English

TBDD: A New Trust-based, DRL-driven Framework for Blockchain Sharding in IoT

Cryptography and Security 2024-01-02 v1

Abstract

Integrating sharded blockchain with IoT presents a solution for trust issues and optimized data flow. Sharding boosts blockchain scalability by dividing its nodes into parallel shards, yet it's vulnerable to the 1%1\% attacks where dishonest nodes target a shard to corrupt the entire blockchain. Balancing security with scalability is pivotal for such systems. Deep Reinforcement Learning (DRL) adeptly handles dynamic, complex systems and multi-dimensional optimization. This paper introduces a Trust-based and DRL-driven (\textsc{TbDd}) framework, crafted to counter shard collusion risks and dynamically adjust node allocation, enhancing throughput while maintaining network security. With a comprehensive trust evaluation mechanism, \textsc{TbDd} discerns node types and performs targeted resharding against potential threats. The model maximizes tolerance for dishonest nodes, optimizes node movement frequency, ensures even node distribution in shards, and balances sharding risks. Rigorous evaluations prove \textsc{TbDd}'s superiority over conventional random-, community-, and trust-based sharding methods in shard risk equilibrium and reducing cross-shard transactions.

Keywords

Cite

@article{arxiv.2401.00632,
  title  = {TBDD: A New Trust-based, DRL-driven Framework for Blockchain Sharding in IoT},
  author = {Zixu Zhang and Guangsheng Yu and Caijun Sun and Xu Wang and Ying Wang and Ming Zhang and Wei Ni and Ren Ping Liu and Andrew Reeves and Nektarios Georgalas},
  journal= {arXiv preprint arXiv:2401.00632},
  year   = {2024}
}
R2 v1 2026-06-28T14:05:47.044Z