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Abstract

Teleoperation in soft robotics can endow soft robots with the ability to perform complex tasks through human–robot interaction. In this study, we propose a teleoperated anthropomorphic soft robot hand with variable degrees of freedom (DOFs) and a metamorphic palm. The soft robot hand consists of four pneumatic-actuated fingers, which can be heated to tune stiffness. A metamorphic mechanism was actuated to morph the hand palm by servo motors. The human fingers' DOF, gesture, and muscle stiffness were collected and mapped to the soft robotic hand through the sensory feedback from surface electromyography devices on the jib. The results show that the proposed soft robot hand can generate a variety of anthropomorphic configurations and can be remotely controlled to perform complex tasks such as primitively operating the cell phone and placing the building blocks. We also show that the soft hand can grasp a target through the slit by varying the DOFs and stiffness in a trail.

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References

, Ma

, Liang

, et al. Vision-based teleoperation of shadow dexterous hand using end-to-end deep neural network. In: 2019 International Conference on Robotics and Automation (ICRA), Montreal, QC, Canada. IEEE; May 2019; pp. 416–422.

Ferre

, Aracil

, Balaguer

, et al. Advances in Telerobotics, Vol. 31. Springer: Berlin, Heidelberg;. 2007.

Chen

, Shao

, Xie

, et al. Soft origami gripper with variable effective length. Adv Intell Syst, 2021; 3(10):2000251.

Zhou

, Chen

, Li

DCF

, et al. 50 benchmarks for anthropomorphic hand function-based dexterity classification and kinematics-based hand design. In: 2020 IEEE/RSJ International Conference on Intelligent Robots and Systems (IROS), Las Vegas, NV, USA. IEEE; October 2020; pp. 9159–9165.

Wang

, Fares

, Le

, et al. A novel soft robotic hand design with human-inspired soft palm. IEEE Robot Autom Magaz, 2021; 28(2):37–49.

Rohling

, Hollerbach

, Jacobsen

. Optimized fingertip mapping: A general algorithm for robotic hand teleoperation. Presence Teleoperat Virt Environ, 1993; 2(3):203–220.

Cerulo

, Ficuciello

, Lippiello

, Siciliano

. Teleoperation of the SCHUNK S5FH under-actuated anthropomorphic hand using human hand motion tracking. Robot Auton Syst, 2017; 89:75–84.

Ekvall

, Kragic

. Interactive grasp learning based on human demonstration. In: IEEE International Conference on Robotics and Automation, 2004. Proceedings. ICRA’04, New Orleans, LA, USA. IEEE; April 2004; Vol. 4; pp. 3519–3524.

Meeker

, Rasmussen

, Ciocarlie

. Intuitive hand teleoperation by novice operators using a continuous teleoperation subspace. In: 2018 IEEE International Conference on Robotics and Automation (ICRA), Brisbane, QLD, Australia. IEEE; May 2018; pp. 5821–5827.

10.

Fang

, Ma

, Wang

, Sun

. Vision-based posture-consistent teleoperation of robotic arm using multi-stage deep neural network. Robot Auton Syst, 2020; 131:103592.

11.

Schäfer

, Reis

, Stricker

. Controlling teleportation-based locomotion in virtual reality with hand gestures: A comparative evaluation of two-handed and one-handed techniques. Electronics, 2021; 10(6):715.

12.

Zi-You

, Xin-Gang

, Bi

, et al. Review of sEMG-based motion intent recognition methods in non-ideal conditions. Acta Automatica Sinica, 2021; 47(5):955–969.

13.

Geng

, Du

, Jin

, et al. Gesture recognition by instantaneous surface EMG images. Sci Rep, 2016; 6(1):36571.

14.

Wei

, Wong

, Du

, et al. A multi-stream convolutional neural network for sEMG-based gesture recognition in muscle-computer interface. Pattern Recogn Lett, 2019; 119:131–138.

15.

