Magnetically actuated robots have proven effective in several applications, specifically in medicine. However, generating high actuating fields with a high degree of manipulability is still a challenge, especially when the application needs a large workspace to suitably cover a patient. The presented work discusses a novel approach for the control of magnetic field and field gradients using two robotically actuated permanent magnets. In this case, permanent magnets&\#x2014;relative to coil-based systems&\#x2014;have the advantage of larger field density without energy consumption. We demonstrate that collaborative manipulation of the two permanent magnets can introduce up to three additional Degrees of Freedom (DOFs) when compared to single permanent magnet approaches (five DOFs). We characterized the dual-arm system through the measurement of the fields and gradients and show accurate open-loop control with a 13.5&\#x0025; mean error. We then demonstrate how the magnetic DOFs can be employed in magnetomechanical manipulation, by controlling and measuring the wrench on two orthogonal magnets within the workspace, observing a maximum crosstalk of 6.1&\#x0025; and a mean error of 11.1&\#x0025;.
%0 Journal Article
%1 pittiglio2022collaborative
%A Pittiglio, Giovanni
%A Brockdorff, Michael
%A da Veiga, Tomas
%A Davy, Joshua
%A Chandler, James Henry
%A Valdastri, Pietro
%D 2022
%J IEEE Transactions on Robotics
%K Coils,Force actuation,medical and automation,magnetic control,Magnetic effects,Permanent imaging,Magnetic in magnets,Robot methods resonance robotics robots sensing separation,Magnetomechanical systems systems,Sensors,formal
%P 1--12,
%R 10.1109/TRO.2022.3209038
%T Collaborative Magnetic Manipulation via Two Robotically Actuated Permanent Magnets
%X Magnetically actuated robots have proven effective in several applications, specifically in medicine. However, generating high actuating fields with a high degree of manipulability is still a challenge, especially when the application needs a large workspace to suitably cover a patient. The presented work discusses a novel approach for the control of magnetic field and field gradients using two robotically actuated permanent magnets. In this case, permanent magnets&\#x2014;relative to coil-based systems&\#x2014;have the advantage of larger field density without energy consumption. We demonstrate that collaborative manipulation of the two permanent magnets can introduce up to three additional Degrees of Freedom (DOFs) when compared to single permanent magnet approaches (five DOFs). We characterized the dual-arm system through the measurement of the fields and gradients and show accurate open-loop control with a 13.5&\#x0025; mean error. We then demonstrate how the magnetic DOFs can be employed in magnetomechanical manipulation, by controlling and measuring the wrench on two orthogonal magnets within the workspace, observing a maximum crosstalk of 6.1&\#x0025; and a mean error of 11.1&\#x0025;.
@article{pittiglio2022collaborative,
abstract = {Magnetically actuated robots have proven effective in several applications, specifically in medicine. However, generating high actuating fields with a high degree of manipulability is still a challenge, especially when the application needs a large workspace to suitably cover a patient. The presented work discusses a novel approach for the control of magnetic field and field gradients using two robotically actuated permanent magnets. In this case, permanent magnets{\&}{\#}x2014;relative to coil-based systems{\&}{\#}x2014;have the advantage of larger field density without energy consumption. We demonstrate that collaborative manipulation of the two permanent magnets can introduce up to three additional Degrees of Freedom (DOFs) when compared to single permanent magnet approaches (five DOFs). We characterized the dual-arm system through the measurement of the fields and gradients and show accurate open-loop control with a 13.5{\&}{\#}x0025; mean error. We then demonstrate how the magnetic DOFs can be employed in magnetomechanical manipulation, by controlling and measuring the wrench on two orthogonal magnets within the workspace, observing a maximum crosstalk of 6.1{\&}{\#}x0025; and a mean error of 11.1{\&}{\#}x0025;.},
added-at = {2023-05-10T16:23:27.000+0200},
author = {Pittiglio, Giovanni and Brockdorff, Michael and da Veiga, Tomas and Davy, Joshua and Chandler, James Henry and Valdastri, Pietro},
biburl = {https://www.bibsonomy.org/bibtex/212c52f2492a2c9e4368a6f20a2cb36c0/sassw},
doi = {10.1109/TRO.2022.3209038},
interhash = {a7c6aed867b53fa107165647fefe57f8},
intrahash = {12c52f2492a2c9e4368a6f20a2cb36c0},
issn = {19410468},
journal = {IEEE Transactions on Robotics},
keywords = {Coils,Force actuation,medical and automation,magnetic control,Magnetic effects,Permanent imaging,Magnetic in magnets,Robot methods resonance robotics robots sensing separation,Magnetomechanical systems systems,Sensors,formal},
pages = {1--12,},
timestamp = {2023-05-10T16:23:27.000+0200},
title = {{Collaborative Magnetic Manipulation via Two Robotically Actuated Permanent Magnets}},
year = 2022
}