Modeling and Estimation of Self-Phoretic Magnetic Janus Microrobot With Uncontrollable Inputs

David Folio; Antoine Ferreira

doi:10.1109/TCST.2021.3139192

Abstract

This study theoretically investigates the modeling of spherical catalytic self-phoretic magnetic Janus microrobot (MJR) evolving in uniform viscous flow. A 2-D state-space representation of the MJR is developed, exhibiting a state-dependent-coefficient (SDC) form. To evaluate the consistency of the modeling formalism, a dual Kalman filter (DKF) methodology is employed with respect to experimental results when unknown parameters or uncontrollable inputs are considered. In fact, the self-phoretic thrust mechanism and the magnetodynamics of the MJR are not well-known. SDC-DKF is implemented, and we find that there is good agreement between the dynamics computed from our theoretical predictions and the experimental observations in a wide range of model parameter variations.

Keywords: Dual Kalman filtering, estimation, Janus particle, Kalman filters, magnetic microrobot, mathematical models, modeling, propulsion, state-space representation

Funding

This work was supported by the French National Institute of Health and Medical Research (Inserm) “Plan Cancer” 2014–2019 program, Project: Microrobots Targeting Glioblastoma (MTG).

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CC BY 4.0

Copyright

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Citation

BibTeX citation:

@article{folio2022,
  author = {Folio, David and Ferreira, Antoine},
  publisher = {IEEE},
  title = {Modeling and {Estimation} of {Self-Phoretic} {Magnetic}
    {Janus} {Microrobot} {With} {Uncontrollable} {Inputs}},
  journal = {IEEE Transactions on Control Systems Technology},
  volume = {30},
  number = {6},
  pages = {2681-2688},
  date = {2022-11-01},
  url = {https://ieeexplore.ieee.org/document/9678101},
  doi = {10.1109/TCST.2021.3139192},
  issn = {1558-0865},
  langid = {en-US},
  abstract = {This study theoretically investigates the modeling of
    spherical catalytic self-phoretic magnetic Janus microrobot (MJR)
    evolving in uniform viscous flow. A 2-D state-space representation
    of the MJR is developed, exhibiting a state-dependent-coefficient
    (SDC) form. To evaluate the consistency of the modeling formalism, a
    dual Kalman filter (DKF) methodology is employed with respect to
    experimental results when unknown parameters or uncontrollable
    inputs are considered. In fact, the self-phoretic thrust mechanism
    and the magnetodynamics of the MJR are not well-known. SDC-DKF is
    implemented, and we find that there is good agreement between the
    dynamics computed from our theoretical predictions and the
    experimental observations in a wide range of model parameter
    variations.}
}

For attribution, please cite this work as:

Folio D. and Ferreira A., “Modeling and Estimation of Self-Phoretic Magnetic Janus Microrobot With Uncontrollable Inputs,” IEEE Trans. Control Syst. Technol., vol. 30, pp. 2681–2688, November 2022. [Online]. Available: https://ieeexplore.ieee.org/document/9678101