Finger‐Skin‐Inspired Flexible Optical Sensor for Force Sensing and Slip Detection in Robotic Grasping

Jiang, Chengpeng; Zhang, Zhang; Pan, Jie; Wang, Yancheng; Zhang, Lei; Tong, Liming

doi:10.1002/admt.202100285

Cited by 47 publications

(24 citation statements)

References 47 publications

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“…7−15 Although these sensors can feed back the grasping behavior of the manipulator to a certain extent, their practical application in the field of robotics is restricted by high manufacturing cost, parasitic effect, complex circuit, and signal crosstalk. 16,17 Additionally, these sensors themselves have a relatively large volume and mass. When they are installed on a robotic manipulator, they will reduce the flexibility of the device and increase energy consumption in the actual operation.…”

Section: ■ Introductionmentioning

confidence: 99%

Coaxial Graphene/MXene Microfibers with Interfacial Buffer-Based Lightweight Distance Sensors Assisting Lossless Grasping of Fragile and Deformable Objects

Jiang

et al. 2023

Langmuir

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Lossless and efficient robotic grasping is becoming increasingly important with the widespread application of intelligent robotics in warehouse transportation, human healthcare, and domestic services. However, current sensors for feedback of grasping behavior are greatly restricted by high manufacturing cost, large volume and mass, complex circuit, and signal crosstalk. To solve these problems, here, we prepare lightweight distance sensor-based reduced graphene oxide (rGO)/ MXene−rGO coaxial microfibers with interface buffer to assist lossless grasping of a robotic manipulator. The as-fabricated distance microsensor exhibits a high sensitivity of 91.2 m −1 in the distance range of 50−300 μm, a fast response time of 116 ms, a high resolution of 5 μm, and good stability in 500 cycles. Furthermore, the highperformance and lightweight microsensor is installed on the robotic manipulator to reflect the grasp state by the displacement imposed on the sensor. By establishing the correlation between the microsensing signal and the grasp state, the safe, non-destructive, and effective grasp and release of the target can be achieved. The lightweight and highpowered distance sensor displays great application prospects in intelligent fetching, medical surgery, multi-spindle automatic machines, and cultural relics excavation.

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Section: ■ Introductionmentioning

confidence: 99%

Coaxial Graphene/MXene Microfibers with Interfacial Buffer-Based Lightweight Distance Sensors Assisting Lossless Grasping of Fragile and Deformable Objects

Jiang

et al. 2023

Langmuir

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“…Tactile sensors have played an important role in medical treatment [ 1 , 2 ], artificial skin [ 3 , 4 ], robot tactile feedback [ 5 ], and human–machine interaction [ 6 , 7 ]. With the discovery of new materials and the development of microelectronics, tactile sensors based on a variety of transducing mechanisms such as resistance [ 8 , 9 , 10 , 11 ], capacitance [ 12 , 13 , 14 , 15 ], piezoelectric [ 16 , 17 , 18 , 19 ], and optics [ 20 , 21 , 22 ] have been developed.…”

Section: Introductionmentioning

confidence: 99%

Recent Progress of Biomimetic Tactile Sensing Technology Based on Magnetic Sensors

Man

Chen

2022

Biosensors

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In the past two decades, biomimetic tactile sensing technology has been a hot spot in academia. It has prospective applications in many fields such as medical treatment, health monitoring, robot tactile feedback, and human–machine interaction. With the rapid development of magnetic sensors, biomimetic tactile sensing technology based on magnetic sensors (which are called magnetic tactile sensors below) has been widely studied in recent years. In order to clarify the development status and application characteristics of magnetic tactile sensors, this paper firstly reviews the magnetic tactile sensors from three aspects: the types of magnetic sensors, the sources of magnetic field, and the structures of sensitive bodies used in magnetic tactile sensors. Secondly, the development of magnetic tactile sensors in four applications of robot precision grasping, texture characterization, flow velocity measurement, and medical treatment is introduced in detail. Finally, this paper analyzes technical difficulties and proposes prospective research directions for magnetic tactile sensors.

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“…[9] Imitating the structural characteristics of human finger skin, Jiang et al proposed a finger-skin inspired flexible optical sensor based on optical microfiber. [10] The application of flexible material sensors for force feedback has a better application prospect. [11,12] Due to the characteristics of flexibility, electromagnetic immunity, high sensitivity and light weight, the application of optical fibers as sensing elements is growing fast.…”

Section: Introductionmentioning

confidence: 99%

Smart laparoscopic grasper integrated with fiber Bragg grating based tactile sensor for real‐time force feedback

Wang

Zhang

Liu

et al. 2022

Journal of Biophotonics

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Minimally invasive surgery, such as laparoscopic surgery, has developed rapidly due to its small wound, less bleeding and quick recovery. However, a lack of force feedback, which leads to tissue damage, is still unsolved. Many sensors have been used to offer force feedback but still limited by their large size, low security and high complexity. Based on the advantages of small size, high sensitivity and immunity to electromagnetic interferences, we propose a tactile sensor integrated with fiber Bragg gratings (FBGs) at the tip of laparoscopic grasper to offer real‐time force feedback in the laparoscopic surgery. The tactile sensor shows a force sensitivity of 0.076 nm/N with a repeatable accuracy of 0.118 N. A bench test is conducted in a laparoscopic training box to verify its feasibility. Test results illustrate that gripping force exerted on the laparoscopic grasper in terms of peak and standard deviation values reduce significantly for the novice subjects with force feedback compared to those without force feedback. The proposed sensor integrated at the tip of the laparoscopic grasper demonstrates a better control of the gripping force among the novice surgeons and indicates that the smart grasper can help surgeons achieve precise gripping force to reduce unnecessary tissue trauma.

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Finger‐Skin‐Inspired Flexible Optical Sensor for Force Sensing and Slip Detection in Robotic Grasping

Cited by 47 publications

References 47 publications

Coaxial Graphene/MXene Microfibers with Interfacial Buffer-Based Lightweight Distance Sensors Assisting Lossless Grasping of Fragile and Deformable Objects

Coaxial Graphene/MXene Microfibers with Interfacial Buffer-Based Lightweight Distance Sensors Assisting Lossless Grasping of Fragile and Deformable Objects

Recent Progress of Biomimetic Tactile Sensing Technology Based on Magnetic Sensors

Smart laparoscopic grasper integrated with fiber Bragg grating based tactile sensor for real‐time force feedback

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