| GRAU A, INDRI M, BELLO L L, et al. Robots in Industry: The Past, Present, and Future of a Growing Collaboration with Humans[J]. IEEE Industrial Electronics Magazine, 2021, 15(1): 50-61. |
| MCLEAY F, OSBURG V S, YOGANATHAN V, et al. Replaced by a Robot: Service Implications in the Age of the Machine[J]. Journal of Service Research, 2021, 24(1): 104-121. |
| ROSHANIANFARD A, NOGUCHI N. Pumpkin Harvesting Robotic End-Effector[J]. Computers and Electronics in Agriculture, 2020, 174: 105503. |
| GAO J, ZHANG F, ZHANG J X, et al. Development and Evaluation of a Pneumatic Finger-Like End-Effector for Cherry Tomato Harvesting Robot in Greenhouse[J]. Computers and Electronics in Agriculture, 2022, 197: 106879. |
| TAWK C, SARIYILDIZ E, ALICI G. Force Control of a 3D Printed Soft Gripper with Built-in Pneumatic Touch Sensing Chambers[J]. Soft Robotics, 2022, 9(5): 970-980. |
| XIE Z X, DOMEL A G, AN N, et al. Octopus Arm-Inspired Tapered Soft Actuators with Suckers for Improved Grasping[J]. Soft Robotics, 2020, 7(5): 639-648. |
| MANTI M, HASSAN T, PASSETTI G, et al. A Bioinspired Soft Robotic Gripper for Adaptable and Effective Grasping[J]. Soft Robotics, 2015, 2(3): 107-116. |
| GAO S, DAI Y N, NATHAN A. Tactile and Vision Perception for Intelligent Humanoids[J]. Advanced Intelligent Systems, 2022, 4(2): 2100074. |
| TANG W, LIU R, SHI Y B, et al. From Finger Friction to Brain Activation: Tactile Perception of the Roughness of Gratings[J]. Journal of Advanced Research, 2020, 21: 129-139. |
| ZHANG B H, XIE Y X, ZHOU J, et al. State-of-the-Art Robotic Grippers, Grasping and Control Strategies, as Well as Their Applications in Agricultural Robots: A Review[J]. Computers and Electronics in Agriculture, 2020, 177: 105694. |
| NARENDIRAN A, GEORGE B. Capacitive Tactile Sensor with Slip Detection Capabilities for Robotic Applications[C]//2015 IEEE International Instrumentation and Measurement Technology Conference (I2MTC) Proceedings, May 11-14, 2015, Pisa, Italy. IEEE, 2015: 464-469. |
| JAVAID S, HIRANO H, TANAKA S, et al. Surface Covering Structure and Active Sensing with MEMS-CMOS Integrated 3-Axis Tactile Sensors for Object Slip Detection and Texture Recognition[C]//2021 21st International Conference on Solid-State Sensors, Actuators and Microsystems (Transducers), June 20-24, 2021, Orlando, FL, USA. IEEE, 2021: 222-225. |
| LI X, MING Z, WANG K Y. Design of Multifunctional Touch and Slip Sensor System Based on PVDF Piezoelectric Film[J]. Journal of Physics: Conference Series, 2021, 1838(1): 012024. |
| FENG J H, JIANG Q. Slip and Roughness Detection of Robotic Fingertip Based on FBG[J]. Sensors and Actuators A: Physical, 2019, 287: 143-149. |
| SHAN B C, LIU C X, CHEN R H, et al. A Self-Powered Sensor for Detecting Slip State and Pressure of Underwater Actuators Based on Triboelectric Nanogenerator[J]. Materials Today Nano, 2023, 24: 100391. |
| WANG X D, LIANG J M, XIAO Y X, et al. A Flexible Slip Sensor Using Triboelectric Nanogenerator Approach[J]. Journal of Physics Conference, 2018, 986: 012009. |
| SOTER G, CONN A, HAUSER H, et al. Bodily Aware Soft Robots: Integration of Proprioceptive and Exteroceptive Sensors[C]//2018 IEEE International Conference on Robotics and Automation (ICRA), May 21-25, 2018, Brisbane, QLD, Australia. IEEE, 2018: 2448-2453. |
| YAN G, SCHMITZ A, TOM O T P, et al. Detection of Slip from Vision and Touch[C]//2022 International Conference on Robotics and Automation (ICRA), May 23-27, 2022, Philadelphia, PA, USA. IEEE, 2022: 3537-3543. |
| QU J T, MAO B J, LI Z K, et al. Recent Progress in Advanced Tactile Sensing Technologies for Soft Grippers[J]. Advanced Functional Materials, 2023, 33(41): 2306249. |
| ZHU J X, ZHU M L, SHI Q F, et al. Progress in TENG Technology-A Journey from Energy Harvesting to Nanoenergy and Nanosystem[J]. EcoMat, 2020, 2(4): e12058. |
