Fast elementary gates for universal quantum computation with Kerr
parametric oscillator qubits
- URL: http://arxiv.org/abs/2310.20108v1
- Date: Tue, 31 Oct 2023 01:03:21 GMT
- Title: Fast elementary gates for universal quantum computation with Kerr
parametric oscillator qubits
- Authors: Taro Kanao, Hayato Goto
- Abstract summary: Kerr parametric oscillators (KPOs) can stabilize the superpositions of coherent states, which can be utilized as qubits, and are promising candidates for realizing hardware-efficient quantum computers.
Although elementary gates for universal quantum computation with KPO qubits have been proposed, these gates are usually based on adiabatic operations and need long gate times.
In this work, we accelerate the elementary gates by experimentally feasible control methods, which are based on numerical optimization of pulse shapes for shortcuts to adiabaticity.
- Score: 0.0
- License: http://arxiv.org/licenses/nonexclusive-distrib/1.0/
- Abstract: Kerr parametric oscillators (KPOs) can stabilize the superpositions of
coherent states, which can be utilized as qubits, and are promising candidates
for realizing hardware-efficient quantum computers. Although elementary gates
for universal quantum computation with KPO qubits have been proposed, these
gates are usually based on adiabatic operations and thus need long gate times,
which result in errors caused by photon loss in KPOs realized by, e.g.,
superconducting circuits. In this work, we accelerate the elementary gates by
experimentally feasible control methods, which are based on numerical
optimization of pulse shapes for shortcuts to adiabaticity. By numerical
simulations, we show that the proposed methods can achieve speedups compared to
adiabatic ones by up to six times with high gate fidelities of 99.9%. These
methods are thus expected to be useful for quantum computers with KPOs.
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