FBLearn:区块链联合学习的去中心化平台

IF 2.6 3区 工程技术 Q2 COMPUTER SCIENCE, INFORMATION SYSTEMS Electronics Pub Date : 2024-09-16 DOI:10.3390/electronics13183672
Daniel Djolev, Milena Lazarova, Ognyan Nakov
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引用次数: 0

摘要

近年来,技术的飞速发展推动区块链和人工智能(AI)在数字产业中发挥着重要作用,各自都有独特的应用。区块链因其安全、透明的数据存储而备受认可,而人工智能则是数据分析和决策制定的强大工具,两者的共同特点使其具有互补性。与此同时,机器学习已成为一种强大而有影响力的技术,被许多公司采用来解决棘手的技术问题。日常运营中产生和使用的大量数据为这一技术的采用提供了动力。区块链和人工智能的一个有趣交叉点出现在联合学习领域,这是一种分布式方法,允许多方在不集中数据的情况下合作训练一个共享模型。本文介绍了在区块链中实施联合学习的去中心化平台 FBLearn,它使我们能够利用联合学习的优势,而无需交换敏感的客户或产品数据,从而促进无信任协作。由于在分布式模型训练中引入了去中心化的区块链网络来取代中心化服务器,因此必须利用全局模型聚合方法。本文研究了几种基于本地模型平均值和集合的模型聚合技术,使用本地或全球分布式验证数据进行模型评估。本文基于 FBLearn 平台的两个使用案例对建议的聚合方法进行了实验评估:使用随机森林分类器的信用风险评分和使用逻辑回归的信用卡欺诈检测。实验结果证实,所建议的基于本地训练数据质量的自适应权重计算和集合技术提高了全局模型的鲁棒性。性能评估指标和 ROC 曲线证明,集合策略成功地隔离了低质量模型对最终模型的影响。拟议系统的性能优于使用独立数据集创建的模型,这突出表明该系统具有加强协作的潜力,而且与每个本地模型相比,它还能提高最终全局模型的准确性。整合区块链和联合学习为数据协作提供了一种前瞻性方法,同时解决了隐私问题。
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FBLearn: Decentralized Platform for Federated Learning on Blockchain
In recent years, rapid technological advancements have propelled blockchain and artificial intelligence (AI) into prominent roles within the digital industry, each having unique applications. Blockchain, recognized for its secure and transparent data storage, and AI, a powerful tool for data analysis and decision making, exhibit common features that render them complementary. At the same time, machine learning has become a robust and influential technology, adopted by many companies to address non-trivial technical problems. This adoption is fueled by the vast amounts of data generated and utilized in daily operations. An intriguing intersection of blockchain and AI occurs in the realm of federated learning, a distributed approach allowing multiple parties to collaboratively train a shared model without centralizing data. This paper presents a decentralized platform FBLearn for the implementation of federated learning in blockchain, which enables us to harness the benefits of federated learning without the necessity of exchanging sensitive customer or product data, thereby fostering trustless collaboration. As the decentralized blockchain network is introduced in the distributed model training to replace the centralized server, global model aggregation approaches have to be utilized. This paper investigates several techniques for model aggregation based on the local model average and ensemble using either local or globally distributed validation data for model evaluation. The suggested aggregation approaches are experimentally evaluated based on two use cases of the FBLearn platform: credit risk scoring using a random forest classifier and credit card fraud detection using a logistic regression. The experimental results confirm that the suggested adaptive weight calculation and ensemble techniques based on the quality of local training data enhance the robustness of the global model. The performance evaluation metrics and ROC curves prove that the aggregation strategies successfully isolate the influence of the low-quality models on the final model. The proposed system’s ability to outperform models created with separate datasets underscores its potential to enhance collaborative efforts and to improve the accuracy of the final global model compared to each of the local models. Integrating blockchain and federated learning presents a forward-looking approach to data collaboration while addressing privacy concerns.
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来源期刊
Electronics
Electronics Computer Science-Computer Networks and Communications
CiteScore
1.10
自引率
10.30%
发文量
3515
审稿时长
16.71 days
期刊介绍: Electronics (ISSN 2079-9292; CODEN: ELECGJ) is an international, open access journal on the science of electronics and its applications published quarterly online by MDPI.
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