A wearable device for controlling a robot gripper with fingertip contact, pressure, vibrotactile, and grip force feedback

This paper investigates the possibility of implementing force-feedback controllers using measurement of interaction force obtained through force-sensing resistors (FSRs), to improve performance of human interacting robots. A custom sensorized handle was developed, with the capability of simultaneously measuring grip force and interaction force during robot-aided rehabilitation therapy. Experiments are performed in order to assess the suitability of FSRs to implement force-feedback interaction controllers. In the force-feedback control condition, the applied force for constant speed motion of a linear 1DOF haptic interface is reduced 6.1 times compared to the uncontrolled condition, thus demonstrating the possibility of improving transparency through force-feedback via FSRs.

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Design of a robot gripper with force feedback control

Mechatronics ◽

10.1016/0957-4158(91)90017-5 ◽

1991 ◽

Vol 1 (3) ◽

pp. 311-319 ◽

Cited By ~ 1

Author(s):

J.D. Tedford

Keyword(s):

Feedback Control ◽

Force Feedback ◽

Robot Gripper

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Force feedback delay affects perception of stiffness but not action, and the effect depends on the hand used but not on the handedness

Journal of Neurophysiology ◽

10.1152/jn.00822.2017 ◽

2018 ◽

Vol 120 (2) ◽

pp. 781-794 ◽

Cited By ~ 7

Author(s):

Raz Leib ◽

Inbar Rubin ◽

Ilana Nisky

Keyword(s):

Force Field ◽

Grip Force ◽

Force Feedback ◽

Internal Representation ◽

Elastic Force ◽

Perceptual Bias ◽

Load Force ◽

Test Case ◽

Robotic Device ◽

Left Handed

Interaction with an object often requires the estimation of its mechanical properties. We examined whether the hand that is used to interact with the object and their handedness affected people’s estimation of these properties using stiffness estimation as a test case. We recorded participants’ responses on a stiffness discrimination of a virtual elastic force field and the grip force applied on the robotic device during the interaction. In half of the trials, the robotic device delayed the participants’ force feedback. Consistent with previous studies, delayed force feedback biased the perceived stiffness of the force field. Interestingly, in both left-handed and right-handed participants, for the delayed force field, there was even less perceived stiffness when participants used their left hand than their right hand. This result supports the idea that haptic processing is affected by laterality in the brain, not by handedness. Consistent with previous studies, participants adjusted their applied grip force according to the correct size and timing of the load force regardless of the hand that was used, the handedness, or the delay. This suggests that in all of these conditions, participants were able to form an accurate internal representation of the anticipated trajectory of the load force (size and timing) and that this representation was used for accurate control of grip force independently of the perceptual bias. Thus these results provide additional evidence for the dissociation between action and perception in the processing of delayed information. NEW & NOTEWORTHY Introducing delay to force feedback during interaction with an elastic force field biases the perceived stiffness of the force field. We show that this bias depends on the hand that was used for probing but not on handedness. At the same time, both left-handed and right-handed participants adjusted their applied grip force while using either their left or right hands in anticipation of the correct magnitude and timing despite the delay in load force.

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Development of BilateralWearable Device Kento for Control Robots Using Muscle-Actuator Modules

Journal of Robotics and Mechatronics ◽

10.20965/jrm.2010.p0308 ◽

2010 ◽

Vol 22 (3) ◽

pp. 308-314 ◽

Cited By ~ 4

Author(s):

Kazuo Hongo ◽

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Yuto Nakanishi ◽

Mariko Yoshida ◽

Ikuo Mizuuchi ◽

...

Keyword(s):

External Force ◽

Force Feedback ◽

Wearable Device ◽

Bilateral Control

The bilateral wearable device with stiffness-adjustable muscle-actuator modules we developed to control robots by sensing external force from them and teaching them movement for contact with their surroundings. Experiments confirmed that maneuvering a musculoskeletal humanoid fed back the humanoid’s force to a manipulator and its force feedback through bilateral control enabled the manipulator to engage in safe contact with its environment.

