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30 results on '"Sokolich, Max"'

1. Model Predictive Control for Magnetically-Actuated Cellbots

Author

Kermanshah, Mehdi, Beaver, Logan E., Sokolich, Max, Kirmizitas, Fatma Ceren, Das, Sambeeta, Tron, Roberto, Weiss, Ron, and Belta, Calin

Subjects
Computer Science - Robotics
Abstract

This paper presents a control framework for magnetically actuated cellbots, which combines Model Predictive Control (MPC) with Gaussian Processes (GPs) as a disturbance estimator for precise trajectory tracking. To address the challenges posed by unmodeled dynamics, we integrate data-driven modeling with model-based control to accurately track desired trajectories using relatively small data. To the best of our knowledge, this is the first work to integrate data-driven modeling with model-based control for the magnetic actuation of cellbots. The GP effectively learns and predicts unmodeled disturbances, providing uncertainty bounds as well. We validate our method through experiments with cellbots, demonstrating improved trajectory tracking accuracy.

Published
2024

3. Learning a Tracking Controller for Rolling $\mu$bots

Author

Beaver, Logan E, Sokolich, Max, Alsalehi, Suhail, Weiss, Ron, Das, Sambeeta, and Belta, Calin

Subjects
Computer Science - Robotics
Abstract

Micron-scale robots ($\mu$bots) have recently shown great promise for emerging medical applications. Accurate controlling $\mu$bots, while critical to their successful deployment, is challenging. In this work, we consider the problem of tracking a reference trajectory using a $\mu$bot in the presence of disturbances and uncertainty. The disturbances primarily come from Brownian motion and other environmental phenomena, while the uncertainty originates from errors in the model parameters. We model the $\mu$bot as an uncertain unicycle that is controlled by a global magnetic field. To compensate for disturbances and uncertainties, we develop a nonlinear mismatch controller. We define the model mismatch error as the difference between our model's predicted velocity and the actual velocity of the $\mu$bot. We employ a Gaussian Process to learn the model mismatch error as a function of the applied control input. Then we use a least-squares minimization to select a control action that minimizes the difference between the actual velocity of the $\mu$bot and a reference velocity. We demonstrate the online performance of our joint learning and control algorithm in simulation, where our approach accurately learns the model mismatch and improves tracking performance. We also validate our approach in an experiment and show that certain error metrics are reduced by up to $40\%$., Comment: 8 pages, 9 figures

Published
2022

4. Closed-loop Control of Catalytic Janus Microrobots

Author

Sokolich, Max, Rivas, David, Shah, Zameer Hussain, and Das, Sambeeta

Subjects
Computer Science - Robotics, Physics - Chemical Physics
Abstract

We report a closed-loop control system for paramagnetic catalytically self-propelled Janus microrobots. We achieve this control by employing electromagnetic coils that direct the magnetic field in a desired orientation to steer the microrobots. The microrobots move due to the catalytic decomposition of hydrogen peroxide, during which they align themselves to the magnetic torques applied to them. Because the angle between their direction of motion and their magnetic orientation is a priori unknown, an algorithm is used to determine this angular offset and adjust the magnetic field appropriately. The microrobots are located using real-time particle tracking that integrates with a video camera. A target location or desired trajectory can be drawn by the user for the microrobots to follow., Comment: micro-robots, magnetic-control, closed-loop, computer-vision

Published
2022

5. ModMag: A Modular Magnetic Micro-Robotic Manipulation Device

Author

Sokolich, Max, Rivas, David, Duey, Markos, Borsykowsky, Daniel, and Das, Sambeeta

Subjects
Computer Science - Robotics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Electromagnetic systems have been used extensively for the control magnetically actuated objects, such as in microrheology and microrobotics research. Therefore, optimizing the design of such systems is highly desired. Some of the features that are lacking in most current designs are compactness, portability, and versatility. Portability is especially relevant for biomedical applications in which in vivo or in vitro testing may be conducted in locations away from the laboratory microscope. This document describes the design, fabrication and implementation of a compact, low cost, versatile, and user friendly device (the ModMag) capable of controlling multiple electromagnetic setups, including a two-dimensional 4-coil traditional configuration, a 3-dimensional Helmholtz configuration, and a 3-dimensional magnetic tweezer configuration. All electronics and circuitry for powering the systems is contained in a compact 10"x6"x3" system which includes a 10" touchscreen. A graphical user interface provides additional ease of use. The system can also be controlled remotely, allowing for more flexibility and the ability to interface with other software running on the remote computer such as propriety camera software. Aside from the software and circuitry, we also describe the design of the electromagnetic coil setups and provide examples of the use of the ModMag in experiments.

