Focused ultrasound as a tool to input sensory information to humans (Review)

Гаврилов, Л. Р.; Tsirulnikov, Efim M.

doi:10.1134/s1063771012010083

Cited by 44 publications

(45 citation statements)

References 47 publications

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“…The use of focused ultrasound as a non-invasive method to stimulate neuroreceptor structures in various parts of the human body has been a topic of research since the early 1970s [Gavrilov and Tsirulnikov 2012]. Dalecki et al [1995] first proposed the idea of using water-based ultrasound to create tactile sensations on a finger attached to an acoustic reflector floating at the surface of a water bath.…”

Section: Creating Tactile Sensations Using Focused Ultrasoundmentioning

confidence: 99%

Rendering volumetric haptic shapes in mid-air using ultrasound

et al. 2014

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General rightsThis document is made available in accordance with publisher policies. Please cite only the published version using the reference above. AbstractWe present a method for creating three-dimensional haptic shapes in mid-air using focused ultrasound. This approach applies the principles of acoustic radiation force, whereby the non-linear effects of sound produce forces on the skin which are strong enough to generate tactile sensations. This mid-air haptic feedback eliminates the need for any attachment of actuators or contact with physical devices. The user perceives a discernible haptic shape when the corresponding acoustic interference pattern is generated above a precisely controlled two-dimensional phased array of ultrasound transducers. In this paper, we outline our algorithm for controlling the volumetric distribution of the acoustic radiation force field in the form of a three-dimensional shape. We demonstrate how we create this acoustic radiation force field and how we interact with it. We then describe our implementation of the system and provide evidence from both visual and technical evaluations of its ability to render different shapes. We conclude with a subjective user evaluation to examine users' performance for different shapes.

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Section: Creating Tactile Sensations Using Focused Ultrasoundmentioning

confidence: 99%

Rendering volumetric haptic shapes in mid-air using ultrasound

et al. 2014

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“…One of the most intriguing methods for creating tactile sensations in the hand involves focused ultrasound [10], [14]. Gavrilov et al investigated this method as a noninvasive tool for diagnosing diseases that affect the nervous system (e.g., the hearing or the skin).…”

Section: B Ultrasound Stimulation Of Neuroreceptor Structuresmentioning

confidence: 99%

“…Gavrilov et al found that the displacement amplitude was approximately 0.1 micrometer for all threshold intensities and independent of the frequency. However, biological effects (e.g., heating) and the direct action of ultrasound vibrations on nerve fibres could be relevant as well [10].…”

Section: B Ultrasound Stimulation Of Neuroreceptor Structuresmentioning

confidence: 99%

“…Moreover, in medical science focused ultrasound has been used as a noninvasive method for diagnosing hearing and neurological disorders, and for creating tactile, temperature and pain sensations in the hand [10]. As a first step to investigate how ultrasound focused in the hand could provide tactile feedback for human-computer interaction, we present a technology that provides the basis for the device we envision and explore the fundamental requirements for creating tactile sensations.…”

Section: Introductionmentioning

confidence: 99%

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SkinHaptics: Ultrasound focused in the hand creates tactile sensations

Spelmezan

González

Subramanian

2016

2016 IEEE Haptics Symposium (HAPTICS)

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Abstract-Recent developments in on-body interfaces have extended the interaction space of physical devices to the skin of our hands. While these interfaces can easily project graphical elements on the bare hand, they cannot give tactile feedback. Here we present a technology that could help to expand the output capability of on-body interfaces to provide tactile feedback without restricting the skin as an interaction surface. SkinHaptics works by focusing ultrasound in the hand using a phased array of ultrasound transmitters and the acoustic timereversal signal processing technique. We present experimental results that show that this device can steer and focus ultrasound on the skin through the hand, which provides the basis for the envisioned technology. We then present results of a study that show that the focused energy can create sensations that are perceived under the skin and in the hand. We demonstrate the potential of SkinHaptics and discuss how our proof-of-concept device can be scaled beyond the prototype.

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“…The displacement caused by the shear wave triggers mechanoreceptors within the skin generating a haptic sensation [11]. The second method bypasses the receptors entirely and directly stimulates the nerve fibres [12]. However, this method requires powerful acoustic fields that penetrate the skin, making it unsuitable for applications designed for prolonged use.…”

Section: Ultrasonic Haptic Feedbackmentioning

confidence: 99%

UltraHaptics

Carter

Seah

Long

et al. 2013

Proceedings of the 26th Annual ACM Symposium on User Interface Software and Technology

412

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We introduce UltraHaptics, a system designed to provide multi-point haptic feedback above an interactive surface. UltraHaptics employs focused ultrasound to project discrete points of haptic feedback through the display and directly on to users' unadorned hands. We investigate the desirable properties of an acoustically transparent display and demonstrate that the system is capable of creating multiple localised points of feedback in mid-air. Through psychophysical experiments we show that feedback points with different tactile properties can be identified at smaller separations. We also show that users are able to distinguish between different vibration frequencies of non-contact points with training. Finally, we explore a number of exciting new interaction possibilities that UltraHaptics provides.

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Focused ultrasound as a tool to input sensory information to humans (Review)

Cited by 44 publications

References 47 publications

Rendering volumetric haptic shapes in mid-air using ultrasound

Rendering volumetric haptic shapes in mid-air using ultrasound

SkinHaptics: Ultrasound focused in the hand creates tactile sensations

UltraHaptics

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