Motion Planning for Multiple Heterogeneous Magnetic Robots Under Global Input

Magnetism provides an untethered actuation mechanism and an alternative way to actuate robots. Using a magnetic field we can control the motion of robots embedded with magnets. This scales down the size of the robots dramatically such that they can be used in applications like drug delivery, sample...

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Bibliographic Details
Published inIEEE transactions on robotics Vol. 40; pp. 697 - 713
Main Authors Asadi, Farshid, Hurmuzlu, Yildirim
Format Journal Article
LanguageEnglish
Published New York IEEE 2024
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
Subjects
Actuation
Algorithms
Collision avoidance
Legged locomotion
Magnetic
Magnetic fields
Magnetic hysteresis
Magnetic resonance
Magnetosphere
Magnets
Micromanipulation
millirobot
Motion planning
Multiple robots
Planning
Robot control
Robot dynamics
Robots
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Summary:Magnetism provides an untethered actuation mechanism and an alternative way to actuate robots. Using a magnetic field we can control the motion of robots embedded with magnets. This scales down the size of the robots dramatically such that they can be used in applications like drug delivery, sample collection, micromanipulation, and noninvasive procedures. Despite all advantages and potentials, magnetic actuation has one major drawback. Due to the similar interaction between the magnetic field and the embedded magnets in multirobot systems, controlling the robots independently is challenging. Using heterogeneous magnetic robots is one way to overcome the independent control challenge. Here, motion planning for multiple magnetic robots that move in parallel directions at different speeds in response to a global input is addressed in the absence of obstacles in a polygonal workspace. Through controllability analysis, it will be shown that having <inline-formula><tex-math notation="LaTeX">n</tex-math></inline-formula> linearly independent heterogeneous responses to the global input, called Modes of Motion here, enables independent position control of <inline-formula><tex-math notation="LaTeX">n</tex-math></inline-formula> robots in the system. Further, a procedure to have a potentially feasible sequence of motion is presented and intrarobot collision free directions of movement are formulated mathematically. These procedures are then used in the proposed optimization-based motion planning algorithm. Also, an innovative millimeter scale multimode magnetic pivot walker design is introduced and used for benchmarking in the experiments. Finally, the motion planning algorithm is used in multiple experiments, using our innovative pivot walkers, and its efficacy is illustrated.
ISSN:1552-3098
1941-0468
DOI:10.1109/TRO.2023.3339529