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Peter J. Berkelman

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13 papers
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13

IROS Conference 2010 Conference Paper

Actuation model for control of a long range Lorentz force magnetic levitation device

  • Peter J. Berkelman
  • Michael Dzadovsky

This paper describes control system development for a large motion range Lorentz force magnetic levitation device designed as a haptic interface device to be grasped by the hand. Due to the 50 mm translation and 60 degree rotation motion ranges of the desktop-sized device, the transformation between the vector of coil currents and the actuation forces and torques generated on the levitated body varies significantly throughout its motion range. To improve the dynamic performance of the device, the current to force and torque transformation can be recalculated at each control update as the levitated body moves about its workspace, rather than using a constant transformation calculated from the unrotated and centered position of the levitated body. The design of the device is presented and the new methods used to calculate coil current to force and torque transformations for levitation are described. Long-range trajectory following feedback control motion results are shown.

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ICRA Conference 2009 Conference Paper

Large motion range magnet levitation using a planar array of coils

  • Peter J. Berkelman
  • Michael Dzadovsky

We have formulated a method and implemented a device for magnetic levitation with a translation range which is at least twice as large as the dimensions of the levitated body in all directions. The motion range can be extended to any distance in the horizontal plane by adding more coils to the actuator array, and the rotation is potentially unlimited in all directions.

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IROS Conference 2007 Conference Paper

A novel coil configuration to extend the motion range of Lorentz force magnetic levitation devices for haptic interaction

  • Peter J. Berkelman

Lorentz force magnetic levitation devices have been used for fine positioning, compliant assembly, force- reflecting teleoperation, and haptic interaction. The advantages of Lorentz levitation devices compared to motorized linkage and/or cable devices include the lack of friction, hysteresis, and other nonlinearities in actuation dynamics, the simplicity and robustness of a single moving part, and the potential for high closed-loop control bandwidths, a large impedance range, and precise motion. The principal disadvantage of existing Lorentz levitation devices is their motion ranges of 25 mm or less in translation and 20 degrees or less in rotation, which limits their utility in application domains such as haptic interaction. In this paper a novel coil and magnet configuration is presented which extends the possible motion range of Lorentz force magnetic levitation devices to 50 mm and at least 60 degrees, twice the present maximum range in translation and three times the maximum rotation. The motion range of the device design is confirmed through computer-aided design models and the levitation feasibility is shown through magnetic finite element analysis.

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IROS Conference 2007 Conference Paper

Task evaluations of a compact laparoscopic surgical robot system

  • Ji Ma
  • Peter J. Berkelman

Minimally invasive surgery (MIS) has become an important technique in practical surgical procedures. Compared with manually operated MIS procedures, surgical robot systems provide more accuracy, enhance dexterity, and make more difficult surgical procedures feasible. In this paper, a prototype teleoperated robotic surgical system which is modular, compact and easy to use is tested with human operators. Two evaluation tasks were performed by participants using manual MIS instruments and this teleoperated robotic surgical system. The task data were analyzed and compared between the manual and robot instrument operation. The results show that compared with typical manual instrument operation, the teleoperated robotic system in this paper has advantages in ease of use, decreased task time, and better accuracy with smooth motions and less tremor.

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IROS Conference 2007 Conference Paper

The University of Hawaii teleoperated robotic surgery system

  • Peter J. Berkelman
  • Ji Ma

Teleoperated robotic surgical systems have been commercially developed and shown to be effective yet their adoption into standard practice has been limited up to the present for reasons which may include size, complexity, and cost. In the Department of Mechanical Engineering at the University of Hawaii, we have developed a new prototype teleoperated robotic system for minimally invasive surgery (MIS) which is simple, compact, and easy to set up and use.

