Your search keyword '"Michael P. Kummer"' showing total 4 results

1. OctoMag: An electromagnetic system for 5-DOF wireless micromanipulation

Author

Ali Sengül, Bradley J. Nelson, Michael P. Kummer, Jake J. Abbott, Bradley E. Kratochvil, and Ruedi Borer

Subjects

Electromagnetic field, Engineering, Electromagnet, Wireless network, business.industry, Electrical engineering, Robotics, Workspace, Computer Science Applications, law.invention, Magnetic field, Computer Science::Robotics, Mechanism (engineering), Control and Systems Engineering, law, Electronic engineering, Robot, Wireless, Artificial intelligence, Electrical and Electronic Engineering, business, Micromanipulator, Magnetic levitation

Abstract

We demonstrate five-degree-of-freedom (5-DOF) wireless magnetic control of a fully untethered microrobot with a magnetic steering system we call OctoMag. Although only occupying a single hemisphere, this system is capable of isotropically applying forces on the order of 1–40 µN with unrestricted control of the 2 orienting DOF. These capabilities are enabled through the use of soft-magnetic-cores which provide an increase of approximately 20× that of air cores in magnetic-field strength, but comes at the cost of more complicated interactions between coils. We propose a modeling mechanism that assumes the field contributions of the individual currents superimpose linearly when using cores with large linear regions and negligible hysteresis. When designing the system, the locations and quantity of electromagnets were optimized with regards to the force generation in the worst-case direction predicted by the model. The resultant system is capable of both open and closed-loop operation over a workspace of 4 cm3. OctoMag was primarily designed for the control of intraocular microrobots for delicate retinal procedures, but also has potential uses in other medical applications or micromanipulation under an optical microscope.

Published

2010

2. Artificial Vitreous Humor for In Vitro Experiments

Author

Bradley J. Nelson, Michael P. Kummer, Jake J. Abbott, and S. Dinser

Subjects

Materials science, Tissue Engineering, genetic structures, Viscosity, Water, Vitreous replacement, Robotics, Elasticity, eye diseases, Aqueous Humor, Agar, Magnetics, Patient diagnosis, Water chemistry, Stress, Mechanical, sense organs, Hyaluronic Acid, Biomedical engineering

Abstract

In this paper we present a protocol to create artificial vitreous humor phantom tissue to be used as a test bed for in vitro experiments. The artificial vitreous consists of water, agar, and hyaluronic acid. Unlike existing vitreous replacement substances, this dummy tissue exhibits viscoelastic characteristics of in vivo natural vitreous humor. We are able to prepare artificial vitreous with a range of viscoelastic properties, which will allow us to account for the variation seen in human vitreous that comes with aging. The artificial vitreous will primarily serve as an experimental test bed for wireless magnetic control and vision-based tracking of assembled-MEMS microrobots. These microrobots will someday enable minimally invasive surgical and diagnostic intraocular procedures.

Published

2007

3. Measuring the Magnetic and Hydrodynamic Properties of Assembled-MEMS Microrobots

Author

Michael P. Kummer, Jake J. Abbott, Bradley J. Nelson, and Karl Vollmers

Subjects

Microelectromechanical systems, Engineering, Field (physics), business.industry, Acoustics, System of measurement, Measure (physics), Linear stage, Ellipsoid, Magnetic field, Computer Science::Robotics, Control theory, Magnet, business

Abstract

Microrobots experience physical phenomena that are difficult to model analytically and that are not completely captured with macro-scale prototypes. In this paper we present a reconfigurable robotic measurement system to characterize the magnetic and hydrodynamic properties of assembled-MEMS microrobots. The system consists of a powerful permanent magnet that is position controlled with a linear stage. The magnetic field is accurately characterized. Precision sensors are used to measure magnetic force as a function of applied field. The system is first used to validate an existing model for the magnetic force on a soft-magnetic ellipsoid. Next, the magnetic force on a soft-magnetic assembled-MEMS microrobot as a function of the applied field is measured experimentally. Finally, a vision tracking system is integrated with the setup to measure the hydrodynamic properties of the microrobot. The coefficient of viscous friction for the microrobot is obtained experimentally.

Published

2007

4. Modeling magnetic torque and force for controlled manipulation of soft-magnetic bodies

Author

Olgaç Ergeneman, Ann M. Hirt, Jake J. Abbott, Michael P. Kummer, and Bradley J. Nelson

Subjects

Physics, Field (physics), Magnetic moment, Continuous modelling, Force field (physics), Ellipsoid, Computer Science Applications, Magnetic field, Magnetization, Classical mechanics, Control and Systems Engineering, Torque, Electrical and Electronic Engineering, Actuator, Axial symmetry

Abstract

We calculate the torque and force generated by an arbitrary magnetic field on an axially symmetric soft-magnetic body. We consider the magnetization of the body as a function of the applied field, using a continuous model that unifies two disparate magnetic models. The continuous torque and force follow. The model is verified experimentally, and captures the often neglected region between weak and saturating fields, where interesting behavior is observed. We provide the field direction to maximize torque for a given field magnitude. We also find an absolute maximum torque, for a given body geometry and material, which can be generated with relatively weak applied fields. This paper is aimed at those interested in systems-level analysis, simulation, and real-time control of soft-magnetic bodies.

Published

2007