Michael Fritschi scite author profile

Abstract-Gait and balance training is an essential ingredient for locomotor rehabilitation of patients with neurological impairments. Robotic overhead support systems may help these patients train, for example by relieving them of part of their body weight. However, there are only very few systems that provide support during overground gait, and these suffer from limited degrees of freedom and/or undesired interaction forces due to uncompensated robot dynamics, namely inertia. Here, we suggest a novel mechanical concept that is based on cable robot technology and that allows three-dimensional gait training while reducing apparent robot dynamics to a minimum. The solution does not suffer from the conventional drawback of cable robots, which is a limited workspace. Instead, displaceable deflection units follow the human subject above a large walking area. These deflection units are not actuated, instead they are implicitly displaced by means of the forces in the cables they deflect. This leads to an underactuated design, because the deflection units cannot be moved arbitrarily. However, the design still allows accurate control of a three-dimensional force vector acting on a human subject during gait. We describe the mechanical concept, the control concept, and we show first experimental results obtained with the device, including the force control performance during robot-supported overground gait of five human subjects without motor impairments.

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Self-Sensing of Deflection, Force, and Temperature for Joule-Heated Twisted and Coiled Polymer Muscles via Electrical Impedance

Weijde

Smit

Fritschi

et al. 2017

IEEE/ASME Trans. Mechatron.

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First evaluation of a novel tactile display exerting shear force via lateral displacement

Drewing

Fritschi

Zopf

et al. 2005

ACM Trans. Appl. Percept.

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Based on existing knowledge on human tactile movement perception, we constructed a prototype of a novel tactile multipin display that controls lateral pin displacement and, thus produces shear force. Two experiments focus on the question of whether the prototype display generates tactile stimulation that is appropriate for the sensitivity of human tactile perception. In particular, Experiment I studied human resolution for distinguishing between different directions of pin displacement and Experiment II explored the perceptual integration of information resulting from the displacement of multiple pins. Both experiments demonstrated that humans can discriminate between directions of the displacements, and also that the technically realized resolution of the display exceeds the perceptual resolution (>14 • ). Experiment II demonstrated that the human brain does not process stimulation from the different pins of the display independent of one another at least concerning direction. The acquired psychophysical knowledge based on this new technology will in return be used to improve the design of the display.

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Force sensing for compliant actuators using coil spring inductance

Weijde

Vlasblom

Dobbe

et al. 2015

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A smart pressure-sensitive insole that reminds you to walk correctly: An orthotic-less treatment for over pronation

Berengueres

Fritschi

McClanahan³

2014

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We equipped an insole with a force sensor that can detect in real time when a foot over pronates. When such behavior is detected, we warn the user so they can correct their posture by using their own muscles. The effectiveness of this novel way to correct over pronation posture is evaluated over a two-week period. The use of vibrotactile feedback reduces over pronation by 30% to 50% during the first week. The natural benefits of the proposed method vs. use of passive orthotics are also presented.

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