An experimental study of the viscous properties of water vapour

Various dry electroencephalography (EEG) electrodes have been developed. Dry EEG electrodes need to be pressed onto the scalp; therefore, there is a tradeoff between keeping the contact impedance low and maintaining comfort. We propose an approach to solve this tradeoff through the printing of complex-shaped electrodes by using a stereolithography 3D printer. To show the feasibility of our approach, we fabricated electrodes that have flexible fingers (prongs) with springs. Although dry electrodes with flexible prongs have been proposed, a suitable spring constant has not been obtained. In this study, the spring constant of our electrodes was determined from a contact model between the electrodes and the scalp. The mechanical properties and reproductivity of the electrodes were found to be sufficient. Finally, we measured the alpha waves when a participant opened/closed his eyes by using our electrodes.

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Precise numerical simulations of electrodynamic tethers for an active debris removal system

Kawamoto

Makida

Sasaki

et al. 2006

Acta Astronautica

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Space debris capture by a joint compliance controlled robot

Nishida¹,

Yoshikawa²

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Shin-Ichiro Nishida

Space debris removal system using a small satellite

Strategy for capturing of a tumbling space debris

3D Printable Dry EEG Electrodes with Coiled-Spring Prongs

Precise numerical simulations of electrodynamic tethers for an active debris removal system

Space debris capture by a joint compliance controlled robot

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