According to Foresight News, on May 19, Anza, a developer studio spun off from Solana Labs, introduced a new consensus layer protocol for Solana named Alpenglow. This protocol modifies the existing TowerBFT and PoH consensus mechanisms by incorporating new components, Votor and Rotor, to handle voting and block finality, and to enhance Solana's current block propagation protocol. Built on Turbine, Solana's version of sharding, it optimizes bandwidth usage through a single-layer relay node based on stake.
Roger Wattenhover, Anza's Head of Research, stated at Solana Accelerate that the new consensus mechanism will significantly reduce transaction finality time from the current 12.8 seconds to 150 milliseconds. Alpenglow has completed prototype testing and is expected to deploy on the testnet by mid-2025, with mainnet deployment anticipated later in the year following approval through Solana Improvement Documents (SIMD). Compared to the current Solana mainnet, Alpenglow simplifies architecture and optimizes data propagation efficiency, making it suitable for high-frequency trading and real-time payments.
Votor, a core component of Alpenglow, will replace TowerBFT by handling consensus logic. It operates through direct communication rather than the current node gossip model, using peer-to-peer communication and dynamic grouping strategies based on stake weight or geographical location. This reduces redundant message transmission and network latency.
Votor introduces a tiered stake voting mechanism: if a block receives over 80% stake support in the first round, it is notarized immediately; if support is between 60% and 80%, a second round of rapid confirmation is initiated. Nodes can skip voting if block delay or risk is detected, preventing resource wastage. Overall, when the validator threshold is below 60%, latency can be controlled to around 100 milliseconds.
Rotor focuses on improving block propagation efficiency and network resource allocation by integrating Turbine sharding technology. It replaces the traditional multi-layer relay model with a single-layer relay node architecture, splitting block data into lightweight shards and dynamically optimizing transmission paths, significantly reducing network complexity and transmission delay.
Rotor also introduces an adaptive propagation algorithm that monitors network status in real-time and switches congested paths, combining lightweight data verification to reduce computational overhead, greatly enhancing propagation speed and fault tolerance. Performance-wise, Rotor compresses block propagation delay to milliseconds, supporting Solana's goal of achieving 50,000 TPS, meeting the demands of DeFi clearing and real-time payment scenarios.
Overall, the Alpenglow protocol removes the PoH mechanism, reducing chain-wide operational risk and simplifying architecture. By replacing Tower BFT consensus with Votor and using stake-driven 1-2 round voting, it achieves block finality within 100-150 milliseconds without relying on optimistic confirmation. Rotor optimizes Turbine sharding with a single-layer relay system, enhancing propagation efficiency to the physical network latency limit, with the main bottleneck being underlying network transmission speed. The system's resilience is significantly enhanced, capable of withstanding 20% malicious nodes and 20% stake offline scenarios, improving attack resistance and fault tolerance. Ultimately, Alpenglow compresses transaction finality to milliseconds, providing foundational support for high-frequency trading, real-time payments, and large-scale on-chain applications.
