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This study shows that even with imperfect quantum gates, measuring quantum observables using Pauli Z operators (Ising form) remains efficient. Grouping terms reduces measurements, outperforming local qubit rotations despite added gate errors.

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Area of Science:

  • Quantum computing
  • Quantum information science
  • Computational chemistry

Background:

  • Measuring quantum observables efficiently is crucial for near-term quantum computing.
  • Transforming observables to Ising form (Pauli Z products) reduces measurement counts.
  • Previous methods overlooked the impact of imperfect quantum gate fidelity.

Purpose of the Study:

  • To analyze the impact of non-unitary gate fidelity on measurement schemes for quantum observables.
  • To compare the efficiency of nonlocal vs. local qubit rotations in Ising form measurements under realistic error conditions.
  • To determine if grouping strategies remain advantageous despite gate errors.

Main Methods:

  • Modeling errors introduced by additional gates in Pauli product grouping schemes.
  • Applying circuit fidelity reduction to account for gate imperfections.
  • Calculating the number of measurements required for molecular electronic Hamiltonians using both nonlocal and local qubit rotations.

Main Results:

  • Additional transformations introduce uncertainty, increasing the required number of measurements.
  • Nonlocal qubit rotation schemes still require fewer measurements than local qubit rotation schemes, even with gate errors.
  • The efficiency of grouping strategies persists despite accounting for gate fidelity reduction.

Conclusions:

  • Grouping terms into Ising form is a robust strategy for efficient quantum observable measurement in near-term devices.
  • Nonlocal qubit rotations offer an advantage over local rotations, even when gate errors are considered.
  • This work provides a more realistic estimation of measurement resources needed for quantum algorithms.