Published
2022

6. Dynamics and Control of Bubble-Propelled Microrobots

Author

Rivas, David P., Sokolich, Max, Muller, Harrison, and Das, Sambeeta

Subjects
Physics - Applied Physics, Electrical Engineering and Systems Science - Systems and Control
Abstract

Having the advantage of being relatively fast and powerful, as well as readily fabricated, spherical bubble-propelled microrobots are particularly well suited for applications such as cargo delivery, micromanipulation, and biological or environmental remediation. However, there have been limited examples of control and manipulation with these microrobots and few studies on their dynamics. Here we investigate the bubble formation and dynamics of both hemispherically coated Janus microrobots as well as GLAD "patchy" microrobots which not only provide for an interesting comparison, but also exhibit useful properties in their own right. Specifically, we find that the patchy microrobots have a tendency to produce smaller bubbles and undergo smoother motion, properties that are beneficial for applications such as precise micro-manipulation, for example. We demonstrate manipulation and assemble of passive spheres on a substrate as well as at an air-liquid interface. We also characterize the propulsion and bubble formation of both types of microrobots and find that previously proposed theories insufficiently describe their motion and bubble bursting mechanism. Additionally, we observe that the microrobots, which reside at the air-liquid interface, demonstrate positive gravitaxis towards the droplet edges which we attribute to a torque resulting from opposing downward and buoyant forces on the microrobot.

Published
2022

9. Control of Microrobots Using Model Predictive Control and Gaussian Processes for Disturbance Estimation

Author

Kermanshah, Mehdi, Beaver, Logan E., Sokolich, Max, Das, Sambeeta, Weiss, Ron, Tron, Roberto, Belta, Calin, Kermanshah, Mehdi, Beaver, Logan E., Sokolich, Max, Das, Sambeeta, Weiss, Ron, Tron, Roberto, and Belta, Calin

Abstract

This paper presents a control framework for magnetically actuated micron-scale robots ($\mu$bots) designed to mitigate disturbances and improve trajectory tracking. To address the challenges posed by unmodeled dynamics and environmental variability, we combine data-driven modeling with model-based control to accurately track desired trajectories using a relatively small amount of data. The system is represented with a simple linear model, and Gaussian Processes (GP) are employed to capture and estimate disturbances. This disturbance-enhanced model is then integrated into a Model Predictive Controller (MPC). Our approach demonstrates promising performance in both simulation and experimental setups, showcasing its potential for precise and reliable microrobot control in complex environments.

Published
2024

13. Rolling Helical Microrobots for Cell Patterning

Author

Yang, Yanda, primary, Kirmizitas, Fatma Ceren, additional, Sokolich, Max, additional, Valencia, Alejandra, additional, Rivas, David, additional, Karakan, M. Çağatay, additional, White, Alice E., additional, Malikopoulos, Andreas A., additional, and Das, Sambeeta, additional

Published
2023
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15. Programmable Modular Acoustic Microrobots

Author

Cherukumilli, Subrahmanyam, primary, Kirmizitas, Fatma Ceren, additional, Sokolich, Max, additional, Valencia, Alejandra, additional, Karakan, M. Çağatay, additional, White, Alice E., additional, Malikopoulos, Andreas A., additional, and Das, Sambeeta, additional

Published
2023
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18. Fabrication of three-lobed magnetic microrobots for cell transportation.

Author

Shah, Zameer Hussain, Sokolich, Max, Mallick, Sudipta, Rivas, David, and Das, Sambeeta

Abstract

Mobile microrobots have the potential to transform medical treatments based on therapeutic delivery. Specifically, microrobots are promising candidates for cell transportation in cell-based therapies. Despite recent progress in cellular manipulation by microrobots, there is a significant need to design and fabricate microrobots to advance the field further. In this work, we present a facile approach to manufacturing three-lobed microrobots by a bench-top procedure. The microrobots are actuated by a harmless magnetic field which makes them biofriendly. Chemically, these microrobots are made of organosilica. The microrobots showed equally good control in both the open-loop and closed-loop settings. The three-lobed microrobots have two modes of motion during the open-loop control experiments. We employed these two modes for single-cell transportation. Our results show that the three-lobed microbots are very promising for cell transportation in a fluid. [ABSTRACT FROM AUTHOR]

