Remote Manipulation of Multiple Objects With Airflow Field Using Model-Based Learning Control

Artur Kopitca; Shahriar Haeri; Quan Zhou

doi:10.1109/TMECH.2025.3568856

Remote Manipulation of Multiple Objects With Airflow Field Using Model-Based Learning Control

Artur Kopitca, Shahriar Haeri, Quan Zhou^*

^*Corresponding author for this work

Research output: Contribution to journal › Article › Scientific › peer-review

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Abstract

Noncontact manipulation is a promising methodology in robotics, offering a wide range of scientific and industrial applications. Among the proposed approaches, airflow stands out for its ability to project across considerable distances and its flexibility in actuating objects of varying materials, sizes, and shapes. However, predicting airflow fields at a distance—and the motion of objects within them—remains notoriously challenging due to their nonlinear and stochastic nature. Here, we propose a model-based learning approach using a jet-induced airflow field for remote multi-object manipulation on a surface. Our approach incorporates an analytical model of the field, learned object dynamics, and a model-based controller. The model predicts an air velocity field over an infinite surface for a specified jet orientation, while the object dynamics are learned through a robust system identification algorithm. Using the model-based controller, we can automatically and remotely, at meter-scale distances, control the motion of single and multiple objects for different tasks, such as path-following, aggregating, and sorting.

Original language	English
Pages (from-to)	2871-2879
Number of pages	9
Journal	IEEE/ASME Transactions on Mechatronics
Volume	30
Issue number	4
DOIs	https://doi.org/10.1109/TMECH.2025.3568856
Publication status	Published - 2025
MoE publication type	A1 Journal article-refereed

Funding

Received 5 December 2024; revised 25 March 2025; accepted 6 May 2025. Date of publication 30 May 2025; date of current version 18 August 2025. Recommended by Technical Editor B. Chu and Senior Editor Z. Sun. This work was supported in part by the Academy of Finland under Grant 331149, and in part by the Aalto Doctoral School of Electrical Engineering. (Corresponding author: Quan Zhou.) The authors are with the Department of Electrical Engineering and Automation of Aalto University, 02150 Espoo, Finland (e-mail: [email protected]; [email protected]; [email protected]).

Keywords

Jet-induced airflow field
model predictive control
noncontact manipulation
system identification

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Cite this

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title = "Remote Manipulation of Multiple Objects With Airflow Field Using Model-Based Learning Control",

abstract = "Noncontact manipulation is a promising methodology in robotics, offering a wide range of scientific and industrial applications. Among the proposed approaches, airflow stands out for its ability to project across considerable distances and its flexibility in actuating objects of varying materials, sizes, and shapes. However, predicting airflow fields at a distance—and the motion of objects within them—remains notoriously challenging due to their nonlinear and stochastic nature. Here, we propose a model-based learning approach using a jet-induced airflow field for remote multi-object manipulation on a surface. Our approach incorporates an analytical model of the field, learned object dynamics, and a model-based controller. The model predicts an air velocity field over an infinite surface for a specified jet orientation, while the object dynamics are learned through a robust system identification algorithm. Using the model-based controller, we can automatically and remotely, at meter-scale distances, control the motion of single and multiple objects for different tasks, such as path-following, aggregating, and sorting.",

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PY - 2025

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N2 - Noncontact manipulation is a promising methodology in robotics, offering a wide range of scientific and industrial applications. Among the proposed approaches, airflow stands out for its ability to project across considerable distances and its flexibility in actuating objects of varying materials, sizes, and shapes. However, predicting airflow fields at a distance—and the motion of objects within them—remains notoriously challenging due to their nonlinear and stochastic nature. Here, we propose a model-based learning approach using a jet-induced airflow field for remote multi-object manipulation on a surface. Our approach incorporates an analytical model of the field, learned object dynamics, and a model-based controller. The model predicts an air velocity field over an infinite surface for a specified jet orientation, while the object dynamics are learned through a robust system identification algorithm. Using the model-based controller, we can automatically and remotely, at meter-scale distances, control the motion of single and multiple objects for different tasks, such as path-following, aggregating, and sorting.

AB - Noncontact manipulation is a promising methodology in robotics, offering a wide range of scientific and industrial applications. Among the proposed approaches, airflow stands out for its ability to project across considerable distances and its flexibility in actuating objects of varying materials, sizes, and shapes. However, predicting airflow fields at a distance—and the motion of objects within them—remains notoriously challenging due to their nonlinear and stochastic nature. Here, we propose a model-based learning approach using a jet-induced airflow field for remote multi-object manipulation on a surface. Our approach incorporates an analytical model of the field, learned object dynamics, and a model-based controller. The model predicts an air velocity field over an infinite surface for a specified jet orientation, while the object dynamics are learned through a robust system identification algorithm. Using the model-based controller, we can automatically and remotely, at meter-scale distances, control the motion of single and multiple objects for different tasks, such as path-following, aggregating, and sorting.

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Remote Manipulation of Multiple Objects With Airflow Field Using Model-Based Learning Control

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Remote Manipulation of Multiple Objects With Airflow Field Using Model-Based Learning Control

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RoboCelli: Robotic Magnetic Needle Characterization of Single Nanoparticle Uptake in Cells

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