Wearable Vibrotactile Haptic Device for Stiffness Discrimination during Virtual Interactions

Maereg, Andualem Tadesse; Nagar, Atulya K.; Reid, David; Secco, Emanuele Lindo

doi:10.3389/frobt.2017.00042

Cited by 69 publications

(48 citation statements)

References 23 publications

(26 reference statements)

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“…This differs from other works in the literature, where, for example, stiffness is modelled as a rigid spring (Maereg et al, 2017). Furthermore, the FHD can allow for both "pressing" and "tapping" on the user's fingertip, depending on the task, unlike haptic devices mentioned in the Introduction Section which are continuously in contact with the user's fingertip.…”

Section: Discussionmentioning

confidence: 46%

“…Some exoskeleton designs are bulky while some cover just fingertips, which can be especially effective for tactile applications and controllable cutaneous feedback (Pacchierotti et al, 2017) and can be classified according to the cutaneous sensation that they provide: normal indentation, tangential motion, lateral skin stretch or vibration (Pacchierotti et al, 2017). An example of use of vibration for haptic feedback is the device by Maereg et al (2017) with five vibro-tactile actuators, one for each fingertip of the user. Although wearable devices usually provide cutaneous stimuli, with most of the kinaesthetic feedback missing (Prattichizzo et al, 2013), it is possible to compensate for this deficiency without significant performance degradation (Pacchierotti et al, 2014).…”

Section: Introductionmentioning

confidence: 99%

“…Motors actuate three legs connecting these two parts to render forces from the virtual environment. A virtual environment is used for testing also in the work by Maereg et al (2017) where tracking is done via a LeapMotion controller and PHF is also explored by visualising displacement in the virtual environment.…”

Section: Introductionmentioning

confidence: 99%

See 2 more Smart Citations

Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

Tzemanaki

Melhuish

et al. 2018

Front. Robot. AI

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This paper presents the development of a wearable Fingertip Haptic Device (FHD) that can provide cutaneous feedback via a Variable Compliance Platform (VCP). The FHD includes an inertial measurement unit, which tracks the motion of the user's finger while its haptic functionality relies on two parameters: pressure in the VCP and its linear displacement towards the fingertip. The combination of these two features results in various conditions of the FHD, which emulate the remote object or surface stiffness properties. Such a device can be used in tele-operation, including virtual reality applications, where rendering the level of stiffness of different physical or virtual materials could provide a more realistic haptic perception to the user. The FHD stiffness representation is characterised in terms of resulting pressure and force applied to the fingertip created through the relationship of the two functional parameters -pressure and displacement of the VCP. The FHD was tested in a series of user studies to assess its potential to create a user perception of the object's variable stiffness. The viability of the FHD as a haptic device has been further confirmed by interfacing the users with a virtual environment. The developed virtual environment task required the users to follow a virtual path, identify objects of different hardness on the path and navigate away from "no-go" zones. The task was performed with and without the use of the variable compliance on the FHD. The results showed improved performance with the presence of the variable compliance provided by the FHD in all assessed categories and particularly in the ability to identify correctly between objects of different hardness.

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Section: Discussionmentioning

confidence: 46%

Section: Introductionmentioning

confidence: 99%

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Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

Tzemanaki

Melhuish

et al. 2018

Front. Robot. AI

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“…force vector, vibration, and contact state [19]. However, vibration motors, which are easy to control, are widely applied in Virtual Reality [20], [21]. We applied eccentric rotating mass (ERM) vibration motors which deliver the dynamic state of the swarm in the form of tactile patterns.…”

Section: Technologymentioning

confidence: 99%

SwarmTouch: Guiding a Swarm of Micro-Quadrotors With Impedance Control Using a Wearable Tactile Interface

Tsykunov

Agishev

Ibrahimov

et al. 2019

IEEE Trans. Haptics

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To achieve a smooth and safe guiding of a drone formation by a human operator, we propose a novel interaction strategy for a human-swarm communication which combines impedance control and vibrotactile feedback. The presented approach takes into account the human hand velocity and changes the formation shape and dynamics accordingly using impedance interlinks simulated between quadrotors, which helps to achieve a natural swarm behavior. Several tactile patterns representing static and dynamic parameters of the swarm are proposed. The user feels the state of the swarm at the fingertips and receives valuable information to improve the controllability of the complex formation. A user study revealed the patterns with high recognition rates. A flight experiment demonstrated the possibility to accurately navigate the formation in a cluttered environment using only tactile feedback. Subjects stated that tactile sensation allows guiding the drone formation through obstacles and makes the human-swarm communication more interactive. The proposed technology can potentially have a strong impact on the human-swarm interaction, providing a higher level of awareness during the swarm navigation.Index Terms-Human-robot interaction, tactile display, wearable computers ! • All authors are with the

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“…• Vibrotactile feedback uses vibration motors to provide feedback: its most familiar uses are "rumbles" in videogames or alerts on smartphones, but it can also be used in quite nuanced ways, such as the display of variable stiffness through different vibration intensities [22]. Such uses can well be adapted for communication purposes of deafblind persons.…”

Section: Haptic and Thermal Feedbackmentioning

confidence: 99%

Empowering Persons with Deafblindness

Korn

Holt

Kontopoulos

et al. 2018

Proceedings of the 11th PErvasive Technologies Related to Assistive Environments Conference

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Deafblindness is a condition that limits communication capabilities primarily to the haptic channel. In the EU-funded project SUITCEYES we design a system which allows haptic and thermal communication via soft interfaces and textiles. Based on user needs and informed by disability studies, we combine elements from smart textiles, sensors, semantic technologies, image processing, face and object recognition, machine learning, affective computing, and gamification. In this work, we present the underlying concepts and the overall design vision of the resulting assistive smart wearable. CCS Concepts

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Wearable Vibrotactile Haptic Device for Stiffness Discrimination during Virtual Interactions

Cited by 69 publications

References 23 publications

Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

Design of a Wearable Fingertip Haptic Device for Remote Palpation: Characterisation and Interface with a Virtual Environment

SwarmTouch: Guiding a Swarm of Micro-Quadrotors With Impedance Control Using a Wearable Tactile Interface

Empowering Persons with Deafblindness

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