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Abstract

Background

In recent years, the large-scale epidemics and the increasing demand for rehabilitation generated a demand for remote rehabilitation, while digital twin provided technical support for home-based rehabilitation.

Objective

In order to monitor the operation status of rehabilitation robot and make dynamic adjustments, a virtual-real interaction system for an ankle rehabilitation robot (VRIS-ARR) is designed based on the digital twin theory, and its virtual-real interaction characteristics is researched.

Methods

The VRIS-ARR is consisted of physical layer, communication layer, virtual layer and application layer, and is designed by the application of software tools such as 3ds Max, Unity 3D, C#, Python. The database technology and multi-threaded development method are applied to realize the virtual-real interaction function of the system.

Results

The performance and function experiments of the VRIS-ARR are carried out, and the system has the characteristics of strong virtual-real interaction, which can work smoothly with high control accuracy and without obvious delay.

Conclusion

The experimental results indicate that the developed VRIS-ARR is very reliable between the ankle rehabilitation robot and the host computer.

Keywords

telerehabilitation digital twin home-based rehabilitation virtual-real interaction rehabilitation robot human–machine interaction

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References

Kolb

Harker

Gibb

. Principles of plasticity in the developing brain. Dev Med Child Neurol 2017; 59: 1218–1223.

Mayetin

Kucuk

. Design and experimental evaluation of a low cost, portable, 3-dof wrist rehabilitation robot with high physical human–robot interaction. J Intell Robot Syst 2022; 106: 65.

Falkowski

Osiak

Wilk

, et al. Study on the applicability of digital twins for home remote motor rehabilitation. Sensors 2023; 23: 11.

Gurbeta

Badnjevic

Maksimovic

, et al. A telehealth system for automated diagnosis of asthma and chronical obstructive pulmonary disease. J Am Med Inform Assoc 2018; 25: 1213–1217.

Modi

Sunny

MSH

Khan

MMR

, et al. Interactive IIoT-based 5DOF robotic arm for upper limb telerehabilitation. IEEE Access 2022; 10: 114919–114928.

Huang

, et al. Design and optimization of a body weight support system for lower-limb rehabilitation robots considering vibration characteristics. Struct Multidiscip Optim 2023; 66: 49.

Yang

Jin

Gao

, et al. Hierarchical trajectory deformation algorithm with hybrid controller for active lower limb rehabilitation. IEEE Robot Autom Lett 2024; 9: 6240–6247.

Semeraro

Lezoche

Panetto

, et al. Digital twin paradigm: a systematic literature review. Comput Ind 2021; 130: 103469.

Zhang

Wei

Zhang

, et al. CKAA: certificateless key-agreement authentication scheme in digital twin telemedicine environment. Trans Emerg Telecommun Technol 2024; 35: e4922.

10.

Dou

Wang

, et al. Research on the virtual–real interaction system and interaction characteristicsof a single-leg of quadruped robots based on digital twin. J Bionic Eng 2024: 1–17. doi: 10.1007/s42235-024-00573-9

11.

Park

Shin

Choi

, et al. Integration of an exoskeleton robotic system into a digital twin for industrial manufacturing applications. Robot Comput Integr Manuf 2024; 89: 102746.

12.

Yang

Cheng

, et al. Design and control of digital twin systems based on a unit level wheeled mobile robot. IEEE Trans Veh Technol 2023. doi: 10.1109/TVT.2023.3309029

13.

Liu

Wang

Zhang

, et al. Scene equipment saving and loading method for digital twin workshop. Appl Sci 2023; 13: 9809.

14.

Garg

Kuts

Anbarjafari

. Digital twin for Fanuc robots: industrial robot programming and simulation using virtual reality. Sustainability 2021; 13: 10336.

15.

Wang

, et al. Digital twin rehabilitation system based on self-balancing lower limb exoskeleton. Technol Health Care 2023; 31: 103–115.

16.

Gao

Zhao

Yang

, et al. A digital twin-driven trajectory tracking control method of a lower-limb exoskeleton. Control Eng Pract 2022; 127: 105271.

17.

Khan

MMR

Sunny

MSH

Ahmed

, et al. Development of a robot-assisted telerehabilitation system with integrated IIoT and digital twin. IEEE Access 2023; 11: 70174–70189.

18.

Tao

. Make more digital twins. Nature 2019; 573: 490–491.

19.

Tao

Wang

, et al. Digital twins and cyber–physical systems toward smart manufacturing and industry 4.0: correlation and comparison. Engineering 2019; 5: 653–661.

20.

Xie

Liu

Duan

, et al. A digital twin-based framework of motion control and state monitoring for pneumatic muscle. Recent Pat Mech Eng 2023; 16: 203–213.

21.

Wang

, et al. Research on digital twin technology of large-scale offshore wind power flexibledirect transmission system. J Phys Conf Ser 2023; 2450: 012046.

22.

Xie

Ren

Xiong

, et al. A trajectory tracking control of a robot actuated with pneumatic artificial muscles based on hysteresis compensation. IEEE Access 2020; 8: 80964–80977.

23.

Fan

Zhong

Zhao

, et al. BP Neural network tuned PID controller for position tracking of a pneumatic artificial muscle. Technol Health Care 2015; 23: S231–S238.

24.

Mujkić

Baralić

Ombašić

, et al. Machine intelligence in biomedical data modeling, processing, and analysis. In: 2022 11th Mediterranean Conference on Embedded Computing (MECO), Budva, Montenegro, 2022 Jun 7-10, pp.1–10: IEEE. 2022. doi: 10.1109/MECO55406.2022.9797164.

25.

Khalid

Naeem

Stasolla

, et al. Impact of AI-powered solutions in rehabilitation process: recent improvements and future trends. Int J Gen Med 2024; 17: 943–969.

26.

Latreche

Kelaiaia

Chemori

, et al. Reliability and validity analysis of MediaPipe-based measurement system for some human rehabilitation motions. Meas 2023; 214: 112826.

27.

Latreche

Kelaiaia

Chemori

, et al. A new home-based upper-and lower-limb telerehabilitation platform with experimental validation. Arab J for Sci and Eng 2023; 48: 10825–10840.

The virtual-real interaction system design and interaction characteristics research of an ankle rehabilitation robot based on digital twin

Abstract

Background

Objective

Methods

Results

Conclusion

Keywords

Get full access to this article

References