Abstract
This paper presents an electroactive and soft vibrotactile actuator based on a dielectric elastomer. The vibrotactile actuator is composed of an upper layer, an adhesive tape layer, a dielectric layer with bumps, and a lower layer. When a voltage is applied to the actuator, an electrostatic force created between the upper and lower layers pulls the upper layer down, compressing the dielectric layer. As soon as the applied voltage is released, the upper layer is quickly restored to its initial state by the elastic force of the compressed dielectric elastomer. Because two forces contribute to the actuation at the same time, the created vibration is sufficiently strong to stimulate human mechanoreceptors. When the applied voltage is removed, the upper layer and dielectric elastomer return to their initial shapes. We conducted experiments to determine the best weight ratio of polydimethylsiloxane (PDMS) and Ecoflex, and to quantitatively investigate the haptic performance of the proposed vibrotactile actuator. The experiments clearly show that the plasticized vibrotactile actuator can create a variety of haptic sensations over a wide frequency range.
Highlights
Considering their abundant capabilities, smart devices have become an integral part of most people’s lives
We have proposed a thin, highly flexible, and lightweight vibrotactile actuator based on PDMS and Ecoflex, and experimentally optimized it to provide a variety
We have proposed a thin, highly flexible, and lightweight vibrotactile actuator based on PDMS and Ecoflex, and experimentally optimized it to provide a variety of haptic sensations in real time
Summary
Considering their abundant capabilities, smart devices have become an integral part of most people’s lives. Smart devices can provide absorbing and interesting content to users through multisensory channels (visual, auditory, and haptic). In the case of smart handheld devices, because the size of the visual display is not large enough to provide an immersive sensation to users, haptic information coupled with visual information enables users to delicately and immersively manipulate target objects. Haptic information is mainly created by small and lightweight vibrotactile actuators already embedded in smart handheld devices [1,2,3,4]. Smart handheld devices have evolved into fully flexible types that maximize their usability and availability [5,6,7]. It is necessary to consider flexible vibrotactile actuators that can change shape to create improved haptic sensations in fully flexible devices
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