Title |
Blockchain-enabled: multi-layered security federated learning platform for preserving data privacy / |
Authors |
Mahmood, Zeba ; Jusas, Vacius |
DOI |
10.3390/electronics11101624 |
Full Text |
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Is Part of |
Electronics.. Basel : MDPI. 2022, vol. 11, iss. 10, art. no. 1624, p. 1-21.. ISSN 2079-9292 |
Keywords [eng] |
federated learning (FL) ; blockchain ; zero-lnowledge proofs (ZKPs) ; multi-layer security ; poisoning attacks ; convolutional neural network (CNN) |
Abstract [eng] |
Privacy and data security have become the new hot topic for regulators in recent years. As a result, Federated Learning (FL) (also called collaborative learning) has emerged as a new training paradigm that allows multiple, geographically distributed nodes to learn a Deep Learning (DL) model together without sharing their data. Blockchain is becoming a new trend as data protection and privacy are concerns in many sectors. Technology is leading the world and transforming into a global village where everything is accessible and transparent. We have presented a blockchain enabled security model using FL that can generate an enhanced DL model without sharing data and improve privacy through higher security and access rights to data. However, existing FL approaches also have unique security vulnerabilities that malicious actors can exploit and compromise the trained model. The FL method is compared to the other known approaches. Users are more likely to choose the latter option, i.e., providing local but private data to the server and using ML apps, performing ML operations on the devices without benefiting from other users’ data, and preventing direct access to raw data and local training of ML models. FL protects data privacy and reduces data transfer overhead by storing raw data on devices and combining locally computed model updates. We have investigated the feasibility of data and model poisoning attacks under a blockchain-enabled FL system built alongside the Ethereum network and the traditional FL system (without blockchain). This work fills a knowledge gap by proposing a transparent incentive mechanism that can encourage good behavior among participating decentralized nodes and avoid common problems and provides knowledge for the FL security literature by investigating current FL systems. |
Published |
Basel : MDPI |
Type |
Journal article |
Language |
English |
Publication date |
2022 |
CC license |
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