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Scientists typically make repeated measurements of a quantity to ensure the quality of their findings and to evaluate both the precision and the accuracy of their results. Measurements are said to be precise if they yield very similar results when repeated in the same manner. A measurement is considered accurate if it yields a result that is very close to the true or the accepted value. Precise values agree with each other; accurate values agree with a true value. 
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Related Experiment Video

Updated: Dec 9, 2025

Quantum State Engineering of Light with Continuous-wave Optical Parametric Oscillators
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Experimental Characterization of Unsharp Qubit Observables and Sequential Measurement Incompatibility via Quantum

Hammad Anwer1, Sadiq Muhammad1, Walid Cherifi1

  • 1Department of Physics, Stockholm University, S-10691 Stockholm, Sweden.

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|September 10, 2020
PubMed
Summary
This summary is machine-generated.

This study demonstrates unsharp qubit measurements in a quantum random access code, outperforming classical and projective quantum methods. This advance enables noise-robust characterization and quantifies measurement incompatibility.

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Area of Science:

  • Quantum Information Science
  • Quantum Foundations
  • Quantum Measurement Theory

Background:

  • Unsharp measurements are crucial for advancing quantum theory and quantum information applications.
  • Implementing and characterizing these measurements is essential for practical quantum technologies.

Purpose of the Study:

  • To experimentally implement unsharp qubit measurements within a sequential quantum random access code (QRAC).
  • To demonstrate a nearly optimal sequential QRAC that surpasses classical and projective quantum protocols.
  • To develop a noise-robust characterization of unsharp measurements and quantify measurement incompatibility.

Main Methods:

  • Utilized a three-party sequential communication protocol involving qubit preparation, operation with classical/quantum outcomes, and measurement.
  • Implemented unsharp qubit measurements in a quantum random access code framework.
  • Applied noise-robust characterization techniques based on the sequential QRAC.

Main Results:

  • Demonstrated a nearly optimal sequential quantum random access code.
  • The implemented protocol outperformed the best classical and projective quantum protocols.
  • Successfully achieved noise-robust characterization of unsharp measurements.
  • Quantified the degree of incompatibility between sequential quantum measurement pairs.

Conclusions:

  • Unsharp qubit measurements can be effectively implemented in sequential QRAC protocols.
  • This approach offers advantages over classical and projective measurement-based quantum communication.
  • The developed characterization method is robust to noise and useful for analyzing quantum measurement properties.