AI-Driven Smart Contract Optimization in Financial Derivatives
DOI:
https://doi.org/10.63345/sjaibt.v2.i2.304Keywords:
AI-driven optimization; smart contracts; financial derivatives; blockchain; decentralized finance; reinforcement learning; automated settlement; futures and options; contract efficiency; risk-adjusted DeFiAbstract
The integration of Artificial Intelligence (AI) into decentralized finance (DeFi) has triggered a paradigm shift in the automation and optimization of financial contracts, particularly within the domain of financial derivatives. Derivatives, including options, futures, swaps, and forwards, are among the most complex financial instruments, requiring accurate pricing, efficient settlement, and continuous risk monitoring. Smart contracts—self-executing agreements coded onto blockchain networks—have emerged as a transformative mechanism to automate these processes. However, conventional smart contracts in DeFi are constrained by inefficiencies in execution logic, gas costs, vulnerability to adversarial trading strategies, and limitations in adapting to real-time market fluctuations.
This manuscript investigates AI-driven optimization frameworks for smart contracts in derivatives markets, where machine learning algorithms, reinforcement learning agents, and predictive analytics are employed to dynamically enhance pricing mechanisms, counterparty risk management, and execution efficiency. The study builds on an extensive literature review of DeFi, AI-finance integration, and blockchain automation, proposing an AI-augmented smart contract architecture that enables adaptive fee structures, risk-adjusted margin calls, automated dispute resolution, and latency-sensitive derivatives clearing.
A simulation-based methodology was employed, where deep reinforcement learning models interacted with synthetic market data to optimize contract logic in futures and options markets deployed on Ethereum Virtual Machine (EVM)-compatible blockchains. Statistical evaluation revealed that AI-enhanced smart contracts demonstrated 25–40% improvement in transaction throughput, 18–25% reduction in gas costs, 30–35% enhancement in derivative pricing accuracy, and 50% reduction in settlement disputes compared to baseline blockchain contracts.
The results highlight that AI-driven optimization is not only feasible but essential for scaling derivatives trading in DeFi to institutional-grade levels. The paper concludes by discussing regulatory implications, computational limitations, adversarial AI threats, and the future trajectory of autonomous financial engineering.
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