Multimode Hydraulically Amplified Electrostatic Actuators for Wearable Haptics

Leroy, Edouard; Hinchet, Ronan; Shea, Herbert

doi:10.1002/adma.202002564

Cited by 164 publications

(190 citation statements)

References 39 publications

(42 reference statements)

Supporting

Mentioning

175

Contrasting

Order By: Relevance

“…The surface texture, topography, stiffness, deformation, applied force, and other desired information of the internal organs of the patient can be measured and fed back by the integrated sensing system of the surgical tools and then transmitted to the surgeon through tactile reproduction provided by the soft actuator array. Some researches using soft robotic technologies for haptic feedback have emerged in recent years, and a recent review of them can be found in the study by Yin et al [408] Common haptic feedback methods based on mechanical stimulation include vibrotactile stimulation, [409,410] normal pressing, [411,412] and skin stretch, [413,414] and the introduction of soft technologies can achieve safe, compact, and lightweight system integration as well as good simulation of tactile sensation of soft organs.…”

Section: Robotic Assistancementioning

confidence: 99%

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Zhu

Lyu

et al. 2021

Advanced Intelligent Systems

View full text Add to dashboard Cite

Endowed with the expected visions for future surgery, minimally invasive surgery (MIS) has become one of the most rapid developing areas in modern surgery. Soft robotics, which originates from interdisciplinary advances in materials, fabrication, and electronics, featuring better adaptability and safer interaction, holds great promises in addressing current technical challenges in MIS, which are difficult to be solved with current rigid robotic technologies. For the first time, herein, the expected characteristics of next-generation MIS from the surgeons' perspectives are analyzed and the recent progress of soft surgical instruments from three different aspects is comprehensively summarized: engineering design, fabrication techniques, and human-robot interaction. Perspectives of nextgeneration soft surgical robots are then discussed, where some exciting possibilities are emphasized. It is believed that further developments of intelligent soft robotics enable the next-generation MIS to agilely navigate to the target and conduct dexterous diagnostic or therapeutic procedures without any trade-offs in invasiveness and ultimately be a propitious solution for future surgery.

show abstract

Section: Robotic Assistancementioning

confidence: 99%

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Zhu

Lyu

et al. 2021

Advanced Intelligent Systems

View full text Add to dashboard Cite

show abstract

“…[ 17,18 ] Yet, DEAs require high driving voltages in the kilovolts range and suffer from dielectric breakdowns, which irreversibly damage the lens (Table S1, Supporting Information). Actuators based on the displacement of dielectric liquids via zipping electroactive polymers (ZEAP) survive dielectric breakdown and have promising applications as artificial muscles for soft robotics [ 19,20 ] and wearable haptic displays, [ 21 ] but they require high driving voltages as well.…”

Section: Figurementioning

confidence: 99%

“…Omitting this connection can lead to directional inflation of the membrane, which is beneficial for other applications that involve touch, such as buttons or brail displays. [ 21 ] Heat‐sealing the electrodes in regular steps along the edge of the electrodes introduces specific starting points for zipping to improve the zipping homogeneity (we use this for all our lenses) and partially reduces the threshold voltage (Figure S3, Supporting Information). The dielectric fluid is a low viscosity paraffin oil with a refractive index n = 1.48 (close to PDMS); it is injected with a syringe through an access tube and sealed.…”

Section: Figurementioning

confidence: 99%

Soft Tunable Lenses Based on Zipping Electroactive Polymer Actuators

et al. 2020

View full text Add to dashboard Cite

Compact and entirely soft optics with tunable and adaptive properties drive the development of life‐like soft robotic systems. Yet, existing approaches are either slow, require rigid components, or use high operating voltages of several kilovolts. Here, soft focus‐tunable lenses are introduced, which operate at practical voltages, cover a high range of adjustable focal lengths, and feature response times in the milliseconds range. The nature‐inspired design comprises a liquid‐filled elastomeric lens membrane, which is inflated by zipping electroactive polymers to tune the focal length. An analytic description of the tunable lens supports optimized designs and accurate prediction of the lens characteristics. Focal length changes between 22 and 550 mm (numerical aperture 0.14–0.005) within 260 ms, equal in performance to human eyes, are demonstrated for a lens with 3 mm aperture radius, while applying voltages below 500 V. The presented model, design rules, and fabrication methods address central challenges of soft electrostatic actuators and optical systems, and pave the way toward autonomous bio‐inspired robots and machines.

show abstract

“…[ 28–30 ] This actuation strategy, which so far has been demonstrated for miniature (up to a few millimeters) tactile interfaces with displacements lower than 1 mm, might be challenged for higher displacements by the need for a larger lateral size, due to the zipping effect required for pressurization. [ 29,30 ]…”

Section: Introductionmentioning

confidence: 99%

A Soft Touch: Wearable Tactile Display of Softness Made of Electroactive Elastomers

Frediani

Boys

Ghilardi

et al. 2021

Adv Materials Technologies

View full text Add to dashboard Cite

Fingertip‐mounted tactile displays of softness are needed for various virtual‐ or augmented‐reality applications such as surgical simulation, tele‐operation, computer‐aided design, 3D model exploration, and tele‐presence. Displaying a virtual softness on a fingertip requires the generation of quasi‐static large displacements at moderate forces (as opposed to high‐frequency small vibrations at high forces), via a deformable surface, to control both the contact area and the indentation depth of the skin. State‐of‐the‐art actuation technologies are unable to combine simple structure, low weight, and low size, as well as energy efficiency and silent operation. Here, the progress on the development of a non‐vibratory display of softness made of electroactive polymers is reported. It consists of a hydrostatically coupled dielectric elastomer actuator, shaped as a bubble interfaced to the fingertip, having a weight of 6 g. Prototypes can generate displacements up to 3.5 mm and forces up to 1 N. By combining this technology with a compact hand tracking sensor, a simple and cost‐effective virtual‐reality system is demonstrated. A psychophysical study engaging 15 volunteers in poke and pinch tactile tasks shows that users can properly distinguish between different stimuli rendered by the display, with an accuracy correlated to the perceptual difficulty of the tactile comparative task.

show abstract

Multimode Hydraulically Amplified Electrostatic Actuators for Wearable Haptics

Cited by 164 publications

References 39 publications

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Soft Tunable Lenses Based on Zipping Electroactive Polymer Actuators

A Soft Touch: Wearable Tactile Display of Softness Made of Electroactive Elastomers

Contact Info

Product

Resources

About