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Multimodal Deep Representation Learning for Quantum Cross-Platform Verification.

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This study introduces a multimodal learning approach for quantum computing cross-platform verification. It significantly improves accuracy in comparing quantum devices, overcoming limitations of previous methods.

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Area of Science:

  • Quantum Computing
  • Machine Learning
  • Quantum Information Science

Background:

  • Cross-platform verification is crucial for early-stage quantum computing, comparing imperfect quantum devices with minimal measurements.
  • The random measurement approach faces scalability challenges due to quasi-exponential computational costs with increasing qubit count.
  • Existing methods struggle with large-qubit systems, necessitating advanced techniques.

Purpose of the Study:

  • To introduce an innovative multimodal learning approach for cross-platform verification in quantum computing.
  • To address the limitations of existing methods in handling large-qubit quantum systems.
  • To enhance the characterization of similarity between quantum devices.

Main Methods:

  • Developed a multimodal neural network to process two distinct data modalities: measurement outcomes and classical circuit descriptions.
  • Independently extracted knowledge from each modality.
  • Fused the extracted knowledge to create a comprehensive data representation for device comparison.

Main Results:

  • Achieved a 3-orders-of-magnitude improvement in prediction accuracy compared to random measurements.
  • Demonstrated effective characterization of quantum device similarity for new quantum algorithms.
  • Evaluated the approach on systems up to 50 qubits with diverse noise models.

Conclusions:

  • Multimodal learning offers a powerful solution for cross-platform verification in quantum computing.
  • The complementary roles of measurement outcomes and circuit descriptions are vital for accurate device comparison.
  • This approach paves the way for broader applications of machine learning in quantum system analysis.