%0 Journal Article %J Journal of Dynamic Systems, Measurement and Control, Transactions of the ASME %D 2006 %T Shared control in haptic systems for performance enhancement and training %A O'Malley, M.K. %A Abhishek Gupta %A Gen, Matthew %A Yanfang Li %K Control equipment %K Damping %K Data reduction %K Haptic interfaces %K Robotics %K Robots %X

This paper presents a shared-control interaction paradigm for haptic interface systems, with experimental data from two user studies. Shared control, evolved from its initial telerobotics applications, is adapted as a form of haptic assistance in that the haptic device contributes to execution of a dynamic manual target-hitting task via force commands from an automatic controller. Compared to haptic virtual environments, which merely display the physics of the virtual system, or to passive methods of haptic assistance for performance enhancement based on virtual fixtures, the shared-control approach offers a method for actively demonstrating desired motions during virtual environment interactions. The paper presents a thorough review of the literature related to haptic assistance. In addition, two experiments were conducted to independently verify the efficacy of the shared-control approach for performance enhancement and improved training effectiveness of the task. In the first experiment, shared control is found to be as effective as virtual fixtures for performance enhancement, with both methods resulting in significantly better performance in terms of time between target hits for the manual target-hitting task than sessions where subjects feel only the forces arising from the mass-spring-damper system dynamics. Since shared control is more general than virtual fixtures, this approach may be extremely beneficial for performance enhancement in virtual environments. In terms of training enhancement, shared control and virtual fixtures were no better than practice in an unassisted mode. For manual control tasks, such as the one described in this paper, shared control is beneficial for performance enhancement, but may not be viable for enhancing training effectiveness. Copyright © 2006 by ASME.

%B Journal of Dynamic Systems, Measurement and Control, Transactions of the ASME %V 128 %P 75 - 85 %G eng %U http://scitation.aip.org/getabs/servlet/GetabsServlet?prog=normal&id=JDSMAA000128000001000075000001&idtype=cvips&gifs=yes %& 75 %R 10.1115/1.2168160 %> https://mahilab.rice.edu/sites/default/files/publications/52-00%20-%20JDSMC%20Shared%20control.pdf %0 Conference Proceedings %B ASEE Annual Conference Proceedings %D 2004 %T Virtual labs in the engineering curriculum %A David M. McStravick %A O'Malley, M.K. %K Computer programming languages %K Computer simulation %K Curricula %K Data reduction %K Graphic methods %K Students %K Visualization %X

Computer simulations have been developed for use as student exercises to illustrate concepts required for various engineering courses. These simulations or Virtual Labs are highly graphical and interactive to help undergraduate students understand basic concepts by graphically solving problems and by visualization of real-time parametric changes. These Virtual Labs (or VL's) can be used productively in conjunction with existing laboratory experiments as pre-lab exercises, but the more important benefit is realized in cases of concepts that have no experimental support and in courses that traditionally do not have an associated laboratory course. These VL's are generated in the software package Lab VIEW, which offers graphical interfaces for the student and can be formatted as standalone files, which the students can download and access at their convenience, without the need for Lab VIEW software. Currently five VL's have been generated and several have been evaluated by students in appropriate classes.

%B ASEE Annual Conference Proceedings %C Salt Lake City, UT, United States %P 15293 - 15304 %G eng %> https://mahilab.rice.edu/sites/default/files/publications/mcstravick2004asee.pdf