Add to ORKGThe control of swarm systems is relatively well understood for simple robotic platforms at the macro scale. However, there are still several unanswered questions about how similar results can be achieved for microrobots. In this paper, we propose a modeling framework based on a dynamic model of magnetized self-propelling Janus microrobots under a global magnetic field. We verify our model experimentally and provide methods that can aim at accurately describing the behavior of microrobots while modeling their simultaneous control. The model can be generalized to other microrobotic platforms in low Reynolds number environments.Comment: 7 pages, 2 figure
330 pagesCollectives in nature demonstrate behaviors that extend far beyond the capabilities of any ...
A novel scalable strategy for open loop control of ferromagnetic microrobots on a plane using a scal...
Self-propelled particles are one prototype of synthetic active matter used to understand complex bio...
My PhD dissertation takes an innovative approach to using the fundamental tools of robotics and cont...
This thesis seeks to advance the field of microrobotics by leveraging Bayesian principles and comput...
Microscale robotics have numerous applications in engineering and the biomedical sciences, as the ma...
Tiny robots have many promising applications in medical treatment including targeted drug delivery, ...
We present a general solution for steering microroboticswarm by dynamic actuating fields. In our app...
In this paper, we have developed an approach for independent autonomous navigation of multiple micro...
Microrobotics has the potential to revolutionize many applications, including targeted material deli...
Microrobots are sub-millimetric untethered devices that can move, interact with a given environment,...
A magnetic micro robot is a microscopic magnet that is controlled by a system of electromagnetic coi...
International audienceThis paper analyses the motion control of two magnetic microrobots in the micr...
Independent control ofmicrorobots is a cardinal challenge for manipulation at micro/nano scale. In t...
In this research, two actuation systems were introduced, inertial and magnetic actuation. In the ine...
330 pagesCollectives in nature demonstrate behaviors that extend far beyond the capabilities of any ...
A novel scalable strategy for open loop control of ferromagnetic microrobots on a plane using a scal...
Self-propelled particles are one prototype of synthetic active matter used to understand complex bio...
My PhD dissertation takes an innovative approach to using the fundamental tools of robotics and cont...
This thesis seeks to advance the field of microrobotics by leveraging Bayesian principles and comput...
Microscale robotics have numerous applications in engineering and the biomedical sciences, as the ma...
Tiny robots have many promising applications in medical treatment including targeted drug delivery, ...
We present a general solution for steering microroboticswarm by dynamic actuating fields. In our app...
In this paper, we have developed an approach for independent autonomous navigation of multiple micro...
Microrobotics has the potential to revolutionize many applications, including targeted material deli...
Microrobots are sub-millimetric untethered devices that can move, interact with a given environment,...
A magnetic micro robot is a microscopic magnet that is controlled by a system of electromagnetic coi...
International audienceThis paper analyses the motion control of two magnetic microrobots in the micr...
Independent control ofmicrorobots is a cardinal challenge for manipulation at micro/nano scale. In t...
In this research, two actuation systems were introduced, inertial and magnetic actuation. In the ine...
330 pagesCollectives in nature demonstrate behaviors that extend far beyond the capabilities of any ...
A novel scalable strategy for open loop control of ferromagnetic microrobots on a plane using a scal...
Self-propelled particles are one prototype of synthetic active matter used to understand complex bio...