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Underflow gates are vital for controlling water flow in irrigation canals. The three main types of underflow gates — vertical, radial, and drum gates — serve different purposes while ensuring effective flow management. Vertical gates move up and down, generating a free-flowing water jet; radial gates pivot to regulate the flow; and drum gates rotate for precise adjustments. The flow through these gates is influenced by downstream conditions, resulting in free or drowned outflow.Free and...
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Leakage Benchmarking for Universal Gate Sets.

Bujiao Wu1,2, Xiaoyang Wang1,3, Xiao Yuan1,2

  • 1Center on Frontiers of Computing Studies, Peking University, Beijing 100871, China.

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|January 22, 2024
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Summary
This summary is machine-generated.

We introduce leakage randomized benchmarking (LRB) to accurately measure quantum system leakage. This new method is robust against noise and benchmarks multi-qubit systems, overcoming limitations of prior techniques.

Keywords:
leakage errorquantum computingquantum gatesrandomized benchmarking

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Area of Science:

  • Quantum Information Science
  • Quantum Computing
  • Quantum Error Correction

Background:

  • Leakage errors, the loss of quantum information to extraneous states, are a significant challenge in quantum computing.
  • Existing methods for benchmarking leakage are often sensitive to noise and limited to single qubits.
  • Developing robust leakage detection and correction is crucial for advancing fault-tolerant quantum computation.

Purpose of the Study:

  • To propose an efficient and accurate framework for measuring leakage rates in multi-qubit quantum systems.
  • To develop a protocol less sensitive to state preparation and measurement (SPAM) noise compared to existing methods.
  • To enable benchmarking of multi-qubit leakages, a capability not previously achieved.

Main Methods:

  • Introduction of Leakage Randomized Benchmarking (LRB) for quantifying leakage in quantum systems.
  • Development of an interleaved variant (iLRB) to benchmark average leakage rates of multi-qubit gates under noise assumptions.
  • Experimental demonstration of iLRB on two-qubit gates using flux tuning, with analysis against leakage models.

Main Results:

  • LRB demonstrates improved insensitivity to SPAM noise and fewer gate set assumptions.
  • LRB successfully benchmarks leakage in multi-qubit systems for the first time.
  • Numerical experiments show good agreement between iLRB protocol results and theoretical leakage models.

Conclusions:

  • The proposed LRB and iLRB protocols offer efficient and accurate methods for leakage characterization in quantum systems.
  • These protocols advance the ability to detect and mitigate leakage errors, crucial for scalable quantum computing.
  • The feasibility of LRB and iLRB paves the way for more reliable quantum hardware development and error correction strategies.