Control methodologies for a heterogeneous group of untethered magnetic micro-robots

Abstract

In this work, we develop methods for controlling multiple untethered magnetic micro-robots (Mag-µBots) without the need for a specialized substrate. We investigate Mag-µBots that are geometrically and magnetically designed to respond uniquely to the same input magnetic fields. Designs include: (1) geometrically similar Mag-µBots with different values of magnetization; (2) geometrically dissimilar Mag-µBots with similar magnetization; and (3) geometrically dissimilar Mag-µBots with dissimilar magnetization. The responses of both magnetically hard and soft Mag-µBots are investigated. By controlling the input magnetic fields, individual and sub-groups of Mag-µBots are able to locomote in a parallel fashion. Specifically, the magnitude and frequency of the imposed driving magnetic fields are used as selection methods among the Mag-µBots. Various methods for accomplishing motion discrimination are discussed, modeled, and tested. It is found that while fully decoupled control is not possible with this method, parallel actuation of sub-groups of Mag-µBots is possible and controllable.

Keywords

Micro/nano robots micro-actuation wireless magnetic actuation multi-agent control

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