Development of an Electrostatic Beat Module for Various Tactile Sensations in Touch Screen Devices

Joo, Young-Bok; Shin, Eun Ju; Heo, Yong Hae; Park, Wonhyung; Yang, Tae‐Heon; Kim, Sang-Youn

doi:10.3390/app9061229

Cited by 6 publications

(3 citation statements)

References 17 publications

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“…Frequency beating can be used in electrostatic actuators to simultaneously activate multiple mechanoreceptors on the skin which creates a multitude of unique sensations. An electrostatic beating actuator with no mechanical vibrotactile actuators was presented and characterized in a study by Joo et al [15]. This study exemplifies one of the many ways electrostatic actuators can be utilized.…”

Section: Introductionmentioning

confidence: 88%

Experimental Evaluation on the Effect of Electrode Configuration in Electrostatic Actuators for Increasing Vibrotactile Feedback Intensity

et al. 2020

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Vibrotactile feedback is a key feature of many modern touch displays, which greatly enhances user experiences when interacting with an onscreen interface. Despite its popularity in small touch screen devices, this haptic feature is absent in most large displays due to a lack of suitable actuators for such applications. Thus, a growing need exists for haptic actuators capable of producing sufficient vibrations in large touch displays. This study proposes and evaluates a novel electrostatic resonant actuator (ERA) with a moving mass and dual electrodes for increased vibration feedback intensity. The dual-electrode ERA was fabricated along with a comparable single-electrode ERA to investigate the effect of the electrode configuration on the maximum vibration intensity. When measured directly on the mass, the maximum vibration intensity of the dual-electrode actuator increased by 73% compared to the single-electrode actuator. When mounted and measured on a mock panel, the maximum vibration intensity of the dual-electrode actuator increased by nearly 65% compared to a similarly mounted single-electrode actuator. These results show that the dual-electrode configuration can significantly increase the vibration intensity when compared to the conventional ERA. This demonstrates a promising potential for the use of the proposed actuator for generating vibrotactile feedback in large touch displays.

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Section: Introductionmentioning

confidence: 88%

Experimental Evaluation on the Effect of Electrode Configuration in Electrostatic Actuators for Increasing Vibrotactile Feedback Intensity

et al. 2020

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“…Most research studies on utilizing electrostatic actuators to provide haptic feedback focus on soft dielectric elastomers. Yong-Bok et al [67] tried to excite two glass panels with input electric beats and created beat-patterned vibration to realize tactile sensing. There are also some film-type actuators with flexible and transparent cellulose acetate (CA) films showing promise for wearable device application [68][69][70].…”

Section: Different Kinds Of Haptic Actuatorsmentioning

confidence: 99%

Electromechanical Actuators for Haptic Feedback with Fingertip Contact

2023

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Haptic technology that provides tactile sensation feedback by utilizing actuators to achieve the purpose of human–computer interaction is obtaining increasing applications in electronic devices. This review covers four kinds of electromechanical actuators useful for achieving haptic feedback: electromagnetic, electrostatic, piezoelectric, and electrostrictive actuators. The driving principles, working conditions, applicable scopes, and characteristics of the different actuators are fully compared. The designs and values of piezoelectric actuators to achieve sophisticated and high-definition haptic effect sensations are particularly highlighted. The current status and directions for future development of the different types of haptic actuators are discussed.

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“…To create high-voltage sine waves, we created a variable, high-voltage simulator consisting of a circuit that generated two high-voltage sine signals with different frequencies [61]. The input frequency was variable, ranging from 70 to 220 Hz, and the actuation voltage amplitude remained between 0 and 800 V. External triggers from the PC were used to control the vibrotactile stimulation sequences.…”

Section: A Meg-compatible Vibrotactile Stimulatormentioning

confidence: 99%

Development of a Polymer-Based MEG-Compatible Vibrotactile Stimulator for Studying Neuromagnetic Somatosensory Responses

et al. 2020

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Vibrotactile technology has been gaining increasing interest for effective human-computer communication in various applications. In addition to psychophysical approaches commonly used to study tactile vibrations, neurocognitive responses to vibrotactile stimuli can provide new insights into mechanisms underlying human vibrotactile perception. In this study, we developed a magnetoencephalography (MEG)compatible vibrotactile stimulation device based on a polyvinyl chloride (PVC) gel actuator to study neuromagnetic somatosensory responses. A symmetric, double-layered PVC gel structure was applied to minimize the magnetic noise from the actuator. The device was used to generate sinusoidal stimuli at high frequencies to activate mechanoreceptors responsible for high-frequency vibrations greater than 50 Hz, and this device showed very little variability in stimulation onset time from the displacement measurements. We successfully observed vibrotactile-evoked magnetic fields by analyzing whole-head MEG data recorded during the high-frequency vibrotactile stimulation of the fingertips. Prominent peak responses were observed at approximately 56 ms (M50) in the contralateral hemisphere and at approximately 100 ms (M100) in both hemispheres. We identified the activation of contralateral primary somatosensory areas as a source of the vibrotactile M50 response. These results demonstrate the feasibility of using our new device to study vibrotactile perception with neuromagnetic imaging methods.

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Development of an Electrostatic Beat Module for Various Tactile Sensations in Touch Screen Devices

Cited by 6 publications

References 17 publications

Experimental Evaluation on the Effect of Electrode Configuration in Electrostatic Actuators for Increasing Vibrotactile Feedback Intensity

Experimental Evaluation on the Effect of Electrode Configuration in Electrostatic Actuators for Increasing Vibrotactile Feedback Intensity

Electromechanical Actuators for Haptic Feedback with Fingertip Contact

Development of a Polymer-Based MEG-Compatible Vibrotactile Stimulator for Studying Neuromagnetic Somatosensory Responses

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