| ZHANG R Y, OLIN H. Material Choices for Triboelectric Nanogenerators: A Critical Review[J]. EcoMat, 2020, 2(4): e12062. |
| CHENG T H, SHAO J J, WANG Z L. Triboelectric Nanogenerators[J]. Nature Reviews Methods Primers, 2023, 3: 39. |
| FAN F R, TIAN Z Q, WANG Z L. Flexible Triboelectric Generator[J]. Nano Energy, 2012, 1(2): 328-334. |
| CHEN J, WANG Z L. Reviving Vibration Energy Harvesting and Self-Powered Sensing by a Triboelectric Nanogenerator[J]. Joule, 2017, 1(3): 480-521. |
| WU Z Y, CHENG T H, WANG Z L. Self-Powered Sensors and Systems Based on Nanogenerators[J]. Sensors, 2020, 20(10): 2925. |
| HOU W C, TANG X L, FANG L, et al. Self-Driven Real-Time Angle Vector Sensor as Security Dialer Based on Bi-Directional Backstop Triboelectric Nanogenerator[J]. Nano Energy, 2022, 99: 107430. |
| JING Q S, XIE Y N, ZHU G, et al. Self-Powered Thin-Film Motion Vector Sensor[J]. Nature Communications, 2015, 6: 8031. |
| DENG J Z, WU Z Y, HUO X Q, et al. Triboelectric Based Smart Ceramic Tiles[J]. Nano Energy, 2024, 128: 109928. |
| GUI Y G, ZHANG W H, LIU S Y, et al. Self-Driven Sensing of Acetylene Powered by a Triboelectric-Electromagnetic Hybrid Generator[J]. Nano Energy, 2024, 124: 109498. |
| HE S S, GUI Y G, WANG Y F, et al. CuO/TiO2/MXene-Based Sensor and SMS-TENG Array Integrated Inspection Robots for Self-Powered Ethanol Detection and Alarm at Room Temperature[J]. ACS Sensors, 2024, 9(3): 1188-1198. |
| GUI Y G, HE S S, WANG Y F, et al. MOF-Derived Porous Ni/C Material for High-Performance Hybrid Nanogenerator and Self-Powered Wearable Sensor[J]. Composites Part A: Applied Science and Manufacturing, 2023, 168: 107492. |
| CHEN H T, SONG Y, GUO H, et al. Hybrid Porous Micro Structured Finger Skin Inspired Self-Powered Electronic Skin System for Pressure Sensing and Sliding Detection[J]. Nano Energy, 2018, 51: 496-503. |
| YUAN Z Q, SHEN G Z, PAN C F, et al. Flexible Sliding Sensor for Simultaneous Monitoring Deformation and Displacement on a Robotic Hand/Arm[J]. Nano Energy, 2020, 73: 104764. |
| SHI S, JIANG Y W, XU Q H, et al. A Self-Powered Triboelectric Multi-Information Motion Monitoring Sensor and Its Application in Wireless Real-Time Control[J]. Nano Energy, 2022, 97: 107150. |
| QIU Y, SUN S S, WANG X E, et al. Nondestructive Identification of Softness via Bioinspired Multisensory Electronic Skins Integrated on a Robotic Hand[J]. NPJ Flexible Electronics, 2022, 6: 45. |
| GAO S, HAN Q K, JIANG Z Y, et al. Triboelectric Based High-Precision Self-Powering Cage Skidding Sensor and Application on Main Bearing of Jet Engine[J]. Nano Energy, 2022, 99: 107387. |
| XIE Z J, WANG Y, WU R S, et al. A High-Speed and Long-Life Triboelectric Sensor with Charge Supplement for Monitoring the Speed and Skidding of Rolling Bearing[J]. Nano Energy, 2022, 92: 106747. |
| PU X J, GUO H Y, TANG Q, et al. Rotation Sensing and Gesture Control of a Robot Joint via Triboelectric Quantization Sensor[J]. Nano Energy, 2018, 54: 453-460. |
| FRANCOMANO M T, ACCOTO D, GUGLIELMELLI E. Artificial Sense of Slip-A Review[J]. IEEE Sensors Journal, 2013, 13(7): 2489-2498. |
| GOH Q L, CHEE P S, LIM E H, et al. An AI-Assisted and Self-Powered Smart Robotic Gripper Based on Eco-EGaIn Nanocomposite for Pick-and-Place Operation[J]. Nanomaterials, 2022, 12(8): 1317. |
| LEI W Q, LU S, WANG Q, et al. A Method of Measuring Weak-Charge of Self-Powered Sensors Based on Triboelectric Nanogenerator[J]. Nano Energy, 2022, 95: 106997. |
| LU S, LEI W Q, WANG Q, et al. A Novel Approach for Weak Current Signal Processing of Self-Powered Sensor Based on TENG[J]. Nano Energy, 2022, 103: 107728. |
| NIU S M, WANG S H, LIN L, et al. Theoretical Study of Contact-Mode Triboelectric Nanogenerators as an Effective Power Source[J]. Energy & Environmental Science, 2013, 6(12): 3576-3583. |