Computational Intelligence and Deep Learning for Next-Generation
Edge-Enabled Industrial IoT
- URL: http://arxiv.org/abs/2110.14937v1
- Date: Thu, 28 Oct 2021 08:14:57 GMT
- Title: Computational Intelligence and Deep Learning for Next-Generation
Edge-Enabled Industrial IoT
- Authors: Shunpu Tang, Lunyuan Chen, Ke HeJunjuan Xia, Lisheng Fan, Arumugam
Nallanathan
- Abstract summary: We investigate how to deploy computational intelligence and deep learning (DL) in edge-enabled industrial IoT networks.
In this paper, we propose a novel multi-exit-based federated edge learning (ME-FEEL) framework.
In particular, the proposed ME-FEEL can achieve an accuracy gain up to 32.7% in the industrial IoT networks with the severely limited resources.
- Score: 51.68933585002123
- License: http://creativecommons.org/licenses/by/4.0/
- Abstract: In this paper, we investigate how to deploy computational intelligence and
deep learning (DL) in edge-enabled industrial IoT networks. In this system, the
IoT devices can collaboratively train a shared model without compromising data
privacy. However, due to limited resources in the industrial IoT networks,
including computational power, bandwidth, and channel state, it is challenging
for many devices to accomplish local training and upload weights to the edge
server in time. To address this issue, we propose a novel multi-exit-based
federated edge learning (ME-FEEL) framework, where the deep model can be
divided into several sub-models with different depths and output prediction
from the exit in the corresponding sub-model. In this way, the devices with
insufficient computational power can choose the earlier exits and avoid
training the complete model, which can help reduce computational latency and
enable devices to participate into aggregation as much as possible within a
latency threshold. Moreover, we propose a greedy approach-based exit selection
and bandwidth allocation algorithm to maximize the total number of exits in
each communication round. Simulation experiments are conducted on the classical
Fashion-MNIST dataset under a non-independent and identically distributed
(non-IID) setting, and it shows that the proposed strategy outperforms the
conventional FL. In particular, the proposed ME-FEEL can achieve an accuracy
gain up to 32.7% in the industrial IoT networks with the severely limited
resources.
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