Published
2023
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23. Learning for Control of Rolling ubots

Author

Beaver, Logan E, Sokolich, Max, Alsalehi, Suhail, Weiss, Ron, Das, Sambeeta, and Belta, Calin

Subjects
FOS: Computer and information sciences, Computer Science - Robotics, Robotics (cs.RO)
Abstract

Micron-scale robots (ubots) have recently shown great promise for emerging medical applications, and accurate control of ubots is a critical next step to deploying them in real systems. In this work, we develop the idea of a nonlinear mismatch controller to compensate for the mismatch between the disturbed unicycle model of a rolling ubot and trajectory data collected during an experiment. We exploit the differential flatness property of the rolling ubot model to generate a mapping from the desired state trajectory to nominal control actions. Due to model mismatch and parameter estimation error, the nominal control actions will not exactly reproduce the desired state trajectory. We employ a Gaussian Process (GP) to learn the model mismatch as a function of the desired control actions, and correct the nominal control actions using a least-squares optimization. We demonstrate the performance of our online learning algorithm in simulation, where we show that the model mismatch makes some desired states unreachable. Finally, we validate our approach in an experiment and show that the error metrics are reduced by up to 40%., Comment: 12 pages, 6 figures

Published
2022
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24. Learning a Tracking Controller for Rolling μ bots.

Author

Beaver LE, Sokolich M, Alsalehi S, Weiss R, Das S, and Belta C

Abstract

Micron-scale robots ( μ bots) have recently shown great promise for emerging medical applications. Accurate control of μ bots, while critical to their successful deployment, is challenging. In this work, we consider the problem of tracking a reference trajectory using a μ bot in the presence of disturbances and uncertainty. The disturbances primarily come from Brownian motion and other environmental phenomena, while the uncertainty originates from errors in the model parameters. We model the μ bot as an uncertain unicycle that is controlled by a global magnetic field. To compensate for disturbances and uncertainties, we develop a nonlinear mismatch controller. We define the model mismatch error as the difference between our model's predicted velocity and the actual velocity of the μ bot. We employ a Gaussian Process to learn the model mismatch error as a function of the applied control input. Then we use a least-squares minimization to select a control action that minimizes the difference between the actual velocity of the μ bot and a reference velocity. We demonstrate the online performance of our joint learning and control algorithm in simulation, where our approach accurately learns the model mismatch and improves tracking performance. We also validate our approach in an experiment and show that certain error metrics are reduced by up to 40%.

Published
2024
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25. Closed-loop Control for a Heterogeneous Group of Magnetically-actuated Microrobots.

Author

Beaver LE, Shah ZH, Sokolich M, Yilmaz AE, Yang Y, Belta C, and Das S

Abstract

The development of magnetically-actuated micro-robots is of great interest for emerging medical applications due to their inherent safety, low cost to manufacture, and flexibility. In many practical applications, precise control over the motion of the microrobots is a strong requirement. In these contexts, closed-loop control is a practical tool to adjust the microrobots' control inputs in real time. In this work, we describe a process to quickly fabricate a large number of heterogeneous microrobots using colloidal synthesis. We simultaneously develop a closed-loop control law that drives the microrobots to a desired formation in the plane. In addition, we prove that heterogeneity in the microrobot dynamics is necessary to generate arbitrary formations. Finally, using experimental data, we show in simulation that N = 4 microrobots can be driven to any arbitrary formation using our control law.

Published
2023
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26. Targeted Vibration-Induced Necrosis in Liver Cancer Cells using Paramagnetic Microrobots.

Author

Mallick S, Sokolich M, Rivas D, and Das S

Abstract

Therapeutic delivery of anti-cancer drugs is a major goal of modern medicine. However, developing methods to target cancer cells for more effective treatment and reduced side effects is a significant ongoing challenge. Microrobots have recently been studied for their ability to navigate difficult-to-reach regions in the human body to deliver therapeutics for microscopically localized interventions. Using microrobots for targeted and local therapy therefore, is a promising revolutionary treatment method. In this study, magnetic microrobots were used to target and kill cancer cells via localized magnetic oscillations, resulting in magnetolysis of the cancer cells. The magnetic microrobots were selectively moved to Hepatocarcinoma cells (HepG2 cells) using a custom magnetic system which applied rotating magnetic fields. After internalization of the microrobots by the cancer cells, magnetic oscillation of varying dosages was applied, resulting in cell death.

