Development of a Thin Vibrotactile Actuator Based on the Electrostatic Force Mechanism for Large Haptic Touch Interfaces

Kim, Jae-Ik; Jo, Gwanghyun; Koo, Jeong‐Hoi; Kim, Dong‐Jun; Kim, Young-Min; Yang, Tae‐Heon

doi:10.1155/2022/8331923

Mobile Information Systems

2022

DOI: 10.1155/2022/8331923

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Development of a Thin Vibrotactile Actuator Based on the Electrostatic Force Mechanism for Large Haptic Touch Interfaces

Jae-Ik Kim

Gwanghyun Jo

Jeong‐Hoi Koo

et al.

Abstract: Vibrotactile feedback in touch screen displays (TSDs) contributes to improved usability and enhanced engagement. It is prevalent in small consumer electronic devices, such as smart phones. While vibrotactile feedback is a desirable feature for large TSDs, it is limited in such devices due to a lack of proper actuators. In this study, we propose a thin vibrotactile actuator based on an electrostatic force mechanism suitable for mounting on the back of large TSDs. The primary goals of this study are to design an… Show more

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2024

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Comparing the Psychophysical Capabilities on Fingertip and Wrist using Method of Adjustment

Adeyemi,

Sarac Stroppa

2024

JECT

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Haptic technology, which refers to creating the sense of touch artificially, offers a crucial source of communication between humans and computers or machines. While conventional haptic devices are designed to render vibrotactile information on the fingertip, recent trends in the field expand the tactile communication to other body locations, like the wrist. Even though the literature has many successful applications showing the validity of such haptic applications, there is no study comparing the user perception for meaningful virtual or teleoperated task scenarios due to the lack of calibration methods between alternative body locations. In this paper, we attempt to compare the perceived intensities at the fingertip and the wrist through psychophysical experiments and to answer: (i) Is there a perpetual difference between the haptic stimuli on the wrist compared to the fingertip? (ii) Is possible to form a reasonable, linear relationship (or a pattern) between the stimuli rendered at the fingertip and the wrist? (iii) If so, do different users require different relationships that would need to be obtained through calibration? We designed a user study with 13 healthy participants, receiving three levels of haptic stimuli at their fingertips while adjusting the intensities of the stimuli rendered at their wrist using the method of adjustments. Our results indicate that there is a linear pattern between the vibrotactile stimuli rendered at the fingertip and the wrist, and each participant exhibits a different pattern. Our results can be used to equalize the perceived intensities of different forms of tactile stimuli for future research investigating the perceived performance under different haptic scenarios.

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Comparing the Psychophysical Capabilities on Fingertip and Wrist using Method of Adjustment

Adeyemi,

Sarac Stroppa

2024

JECT

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Development of a Thin Vibrotactile Actuator Based on the Electrostatic Force Mechanism for Large Haptic Touch Interfaces

Cited by 1 publication

References 17 publications

Comparing the Psychophysical Capabilities on Fingertip and Wrist using Method of Adjustment

Comparing the Psychophysical Capabilities on Fingertip and Wrist using Method of Adjustment

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