TY - JOUR
T1 - Synthesis of a six-bar mechanism for generating knee and ankle motion trajectories using deep generative neural network
AU - Kapsalyamov, Akim
AU - Hussain, Shahid
AU - Brown, Nicholas A.T.
AU - Goecke, Roland
AU - Hayat, Munawar
AU - Jamwal, Prashant K.
N1 - Funding Information:
M. Hayat was supported by the Australian Research Council DECRA fellowship DE200101100 .
Funding Information:
This research work was supported in part by the Collaborative Research Program 2021–2023 of Nazarbayev University, Kazakhstan under grant number 021220CRP0222 .
Funding Information:
A. Kapsalyamov was supported by an Australian Government Research Training Program (RTP) Scholarship through University of Canberra.
Funding Information:
The authors wish to acknowledge Alfonso Hernández, CompMech, Department of Mechanical Engineering, UPVEHU for the permission to use the GIM® software. (www.ehu.es/compmech). All authors read and approved the final manuscript. A. Kapsalyamov was supported by an Australian Government Research Training Program (RTP) Scholarship through University of Canberra. This research work was supported in part by the Collaborative Research Program 2021–2023 of Nazarbayev University, Kazakhstan under grant number 021220CRP0222. M. Hayat was supported by the Australian Research Council DECRA fellowship DE200101100. Ethical Approval Not applicable
Publisher Copyright:
© 2022 Elsevier Ltd
PY - 2023/1
Y1 - 2023/1
N2 - Robotic exoskeletons have demonstrated their effectiveness in post-stroke gait rehabilitation therapy. Nevertheless, further research is being conducted to improve existing rehabilitation exoskeletons in terms of ease-of-use and innovative design. Previously, the adaptation of linkage-based mechanisms for rehabilitation exoskeletons has been considered an option. However, finding linkage parameters that will produce the required gait trajectories using a linkage-based exoskeleton, is quite challenging. It is furthermore challenging to obtain parameters of a linkage-based mechanism designed for a gait rehabilitation task that has to produce two trajectories (for knee and ankle joints) simultaneously. In this work, we propose Deep Generative Neural Networks (DGNN) to obtain a set of optimal dimensions and parameters for the Stephenson III six-bar linkage-based gait exoskeleton. The proposed methodology demonstrates high efficacy in determining the linkage parameters for various target trajectories. The proposed framework, once trained, can accurately predict mechanism parameters to achieve two joint trajectories simultaneously. Subsequent to developing the model, walking trajectories from healthy human subjects are given to the model to determine the optimal linkage dimensions of the gait rehabilitation exoskeleton. The proposed model can be used to assist designers in quickly determining the optimized linkage dimensions of linkage-based mechanisms that can provide various target trajectories.
AB - Robotic exoskeletons have demonstrated their effectiveness in post-stroke gait rehabilitation therapy. Nevertheless, further research is being conducted to improve existing rehabilitation exoskeletons in terms of ease-of-use and innovative design. Previously, the adaptation of linkage-based mechanisms for rehabilitation exoskeletons has been considered an option. However, finding linkage parameters that will produce the required gait trajectories using a linkage-based exoskeleton, is quite challenging. It is furthermore challenging to obtain parameters of a linkage-based mechanism designed for a gait rehabilitation task that has to produce two trajectories (for knee and ankle joints) simultaneously. In this work, we propose Deep Generative Neural Networks (DGNN) to obtain a set of optimal dimensions and parameters for the Stephenson III six-bar linkage-based gait exoskeleton. The proposed methodology demonstrates high efficacy in determining the linkage parameters for various target trajectories. The proposed framework, once trained, can accurately predict mechanism parameters to achieve two joint trajectories simultaneously. Subsequent to developing the model, walking trajectories from healthy human subjects are given to the model to determine the optimal linkage dimensions of the gait rehabilitation exoskeleton. The proposed model can be used to assist designers in quickly determining the optimized linkage dimensions of linkage-based mechanisms that can provide various target trajectories.
KW - Deep generative neural network
KW - Gait rehabilitation
KW - Machine learning
KW - Modified GAN
KW - Stephenson III six-bar linkage
UR - http://www.scopus.com/inward/record.url?scp=85140138623&partnerID=8YFLogxK
U2 - 10.1016/j.engappai.2022.105500
DO - 10.1016/j.engappai.2022.105500
M3 - Article
AN - SCOPUS:85140138623
SN - 0952-1976
VL - 117
JO - Engineering Applications of Artificial Intelligence
JF - Engineering Applications of Artificial Intelligence
IS - Part A
M1 - 105500
ER -