CoBRA: A Universal Strategyproof Confirmation Protocol for Quorum-based Proof-of-Stake Blockchains

Abstract

The security of many Proof-of-Stake (PoS) payment systems relies on quorum-based State Machine Replication (SMR) protocols. While classical analyses assume purely Byzantine faults, real-world systems must tolerate both arbitrary failures and strategic, profit-driven validators. We therefore study quorum-based SMR under a hybrid model with honest, Byzantine, and rational participants. We first establish the fundamental limitations of traditional consensus mechanisms, proving two impossibility results: (1) in partially synchronous networks, no quorum-based protocol can achieve SMR when rational and Byzantine validators collectively exceed 1/3 of the participants; and (2) even under synchronous network assumptions, SMR remains unattainable if this coalition comprises more than 2/3 of the validator set. Assuming a synchrony bound Δ, we show how to extend any quorum-based SMR protocol to tolerate up to 1/3 Byzantine and 1/3 rational validators by modifying only its finalization rule. Our approach enforces a necessary bound on the total transaction volume finalized within any time window Δ and introduces the strongest chain rule, which enables efficient finalization of transactions when a supermajority of honest participants provably supports execution. Empirical analysis of Ethereum and Cosmos demonstrates validator participation exceeding the required 5/6 threshold in over 99% of blocks, supporting the practicality of our design. Finally, we present a recovery mechanism that restores safety and liveness after consistency violations, even with up to 5/9 Byzantine stake and 1/9 rational stake, guaranteeing full reimbursement of provable client losses.