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IROS Conference 2006 Conference Paper

Control Software Design of A Compact Laparoscopic Surgical Robot System

  • Ji Ma
  • Peter J. Berkelman

We have developed a prototype teleoperated robotic surgical system which is modular, compact and easy to use. In this paper, the control software design of the prototype is introduced. The main function of the control software is to realize master-slave control. According to the functions, The control software consists of three layers: hardware drivers, master-slave control and human-machine interface. Each software layer includes several software modules which are easy to maintain and upgrade and are reliable. The preliminary motion control and experimental results are given in the end

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IROS Conference 2006 Conference Paper

Effects of Friction Parameters on Completion Times for Sustained Planar Positioning Tasks with a Haptic Interface

  • Peter J. Berkelman
  • Ji Ma

Haptic interface devices and teleoperation masters are multiple degree of freedom devices manipulated by an operator to generate real-time motion commands to simulated environments or robot manipulators. In this work we examine the relationship between the simulated friction parameters of a particular spatial positioning master device and the completion times of planar positioning tasks by human operators. It is expected that increasing the Coulomb or viscous friction of the device would tend to increase the completion times of less difficult, quicker positioning tasks and decrease completion times for more difficult fine positioning tasks requiring higher precision from the operator. A common haptic interface device was used to perform continuous sequences of planar positioning tasks. Each trial required 10-12 minutes to complete and consisted of 15 positioning sequences which varied in the size of the target regions and the magnitude and type of simulated friction in the device. With a sample size of 10 test subjects, small effects were generally observed as expected, with the exception of the first 3 to 4 sequences of the trials which are concluded to be an adaptation or learning period for the users during each trial

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IROS Conference 2003 Conference Paper

LER: the light endoscope robot

  • Peter J. Berkelman
  • Eric Boidard
  • Philippe Cinquin
  • Jocelyne Troccaz

LER is a compact surgical assistant robot for positioning of an endoscope and camera during minimally invasive surgery. In contrast to typical endoscope manipulators, LER is particularly compact and lightweight at 625 g and 110 mm in diameter, so that it is simple to set up and use, occupies no floor space, and does not limit access to the patient in any way. Our current prototype is fully sterilizeable by autoclave and is ready for clinical trials. It features a full motion range of 360/spl deg/ in rotation and inclination to 10/spl deg/ from the horizontal plane and is backdriveable for manual positioning. Actuation forces are limited for safety. LER may be held in place on the abdomen by adhesive strips or sutures, or attached to the sides of the table with elastic straps or clamps. We have implemented a variety of different user command interfaces for LER, including a miniature keypad, automatic optical instrument motion tracking, and voice command recognition. Experimental trajectory following results and performance parameters are given.

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ICRA Conference 2002 Conference Paper

A Compact, Compliant Laparoscopic Endoscope Manipulator

  • Peter J. Berkelman
  • Philippe Cinquin
  • Jocelyne Troccaz
  • Jean-Marc Ayoubi
  • Christian Létoublon
  • F. Bouchard

We have developed a cable-driven manipulator using pneumatic artificial muscle actuators to control the orientation and insertion depth of an endoscope during abdominal surgery. This manipulator enables a single surgeon to manipulate surgical instruments with both hands while the endoscope position is controlled to view an area of interest inside the abdomen. The surgeon may then control the endoscope by alternate methods such as voice commands, pedals, a joystick, or head movements. The advantages of our newly developed endoscope manipulator over those of commercially available robotic laparoscopic surgical systems are its low cost, simplicity, ease of setup and use, compliance, nonintrusiveness, and very small size and light weight, with the disadvantage of somewhat reduced absolute positioning accuracy. Multiple instruments may be manipulated simultaneously by the manipulators set close together. Experimental performance results of open-loop and feedback control methods are presented.

