Optimized Brain-Computer Interface For Smart Environments: Employing Transfer Learning And Edge AI For Iot Control
Keywords:
Brain-Computer Interface (BCI), Internet of Things (IoT) Control, Smart Environments, Transfer Learning, Edge AI, Real-Time Processing, Neural Signal Classification, Low Latency, Resource Efficiency, Assistive TechnologyAbstract
The quick evolution of Brain-Computer Interfaces (BCIs) has opened up new horizons for IoT device control in
smart spaces. Nevertheless, conventional BCI systems are plagued with high latency, computational inefficiency,
and limited resources, making real-time processing challenging. In this research, an optimized BCI system based
on Transfer Learning and Edge AI is proposed to improve neural signal classification and facilitate real-time IoT
control. Transfer Learning utilizes pre-trained neural networks to classify EEG signals with little training data,
while Edge AI provides low-latency processing by performing computations on edge devices directly, minimizing
cloud-based model dependence. Experimental results demonstrate that the proposed framework has 92.0%
classification accuracy, much higher than traditional CNNs (82.1%), and decreases latency from 35.0 ms to 24.0
ms and power consumption from 25.0 MJ/inference to 18.0 MJ/inference. These advancements showcase the
efficacy of the framework in assistive technology, home automation, and industrial control systems. Upcoming
advancements are federated learning for privacy-preserving model updates, optimizations of deep neural
networks, and real-world deployments across varied smart environments. This research showcases the promise
of Transfer Learning and Edge AI in creating scalable, efficient, and real-time BCI applications for smart humanmachine
interaction.
