Rubber artificial skin layer with flexible structure for shape estimation of micro-undulation surfaces

Ando, Makoto; Takei, Toshinobu; Mochiyama, Hiromi

doi:10.1186/s40648-020-00159-0

Cited by 5 publications

(2 citation statements)

References 29 publications

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“…The mechanism is applied to developing tactile sensors, where strains on tips of the cylinders of the tactile contact lenses are measured using a strain gauge and camera [33]- [35]. For example, Ando et al installed a strain gauge between a fingertip and tips of the cylinders of a tactile contact lens to measure the strain generated on the skin during active exploration on a surface [33], [34]. They also investigated the effect of the length of cylinders on amplifications when sliding a bump whose height and width were 100 µm and 160 mm, respectively [33].…”

Section: Related Workmentioning

confidence: 99%

Lever Mechanism for Diaphragm-Type Vibrators to Enhance Vibrotactile Intensity

Hachisu,

Kajiura,

Takeshita

et al. 2024

IEEE Trans. Haptics

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Thin and light vibrators that leverage the inverse piezoelectric effect with a diaphragm mechanism are promising vibrotactile actuators owing to their form factors and high temporal and frequency response. However, generating perceptually sufficient displacement in the low-frequency domain is challenging. This study presents a lever mechanism mounted on a diaphragm vibrator to enhance the vibrotactile intensity of lowfrequency vibrotactile stimuli. The lever mechanism is inspired by the tactile contact lens consisting of an array of cylinders held against the skin on a sheet that enhances micro-bump tactile detection. We built an experimental apparatus including our previously developed thin-film diaphragm-type vibrator, which reproduced the common characteristic of piezoelectric vibrators: near-threshold displacement (10 to 30 µm) at low frequency. Experiments demonstrated enhanced vibrotactile intensity at frequencies less than 100 Hz with the lever mechanism. Although the arrangement and material of the mechanism can be improved, our findings can help improve the expressiveness of diaphragmtype vibrators.

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Section: Related Workmentioning

confidence: 99%

Lever Mechanism for Diaphragm-Type Vibrators to Enhance Vibrotactile Intensity

Hachisu,

Kajiura,

Takeshita

et al. 2024

IEEE Trans. Haptics

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“…Furthermore, a method based on spray coating conductive substances can be easily applied to objects with complex shapes for forming a touch-sensitive surface [6,7,24]. Moreover, wearable sensors, such as [25,26], are a potential approach to detect a touch on objects without sensory instruments.…”

Section: Introductionmentioning

confidence: 99%

One-touch calibration of hum-noise-based touch sensor for unknown users utilizing models trained by different users

et al. 2022

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Hum-noise-based touch sensors (HumTouch) are capable of recognizing human touch on semiconductive materials using the current leaking from the finger to the surface. Thus far, calibration for these hum-noise-based touch sensors has been performed for individual users because of the individual differences in hum-driven electric currents in human bodies. However, for applications designed for unknown users, time-consuming calibration for individual users is not preferred, and a new user should be able to use the sensor immediately. For this purpose, we propose a new calibration method for HumTouch. In this method, learning datasets collected from multiple people and a few extra samples from a new user are collectively used to establish a touch localization estimator. The estimator is computed using the kernel regression method with weighted samples from the new user. For a 20 $$\times $$ × 18 cm$$^2$$ 2 paper, the mean localization error is reduced from 1.24 cm to 0.90 cm with only one sample from the new user. Hence, a new user can establish a semipersonalized localization estimator by touching only one point on the surface. This method improves the localization performance of HumTouch sensors in an easy-to-access manner.

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