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Local clustering decoder as a fast and adaptive hardware decoder for the surface code.

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A new Local Clustering Decoder offers accurate and fast real-time decoding for quantum computers. This breakthrough reduces the number of physical qubits needed for fault-tolerant quantum computation, enabling more operations.

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Area of Science:

  • Quantum Information Science
  • Computer Engineering

Background:

  • Fault-tolerant quantum computation requires efficient decoding to manage errors.
  • Current decoding methods face trade-offs between speed and accuracy, hindering practical quantum computing.

Purpose of the Study:

  • To introduce a novel decoding system that meets both accuracy and speed requirements for real-time quantum error correction.
  • To reduce the overheads associated with fault-tolerant quantum computation.

Main Methods:

  • Implementation of the Local Clustering Decoder on Field-Programmable Gate Arrays (FPGAs).
  • Exploitation of hardware parallelism and an adaptivity engine for real-time updates.
  • Testing under a circuit-level noise model with leakage as a primary error source.

Main Results:

  • The Local Clustering Decoder achieves high accuracy and speed, decoding in under 1 microsecond per round.
  • Enables one million error-free quantum operations using 4x fewer physical qubits compared to standard non-adaptive decoders.
  • Demonstrates efficient performance with modest FPGA resources.

Conclusions:

  • The Local Clustering Decoder provides a viable solution for real-time decoding in fault-tolerant quantum computation.
  • This advancement significantly reduces qubit overhead, paving the way for scalable quantum computers.
  • The adaptive nature of the decoder enhances its robustness against dominant error sources like leakage.