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Kinematic Model of a Magnetic-Microrobot Swarm in a Rotating Magnetic Dipole Field

BhanuKiran Chaluvadi, Kristen M. Stewart, Adam J. Sperry, Henry Fu, Jake J. Abbott

2020IEEE Robotics and Automation Letters32 citationsDOI

Abstract

This letter describes how a rotating magnetic dipole field will manipulate the location and shape of a swarm of magnetic microrobots, specifically microrobots that convert rotation into forward propulsion, such as helical swimmers and screws. The analysis assumes a swarm that can be described by a centroid and a covariance matrix, with the swarm comprising an arbitrary and unknown number of homogenous microrobots. The result of this letter is a kinematic model that can be used as an apriori model for motion planners and feedback control systems. Because the model is fully three-dimensional and does not require any localization information beyond what could realistically be determined from medical images, the method has potential for in vivo medical applications. The model is experimentally verified using magnetic screws moving through a soft-tissue phantom, propelled by a rotating spherical permanent magnet.

Topics & Concepts

Swarm behaviourKinematicsCentroidRotation (mathematics)Magnetic fieldRotation matrixImaging phantomMagnetic dipoleMagnetComputer sciencePhysicsPropulsionDipoleForce between magnetsControl theory (sociology)Classical mechanicsArtificial intelligenceMechanical engineeringEngineeringMagnetic energyOpticsMagnetizationThermodynamicsControl (management)Quantum mechanicsMicro and Nano RoboticsModular Robots and Swarm IntelligenceCerebrospinal fluid and hydrocephalus
Kinematic Model of a Magnetic-Microrobot Swarm in a Rotating Magnetic Dipole Field | Litcius