Title : NeuroWave WhisperNet: A conceptual study of non-contact neural electromagnetic communication
Abstract:
In critical environments such as emergency response and high-risk operations, communication reliability is limited by the dependence on physical electronic devices that may fail, be detected, or be disrupted. This paper presents NeuroWave WhisperNet, a conceptual and theoretical exploration of non-contact communication approaches based on the electromagnetic (EM) activity generated by the human brain. Neural processes produce extremely weak electromagnetic fields that can be measured non-invasively under controlled conditions. Motivated by recent studies on remote and non-contact detection of neural EM signals, this work examines whether such fields could, in principle, enable selective electromagnetic coupling between an external transmitter and neural activity. A hypothetical framework is outlined to explore identity-linked signal interaction while remaining within established physical and biological safety limits. This study does not claim practical realization. Instead, it focuses on identifying fundamental challenges, including signal attenuation, noise dominance, spatial resolution limits, coupling efficiency, and ethical considerations. By framing these constraints, the work aims to stimulate 2 interdisciplinary discussion at the intersection of electromagnetism, neuroscience, and signal processing. NeuroWave WhisperNet is proposed as a future research direction, encouraging further theoretical modeling and experimental validation of non-contact neural communication paradigms.
