailored and near-optimal quantum circuits for diagonalizing entire stabilizer groups on n≤ 6 qubits.

We use the new circuits to craft sets of mutually unbiased bases that are tailored to important hardware connectivities. Our results allow for an exponential reduction of the sample complexity when performing full-state tomography on up to n = 12 qubits, as verified by theory, simulations, and experiments on quantum hardware. Specifically, we achieve a 1.8x shot reduction over state-of-the-art tensor product bases for three-qubit full-state tomography with a cloud-based quantum computer. With classical simulations, we demonstrate a theoretical shot reduction of 11.4x for n = 11 qubits.

Our circuits feature a two-qubit gate depth that is within reach for present-day, erroneous quantum hardware, rendering them a versatile building block for meaningful applications on existing devices.

Keywords: quantum state tomography; circuit optimization; stabilizer circuits; mutually unbiased bases; graph states