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IROS Conference 2001 Conference Paper

Comparison of 3-D haptic peg-in-hole tasks in real and virtual environments

  • Bertram J. Unger
  • A. Nicolaidis
  • Peter J. Berkelman
  • A. Thompson
  • Roberta L. Klatzky
  • Ralph L. Hollis

We describe an experimental arrangement for comparison of user performance during a real and a virtual 3D peg-in-hole task. Tasks are performed using a unique six-degree-of-freedom (6-DOF) magnetic levitation haptic device. The arrangement allows a user to exert and experience real and virtual forces using the same 6-DOF device. During the virtual task, a peg and hole are rendered haptically, and visual feedback is provided through a graphical display. During the real task, a physical peg is attached to the underside of the haptic device. Using only real forces/torques, the peg is inserted into a hole in a plate attached to a force/torque sensor, while positions/orientations are measured by the haptic device. positions/orientations and forces/torques are recorded for both modes. Preliminary results indicate increased task time, larger total forces and more failures occur with the virtual task. Recorded data reveal user strategies that are similar for both tasks. Quantitative analysis of the strategies employed should lead to identification of significant factors in haptic interface design and haptic rendering techniques.

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ICRA Conference 2000 Conference Paper

Preliminary Experiments in Cooperative Human/Robert Force Control for Robot Assisted Microsurgical Manipulation

  • Rajesh Kumar 0001
  • Peter J. Berkelman
  • Puneet K. Gupta
  • Aaron C. Barnes
  • Patrick S. Jensen
  • Louis L. Whitcomb
  • Russell H. Taylor

Reports preliminary experiments with a robot system designed to cooperatively extend a human's ability to perform fine manipulation tasks requiring human judgement, sensory integration and hand-eye coordination. A completed steady-hand robot is reported. A stable force control law is reviewed. Preliminary experiments validate theoretical predictions of stable one-dimensional control of tool-tip forces in contact with both linearly and nonlinearly compliant objects. Preliminary feasibility experiments demonstrate stable one-dimensional robotic augmentation and "force scaling" of a human operator's tactile input.

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ICRA Conference 1999 Conference Paper

Interaction with a Realtime Dynamic Environment Simulation Using a Magnetic Levitation Haptic Interface Device

  • Peter J. Berkelman
  • Ralph L. Hollis
  • David Baraff

A high performance six degree-of-freedom magnetic levitation haptic interface device has been integrated with a physically-based dynamic rigid-body simulation to enable realistic user interaction in real time with a 3-D dynamic virtual environment. The user grasps the levitated handle of the device to manipulate a virtual tool in the simulated environment and feels its force and motion response as it contacts and interacts with other objects in the simulation. The physical simulation and the magnetic levitation controller execute independently on separate processors. The position and orientation of the virtual tool in the simulation and the levitated handle of the maglev device are exchanged at each update of the simulation. The position and orientation data from each system act as impedance control setpoints for the other, with position error and velocity feedback on each system acting as virtual coupling between the two systems. The setpoints from the simulation are interpolated by the controller at the faster device control rate so that the user feels smooth sliding contacts without chattering due to the slower updates of the simulation. The simple feedback coupling between the two systems enables the overall stiffness and stability of the combined system to be tuned easily and provides realistic haptic user interaction. Sample task simulation environments have been programmed to demonstrate the effectiveness of the haptic interaction system.

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IROS Conference 1995 Conference Paper

Interacting with virtual environments using a magnetic levitation haptic interface

  • Peter J. Berkelman
  • Ralph L. Hollis
  • Septimiu E. Salcudean

A high-performance magnetic levitation haptic interface has been developed to enable the user to interact dynamically with simulated environments by holding a levitated structure and directly feeling its computed force and motion responses. The haptic device consists of a levitated body with six degrees of freedom and motion ranges of /spl plusmn/5 mm and /spl plusmn/3. 5 degrees in all directions. The current device can support weights of up to 20 N and can generate a torque of 1. 7 Nm. Control bandwidths of up to 50 Hz and stiffnesses from 0. 01 to 23 N/mm have been achieved by the device using a digital velocity estimator and 1 KHz control on each axis. The response of the levitated device has been made successfully to emulate virtual devices such as gimbals and bearings as well as different dynamic interactions such as hard solid contacts, dry and viscous friction, and textured surfaces.

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