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Towards Wearability in Fingertip Haptics: A 3-DoF Wearable Device for Cutaneous Force Feedback

IEEE Transactions on Haptics ◽

10.1109/toh.2013.53 ◽

2013 ◽

Vol 6 (4) ◽

pp. 506-516 ◽

Cited By ~ 152

Author(s):

Domenico Prattichizzo ◽

Francesco Chinello ◽

Claudio Pacchierotti ◽

Monica Malvezzi

Keyword(s):

Force Feedback ◽

Wearable Device

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The Effect of Dissociation between Proprioception and Vision on Perception and Grip Force Control in a Stiffness Judgment Task

10.1101/252536 ◽

2018 ◽

Author(s):

Stephanie Hu ◽

Raz Leib ◽

Ilana Nisky

Keyword(s):

Visual Feedback ◽

Grip Force ◽

Force Feedback ◽

Judgment Task ◽

Hand Position ◽

Sensorimotor System ◽

Mixed Effect ◽

Sensory Modalities ◽

Teleoperation Systems ◽

Visual Delay

AbstractOur sensorimotor system estimates stiffness to form stiffness perception, such as for choosing a ripe fruit, and to generate actions, such as to adjust grip force to avoid slippage of a scalpel during surgery. We examined how temporal manipulation of the haptic and visual feedback affect stiffness perception and grip force adjustment during a stiffness discrimination task. We used delayed force feedback and delayed visual feedback to break the natural relations between these modalities when participants tried to choose the harder spring between pairs of springs. We found that visual delay caused participants to slightly overestimate stiffness while force feedback delay caused a mixed effect on perception; for some it caused underestimation and for some overestimation of stiffness. Interestingly and in contrast to previous findings without vision, we found that participants increased the magnitude of their applied grip force for all conditions. We propose a model that suggests that this increase was a result of coupling the grip force adjustment to their proprioceptive hand position, which was the only modality which we could not delay. Our findings shed light on how the sensorimotor system combines information from different sensory modalities for perception and action. These results are important for the design of improved teleoperation systems that suffer from unavoidable delays.

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Auditory Grip Force Feedback in the Treatment of Writer's Cramp

Journal of Hand Therapy ◽

10.1016/j.jht.2008.11.001 ◽

2009 ◽

Vol 22 (2) ◽

pp. 163-171 ◽

Cited By ~ 21

Author(s):

Barbara Baur ◽

Waltraud Fürholzer ◽

Christian Marquardt ◽

Joachim Hermsdörfer

Keyword(s):

Grip Force ◽

Force Feedback ◽

Writer’S Cramp ◽

Writer's Cramp

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Enhanced visual feedback for slip prevention with a prosthetic hand

Prosthetics and Orthotics International ◽

10.1177/0309364612440077 ◽

2012 ◽

Vol 36 (4) ◽

pp. 423-429 ◽

Cited By ~ 23

Author(s):

Erik D Engeberg ◽

Sanford Meek

Keyword(s):

Visual Feedback ◽

Upper Limb ◽

Grip Force ◽

Force Feedback ◽

Sliding Mode ◽

Controlled Trial ◽

Prosthetic Hand ◽

Success Rates ◽

Precise Control ◽

Visual Force Feedback

Background: Upper limb amputees have no direct sense of the grip force applied by a prosthetic hand; thus, precise control of the applied grip force is difficult for amputees. Since there is little object deformation when rigid objects are grasped, it is difficult for amputees to visually gauge the applied grip force in this situation. Objectives: To determine if the applied grip force from a prosthetic hand can be visually displayed and used to more efficaciously grasp objects. Study Design: Experimental controlled trial. Methods: Force feedback is used in the control algorithm for the prosthetic hand and supplied visually to the user through a bicolor LED experimentally mounted to the thumb. Several experiments are performed by able-bodied test subjects to rate the usefulness of the additional visual feedback when manipulating a clearly visible, brittle object that can break if grasped too firmly. A hybrid force-velocity sliding mode controller is used with and without additional visual force feedback supplied to the operators. Results: Subjective evaluations and success rates from the test subjects indicate a statistically significant reduction in breaking the grasped object when using the prosthesis with the extra visual feedback. Conclusions: The additional visual force feedback can effectively facilitate the manipulation of brittle objects. Clinical relevance The novel approach of this research is the implementation of a noninvasive, effective and economic technique to visually indicate the grip force applied by a prosthetic hand to upper limb amputees. This technique provides a statistically significant improvement when handling brittle objects.

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