Published
2023
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27. Rolling Helical Microrobots for Cell Patterning.

Author

Yang Y, Kirmizitas FC, Sokolich M, Valencia A, Rivas D, Karakan MÇ, White AE, Malikopoulos AA, and Das S

Abstract

Microrobots, untethered miniature devices capable of performing tasks at the microscale, have gained significant attention in the fields of robotics and biomedicine. These devices hold immense potential for various industrial and scientific applications, including targeted drug delivery and cell manipulation. In this study, we present a novel magnetic rolling helical microrobot specifically designed for bio-compatible cell patterning. Our microrobot incorporates both open-loop and closed-loop control mechanisms, providing flexible, precise, and rapid control for various applications. Through experiments, we demonstrate the microrobot's ability to manipulate cells by pushing them while rolling and arranging cells into desired patterns. This result is particularly significant as it has implications for diverse biological applications such as tissue engineering and organoid development. Moreover, we showcase the effectiveness of our microrobot in a closed-loop control system, where it successfully follows a predetermined path from an origin to a destination. The combination of cellular manipulation capabilities and trajectory-tracking performance underlines the versatility and potential of our magnetic rolling helical microrobot. The ability to control and navigate the microrobot with high precision opens up new possibilities for advanced biomedical applications. These findings contribute to the growing body of knowledge in microbotics and pave the way for further research and development in the field.

Published
2023
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28. Programmable Modular Acoustic Microrobots.

Author

Cherukumilli S, Kirmizitas FC, Sokolich M, Valencia A, Karakan MÇ, White AE, Malikopoulos AA, and Das S

Abstract

Microrobots have emerged as promising tools for biomedical and in vivo applications, leveraging their untethered actuation capabilities and miniature size. Despite extensive research on diversifying multi-actuation modes for single types of robots, these tiny machines tend to have limited versatility while navigating different environments or performing specific tasks. To overcome such limitations, self-assembly microstructures with on-demand reconfiguration capabilities have gained recent attention as the future of biocompatible microrobotics, as they can address drug delivery, microsurgery, and organoid development processes. Reversible modular reconfiguration structures require specific arrangements of particles that can assume several shapes when external fields are applied. We show how magnetic interaction can be used to assemble cylindrical microrobots into modular microstructures with different shapes. The motion actuation of the formed microstructure happens due to an external acoustic field, which generates responsive forces in the air bubbles trapped in the inner cavity of the robots. An external magnetic field can also steer these structures. We illustrate these capabilities by assembling the robots into different shapes that can swim and be steered, showing the potential to perform biomedical applications. Furthermore, we confirm the biocompatibility of the cylindrical microrobot used as the building blocks of our microstructure. Exposing Chinese Hamster Ovary cells to our microrobots for 24 hours demonstrates cell viability when in contact with the microrobot.

Published
2023
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29. Closed Loop Control of Bubble-Propelled Microrobots.

Author

Yang Y, Rivas D, Sokolich M, and Das S

Abstract

Bubble-propelled microrobots have an advantage of relatively swift movement compared to most other types of microrobots, which makes them well suited for applications such as micromanipulation or movement in flows, but their high speed also poses challenges in precisely controlling their motion. This study proposes automated control of the microrobots using visual feedback and steering with uniform magnetic fields to constrain the microrobot's moving direction. The implementation of a closed-loop control mechanism ensures precise autonomous navigation along prescribed trajectories. Experimental results demonstrate that this approach achieves satisfactory tracking performance, with an average error of 6. 7 μ m for a microrobot with a diameter of 24 μ m.

Published
2023
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30. Cellular Manipulation Using Rolling Microrobots.

Author

Rivas D, Mallick S, Sokolich M, and Das S

Abstract

Many biomedical applications, such as targeted drug delivery or cell manipulation, are well suited for the deployment of microrobots, untethered devices that are capable of carrying out tasks at the microscale. One biocompatible means of driving microrobots relies on magnetic actuation. In particular, microrobots driven using rotating fields rather than magnetic field gradients are especially practical for real-word applications. Many biological applications involve enclosed environments, such as blood vessels, in which surfaces are abundant, therefore, surface rolling is a particularly pertinent method of transportation. In this paper we demonstrate manipulation and transportation of cells using two types of magnetically driven rolling microrobots. We find that the microrobots are able to manipulate the cells by physically pushing or by first adhering to the cells and then carrying them. Microrobots spinning at high rates also can transport cells via the induced fluid flows.

Published
2022
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