Stretchable distributed fiber-optic sensors

Bai, Hedan; Li, Shuo; Barreiros, José Augusto Lima; Tu, Yaqi; Pollock, Clifford R.; Shepherd, Robert F.

doi:10.1126/science.aba5504

Cited by 313 publications

(260 citation statements)

References 32 publications

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“…[ 1–3 ] Although many EM interference (EMI) shielding materials have been developed for electronics, military, and infrastructural applications, they are hardly utilized in the EMI shielding of human body because the flexibility and transparence are generally needed to satisfy the wearable requirements. [ 4–6 ] In contrast, transparent EMI shielding materials are highly desired for special electronic devices and infrastructures which require transparence in visible and near‐infrared regions, for example, the windows of light‐controlled devices and aircrafts. [ 7 ] In addition, the fast development of wearable electronics also needs flexible EMI shielding materials.…”

Section: Introductionmentioning

confidence: 99%

Transparent, Flexible, and Stable Polyethersulfone/Copper‐Nanowires/Polyethylene Terephthalate Sandwich‐Structured Films for High‐Performance Electromagnetic Interference Shielding

et al. 2021

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Transparent and flexible electromagnetic interference (EMI) shielding materials are highly desirable in wearable electronic devices and optical windows of aircrafts. Herein, transparent and flexible EMI shielding films are prepared by the use of Cu nanowires (Cu NWs). The films have a sandwiched structure composed of polyethersulfone (PES), Cu NW network, and polyethylene terephthalate (PET). The coating of PES strengthens the Cu NW contact, protects Cu NWs from the oxidation, and reduces the surface average roughness. The PES/Cu NWs/PET sandwich‐structured films show an EMI shielding effectiveness (SE) of 22 dB with an optical transmittance of 73%, and an even higher EMI SE of 30 dB in the entire X band with the optical transmittance of 67%. The PES/Cu NWs/PET sandwich‐structured films also exhibit superior flexibility, very good chemical stability in basic, acidic, and strong oxidizing solutions, as well as long‐term stability in ambient condition. This PES/Cu NWs/PET sandwich‐structured films are a promising transparent flexible EMI shielding material in wearable electronics and optical windows of aircrafts.

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Section: Introductionmentioning

confidence: 99%

Transparent, Flexible, and Stable Polyethersulfone/Copper‐Nanowires/Polyethylene Terephthalate Sandwich‐Structured Films for High‐Performance Electromagnetic Interference Shielding

et al. 2021

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“…[ 316 ] However, the relatively large cross‐sectional area (about 3 mm × 3 mm) of the reported fibers still has to be further miniaturized before their use in microscale soft devices, and it is difficult to use them to measure the local strain of soft devices, which has been resolved by a follow‐up work recently proposed. [ 317 ] Also, the fibers are generally embedded in soft materials in a 'U’ shape, which may be unfriendly to some segmented and slender SSIs. The 'I'‐shaped optical waveguide sensors based on a similar principle used in SSIs were later proposed by Al Jaber et al [ 314 ] But these sensors often have to align to a specific light source or camera at the instrument's end, which may affect the operation of possible end manipulators.…”

Section: Human–robot Interactionmentioning

confidence: 99%

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Zhu

Lyu

et al. 2021

Advanced Intelligent Systems

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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.

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“…Magnetic field sensors mounted to glasses pick up small movements for individuals with spinal cord injuries (adapted from Ref. [70] with permission, copyright John Wiley & Sons, 2020) polymer or fiber optic cable, resulting in a relationship between strain and light intensity [53,[82][83][84]. These flexible sensors offer low susceptability to electromagnetic interference and a fast response [18].…”

Section: Optical Sensing Skinsmentioning

confidence: 99%

Soft Tactile Sensing Skins for Robotics

2021

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Purpose of Review Soft electronic skins (E-skins) capable of tactile pressure sensing have the potential to endow robotic systems with many of the same somatosensory properties of natural human skin. In this progress report, we review recent progress in creating soft tactile pressure sensing skins to give robots a sense of touch that resembles human skin sensing.Recent Findings For soft tactile pressure sensing skins, researchers have focused on five main sensing principles: (1) resistive; (2) capacitive; (3) magnetic; (4) barometric; and (5) optical. The combination of these traditional sensing techniques, along with the use of soft materials such as liquid metal and magnetic elastomers, has improved the perception capabilities and mechanical characteristics of artificial skin. In addition, the implementation of artificial intelligence and machine learning algorithms for data processing give robotic systems with these soft sensing skins an enhanced sense of touch.Summary E-skins for tactile sensing have a central role in a range of robotic applications, from haptics and teleoperation to bio-inspired soft robots. For many of these applications, E-skins must be soft, thin, flexible, stretchable, and lightweight so that they can be mounted on a robot, incorporated into clothing, or placed on human skin without interfering with mobility or contact mechanics. Significant research has been conducted on sensing techniques that can allow a robot to achieve a sense of human touch, with important progress being made in force feedback sensing, texture recognition, and spatial acuity. We begin by covering principles of tactile sensing in humans, robotics, and human-machine interaction. This is followed by an overview of soft material transducers capable of pressure and force sensing. This includes resistive, capacitive, magnetic, barometric, and optical sensing techniques. We close with a summary of emerging trends in sensor design and implementations for applications in robotics.

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Stretchable distributed fiber-optic sensors

Cited by 313 publications

References 32 publications

Transparent, Flexible, and Stable Polyethersulfone/Copper‐Nanowires/Polyethylene Terephthalate Sandwich‐Structured Films for High‐Performance Electromagnetic Interference Shielding

Transparent, Flexible, and Stable Polyethersulfone/Copper‐Nanowires/Polyethylene Terephthalate Sandwich‐Structured Films for High‐Performance Electromagnetic Interference Shielding

Intelligent Soft Surgical Robots for Next‐Generation Minimally Invasive Surgery

Soft Tactile Sensing Skins for Robotics

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