Focal Interest
Focal Interest

Quantum Computing Algorithms and Architecture

External reference: https://openalex.org/T10682

  1. Noisy quantum circuits can behave like shallow circuits
    Theoretical analysis of how local noise restricts quantum circuits to shallow depths and prevents barren plateaus, enabling efficient classical simulation of observable expectation value estimation.
  2. Communication settings can be translated in delegated quantum computing
    Unified framework for delegated quantum computing shows that prepare-and-send and receive-and-measure protocols are interchangeable, removing fundamental constraints on distributed quantum computing.
  3. Non-Gaussian measurements enable near-optimal coherent state discrimination
    Study demonstrates that non-Gaussian continuous quantum measurements can achieve near-optimal coherent state discrimination, surpassing traditional Gaussian limits without requiring photon detection.
  4. Quantum data centres may support scalable quantum networking
    Quantum data centres overcome NISQ limitations through distributed quantum computing, leveraging entanglement orchestrators for dynamic network reconfiguration toward large-scale quantum internet.
  5. Integrating Quantum Software Tools with(in) MLIR
    A practical guide for integrating quantum software tools using MLIR infrastructure, demonstrated through a case study connecting PennyLane and Munich Quantum Toolkit.