Mobile Edge Computing (MEC) has been a promising paradigm for communicating and edge processing of data on the move. We aim to employ Federated Learning (FL) and prominent features of blockchain into MEC architecture such as connected autonomous vehicles to enable complete decentralization, immutability, and rewarding mechanisms simultaneously. FL is advantageous for mobile devices with constrained connectivity since it requires model updates to be delivered to a central point instead of substantial amounts of data communication. For instance, FL in autonomous, connected vehicles can increase data diversity and allow model customization, and predictions are possible even when the vehicles are not connected (by exploiting their local models) for short times. However, existing synchronous FL and Blockchain incur extremely high communication costs due to mobility-induced impairments and do not apply directly to MEC networks. We propose a fully asynchronous Blockchained Federated Learning (BFL) framework referred to as BFL-MEC, in which the mobile clients and their models evolve independently yet guarantee stability in the global learning process. More importantly, we employ post-quantum secure features over BFL-MEC to verify the client's identity and defend against malicious attacks. All of our design assumptions and results are evaluated with extensive simulations.
翻译:移动边缘计算(MEC)是移动数据通信和边端处理的一个很有希望的范例,我们打算利用联邦学习(FL)和封闭链的显著特征进入MEC结构,例如连接的自主车辆,以便能够同时实现完全的权力下放、不移动和奖励机制;FL对连接受限的移动设备是有利的,因为它要求向一个中心点提供模型更新,而不是大量的数据通信;例如,自主、连接的车辆的FL可以增加数据多样性,允许模式定制,即使车辆没有连接(通过利用当地模型),也有可能在短期内作出预测;然而,由于移动导致的损伤,现有的同步的FL和阻链造成极高的通信费用,而且不直接适用于MEC网络;我们提议一个完全不固定的封闭链式联邦学习框架,称为BFL-MEC,其中移动客户及其模型可以独立地演变,同时又保证全球学习过程的稳定;更重要的是,我们利用BFLL-MEC的后方安全特征来核查客户的身份和恶意攻击的模拟结果。</s>