Force Feedback Control of a Medical Haptic Master using an Electrorheological Fluid

This study presents force feedback control performance of a spherical haptic device featuring an electrorheological (ER) fluid that can be used for minimally invasive surgery (MIS). As a first step, a spherical ER joint composed of rotational and stationary electrodes is designed and optimized based...

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Veröffentlicht in:	Journal of intelligent material systems and structures 2007-12, Vol.18 (12), p.1149-1154
Hauptverfasser:	Han, Young-Min, Kang, Pil-Soon, Sung, Kum-Gil, Choi, Seung-Bok
Format:	Artikel
Sprache:	eng
Schlagworte:	Applied sciences Biological and medical sciences Drives Exact sciences and technology Fundamental and applied biological sciences. Psychology Fundamental areas of phenomenology (including applications) Linkage mechanisms, cams Mechanical engineering. Machine design Physics Shafts, couplings, clutches, brakes Solid mechanics Structural and continuum mechanics Vertebrates: nervous system and sense organs
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container_issue	12
container_start_page	1149
container_title	Journal of intelligent material systems and structures
container_volume	18
creator	Han, Young-Min Kang, Pil-Soon Sung, Kum-Gil Choi, Seung-Bok
description	This study presents force feedback control performance of a spherical haptic device featuring an electrorheological (ER) fluid that can be used for minimally invasive surgery (MIS). As a first step, a spherical ER joint composed of rotational and stationary electrodes is designed and optimized based on mathematical torque modeling. The active force produced in MIS is generally small, even though the passive force is large. In order to meet this agreement, both clutch and brake mechanism are adopted for the ER joint. In this operation, the active (small) force feedback by the rotational electrodes and/or semi-active (large) force feedback are achieved by the stationary electrode. Subsequently, the master device is manufactured by integration of the spherical ER joint with AC motor. In order to achieve desired force trajectories, a sliding mode controller, which is robust to uncertainty, is formulated by considering mechanical friction and hysteretic behavior of the ER fluid as uncertainty. The controller is then experimentally realized. Tracking control performances for various force trajectories are presented in time domain.
doi_str_mv	10.1177/1045389X07083132
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As a first step, a spherical ER joint composed of rotational and stationary electrodes is designed and optimized based on mathematical torque modeling. The active force produced in MIS is generally small, even though the passive force is large. In order to meet this agreement, both clutch and brake mechanism are adopted for the ER joint. In this operation, the active (small) force feedback by the rotational electrodes and/or semi-active (large) force feedback are achieved by the stationary electrode. Subsequently, the master device is manufactured by integration of the spherical ER joint with AC motor. In order to achieve desired force trajectories, a sliding mode controller, which is robust to uncertainty, is formulated by considering mechanical friction and hysteretic behavior of the ER fluid as uncertainty. The controller is then experimentally realized. 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As a first step, a spherical ER joint composed of rotational and stationary electrodes is designed and optimized based on mathematical torque modeling. The active force produced in MIS is generally small, even though the passive force is large. In order to meet this agreement, both clutch and brake mechanism are adopted for the ER joint. In this operation, the active (small) force feedback by the rotational electrodes and/or semi-active (large) force feedback are achieved by the stationary electrode. Subsequently, the master device is manufactured by integration of the spherical ER joint with AC motor. In order to achieve desired force trajectories, a sliding mode controller, which is robust to uncertainty, is formulated by considering mechanical friction and hysteretic behavior of the ER fluid as uncertainty. The controller is then experimentally realized. Tracking control performances for various force trajectories are presented in time domain.</abstract><cop>London, England</cop><pub>SAGE Publications</pub><doi>10.1177/1045389X07083132</doi><tpages>6</tpages></addata></record>
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subjects	Applied sciences Biological and medical sciences Drives Exact sciences and technology Fundamental and applied biological sciences. Psychology Fundamental areas of phenomenology (including applications) Linkage mechanisms, cams Mechanical engineering. Machine design Physics Shafts, couplings, clutches, brakes Solid mechanics Structural and continuum mechanics Vertebrates: nervous system and sense organs
title	Force Feedback Control of a Medical Haptic Master using an Electrorheological Fluid
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