Olsson

, Malešević

, Björkman

, Antfolk

End-to-end estimation of hand-and wrist forces from raw intramuscular EMG signals using LSTM networks. Front Neurosci, 2021; 15:777329.

16.

Jiang

, Liu

, Fan

, et al. Random channel masks for regularization of least squares-based finger EMG-force modeling to improve cross-day performance. IEEE Trans Neural Syst Rehabil Eng, 2022; 30:2157–2167.

17.

, Chen

, Zhang

, et al. A novel myoelectric control scheme supporting synchronous gesture recognition and muscle force estimation. IEEE Trans Neural Syst Rehabil Eng, 2022; 30:1127–1137.

18.

Baldacchino

, Jacobs

, Anderson

, et al. Simultaneous force regression and movement classification of fingers via surface EMG within a unified Bayesian framework. Front Bioeng Biotechnol, 2018; 6:13.

19.

Zhang

, Fang

, Zhang

, et al. Simultaneous estimation of joint angle and interaction force towards sEMG-driven human-robot interaction during constrained tasks. Neurocomputing, 2022; 484:38–45.

20.

, Liu

, Zhou

, et al. Simultaneous hand/wrist motion recognition and continuous grasp force estimation based on nonlinear spectral sEMG features for transradial amputees. Biomed Signal Process Control, 2023; 85:105044.

21.

Hao

, Wang

, Xie

, et al. A eutectic-alloy-infused soft actuator with sensing, tunable degrees of freedom, and stiffness properties. J Micromech Microeng, 2018; 28(2):024004.

22.

Hao

, Liu

, et al. A soft gripper with programmable effective length, tactile and curvature sensory feedback. Smart Mater Struct, 2020; 29(3):035006.

23.

Emmanouil

, Wei

, Dai

. Spherical trigonometry constrained kinematics for a dexterous robotic hand with an articulated palm. Robotica, 2016; 34(12):2788–2805.

24.

Dai

, Wang

. Geometric analysis and synthesis of the metamorphic robotic hand. J Mech Des, 2007; 129(11):1191–1197.

25.

Fang

, Wang

, Sun

, et al. Simultaneous sEMG recognition of gestures and force levels for interaction with prosthetic hand. IEEE Trans Neural Syst Rehabil Eng, 2022; 30:2426–2436.

26.

LeCun

, Boser

, Denker

, et al. Backpropagation applied to handwritten zip code recognition. Neural Comput, 1989; 1(4):541–551.

27.

Yang

, Liu

. An EMG-based deep learning approach for multi-DOF wrist movement decoding. IEEE Trans Industr Electr, 2021; 69(7):7099–7108.

28.

, Chen

, Sheng

, Zhu

. Wrist torque estimation via electromyographic motor unit decomposition and image reconstruction. IEEE J Biomed Health Inform, 2020; 25(7):2557–2566.

29.

Qin

, Stapornchaisit

, He

, et al. Multi–joint angles estimation of forearm motion using a regression model. Front Neurorobot, 2021; 15:685961.

30.

, Zhang

, Xu

, et al. A soft neuroprosthetic hand providing simultaneous myoelectric control and tactile feedback. Nat Biomed Eng, 2023; 7(4):589–598.

31.

Wang

, Abu-Dakka

, Le

, et al. A novel design of soft robotic hand with a human-inspired soft palm for dexterous grasping. 2020; arXiv preprint arXiv:2009.00979.

32.

Feix

, Romero

, Schmiedmayer

, et al. The grasp taxonomy of human grasp types. IEEE Trans Hum Mach Syst, 2015; 46(1):66–77.

33.

Stanley

, Gwilliam

, Okamura

. Haptic jamming: A deformable geometry, variable stiffness tactile display using pneumatics and particle jamming. In: 2013 World Haptics Conference (WHC), Daejeon, Korea (South). IEEE; April 2013; pp. 25–30.

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Teleoperation of an Anthropomorphic Robot Hand with a Metamorphic Palm and Tunable-Stiffness Soft Fingers

Abstract

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