Computingpowertoken

Analysis of a novel blockchain proof-of-work protocol using analog Hamiltonian optimizers like quantum annealers and gain-dissipative simulators to enhance decentralization and transaction speed.

Analysis of the LooPIN PinFi protocol, a novel decentralized framework for computing resource coordination, pricing, and liquidity using dissipative pools.

Research on optimizing LLM inference by splitting prompt computation and token generation phases onto separate hardware for improved throughput, cost, and power efficiency.

Analysis of a novel proof-of-work blockchain incentive scheme using a DAG structure to guarantee protocol adherence as the optimal selfish mining strategy.

Analysis of a decentralized computing algorithm (dRAP) using multi-agent systems for dynamic task scheduling and resource allocation in distributed grids, outperforming FIFO.

Analysis of the Optical Proof of Work (oPoW) paper proposing a novel, energy-efficient mining algorithm using silicon photonics to replace traditional electricity-intensive Hashcash.

Analysis of the Optical Proof of Work (oPoW) proposal, a novel cryptocurrency mining algorithm shifting cost from electricity (OPEX) to hardware (CAPEX) using silicon photonics.

Analysis of a novel parallel proof-of-work blockchain protocol offering concrete security bounds, faster finality, and robustness against double-spending attacks.

Analysis of a novel PoW protocol using DAG-structured votes and targeted reward discounting to improve consistency, throughput, latency, and attack resilience compared to Bitcoin and Tailstorm.

An empirical study on reducing the storage footprint of PoW blockchains like Bitcoin, exploring client-side strategies without protocol modifications.

A novel paradigm using distributed HPC data centers to stabilize power grids, reduce renewable curtailment, and optimize AI workload scheduling through grid-aware placement.