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Quantum-assisted trustworthiness for the Quantum Internet.

Agustín Zaballos1, Adrià Mallorquí1, Joan Navarro1

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New quantum-assisted mechanisms enhance system trustworthiness and performance in wireless networks. These quantum internet approaches improve fault tolerance by reducing message flooding, boosting performance by up to 28%.

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Area of Science:

  • Distributed Systems
  • Quantum Communication
  • Wireless Networks

Background:

  • Device redundancy is crucial for fault tolerance and trustworthiness in distributed systems.
  • Classical redundancy algorithms cause performance degradation in bandwidth-limited wireless networks due to message flooding.
  • Quantum-assisted mechanisms offer a promising alternative for improving performance in such networks.

Purpose of the Study:

  • To explore quantum-assisted mechanisms for enhancing system trustworthiness.
  • To utilize super-additivity and superposed quantum trajectories in a quantum internet context.
  • To improve performance in wireless communication networks supporting critical services like Antarctic permafrost telemetry.

Main Methods:

  • Simulation of a wireless communication network for Antarctic permafrost telemetry.
  • Comparison of three classical operational modes with two quantum-assisted operational modes.
  • Application of super-additivity and superposed quantum trajectories within the quantum internet framework.

Main Results:

  • Quantum-assisted mechanisms demonstrated superior performance compared to classical methods.
  • System performance improvements of up to 28% were observed with the new quantum approaches.
  • Reduced message flooding in quantum-assisted mechanisms leads to better efficiency.

Conclusions:

  • Quantum-assisted mechanisms, leveraging super-additivity and quantum trajectories, significantly enhance system trustworthiness and performance.
  • This approach offers a viable solution for improving fault tolerance in bandwidth-constrained wireless communication networks.
  • The findings suggest a promising future for quantum internet applications in critical infrastructure monitoring.