SHARE: Optimizing Secure Hub Allocation and Routing Efficiency in Payment Channel Networks

TL;DR

SHARE is a novel distributed routing scheme for payment channel networks that uses trusted execution environments to optimize hub allocation and routing, significantly improving success rates and throughput while maintaining security.

Contribution

The paper introduces SHARE, a multi-hub distributed routing scheme with TEE assistance, transforming NP-hard problems into solvable forms and dynamically balancing load and security in PCNs.

Findings

43.6% increase in transaction success ratio

Over 181.5% improvement in system throughput

Secure protocol proven under the universally composable framework

Abstract

Payment channel hub (PCH), by leveraging a powerful hub to reliably provide off-chain payment services, offers an effective enhancement to payment channel networks (PCNs). However, existing approaches typically rely on a single hub to relay transactions and provide relationship anonymity between participants. This design lacks flexibility under high-frequency transaction scenarios and fail to adequately balance the security of off-chain payments with PCH efficiency. Moreover, current PCNs often adopt source routing, where each transaction path is predetermined without considering the dynamic distribution of large-scale payment requests, leading to load imbalance and even transaction deadlocks. To address these issues, we propose SHARE, a multi-PCH distributed routing scheme based on trusted execution environments (TEE), designed to optimize secure hub allocation and routing efficiency in PCNs. For the multi-hub allocation problem, SHARE balances the management and synchronization costs among participants, and employs mixed-integer linear programming along with supermodular optimization techniques to transform the NP-hard problem into a solvable form, enabling optimal or approximate solutions across various PCN scales. At the routing layer, SHARE integrates global network state with local sender requests to design a TEE-assisted, privacy-preserving distributed routing protocol that dynamically adjusts multipath flow rates, achieving high-throughput and deadlock-free transaction forwarding. We formally prove the security of the SHARE protocol under the universally composable framework. Experimental results demonstrate that SHARE achieves a 43.6% improvement in transaction success ratio and an over 181.5% enhancement in system throughput compared to state-of-the-art PCN solutions, effectively realizing a secure extension of PCNs.