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This study introduces a new protocol to learn quantum states using classical shadows and matrix-product operators (MPO). The method efficiently reconstructs complex quantum states from experimental data, advancing quantum computation.

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Area of Science:

  • Quantum Information Science
  • Quantum Computing
  • Quantum State Tomography

Background:

  • Accurately representing quantum states is crucial for quantum computation and simulation.
  • Classical shadows offer a resource-efficient method for quantum state tomography.
  • Matrix-product operator (MPO) is a powerful tool for describing many-body quantum systems.

Purpose of the Study:

  • To develop and validate a protocol for learning matrix-product operator (MPO) representations of experimentally prepared quantum states.
  • To enable efficient reconstruction and characterization of quantum states from classical shadow data.
  • To enhance the scalability of quantum state learning for large quantum systems.

Main Methods:

  • Inputting classical shadows from local randomized measurements.
  • Optimizing MPO tensors sequentially to maximize fidelity with the experimental state.
  • Utilizing a protocol similar to the density matrix renormalization group algorithm.

Main Results:

  • Demonstrated provable efficiency under conditions relevant to short-range correlated states and noisy experiments.
  • Developed an efficient scheme for estimating fidelities between learned and experimental states.
  • Successfully learned entangled quantum states of up to 96 qubits on a superconducting quantum processor.

Conclusions:

  • The presented protocol effectively upgrades classical shadows for large-scale quantum computation and simulation.
  • This method provides a scalable approach to quantum state learning and characterization.
  • The protocol shows promise for advancing experimental quantum information processing.