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Research Article
Footwear-Based Assistive Technology for Lower Limb Amputees
M. Nila Nandhini1
C.P. Bertilla Madonna2
P.S. Supraja3
Vasantha Varshini4
1Assistant professor, Biomedical Instrumentation Engineering, Avinashilingam Institute for home science and higher education for women, Coimbatore, Tamilnadu, India. 234 Biomedical Instrumentation Engineering, Avinashilingam Institute for home science and higher education for women, Coimbatore, Tamilnadu, India.
Published Online: May-August 2024
Pages: 05-10
Cite this article
↗ https://www.doi.org/10.59256/indjcst.20240302001
References
1. Nur Azah Hamzaid.Et:al., “Sensory Systems in Micro-Processor Controlled Prosthetic Leg” Institute of Electrical and Electronics Engineers
(IEEE), Issue.September 2019.
2. He Huang.Et.al.,“Continuous Locomotion-Mode Identification for Prosthetic Legs Based on Neuromuscular–Mechanical Fusion” Institute
of Electrical and Electronics Engineers (IEEE), Issue. July 2011.
3. Dongfang Xu.Et.al.,”Real-Time On-Board Recognition of Continuous Locomotion Modes for Amputees With Robotic Transtibial Prostheses”
Institute of Electrical and Electronics Engineers (IEEE), Issue. September 2018.
4. Muhammad Jawad Khan.Et.al., “Control system design for a prosthetic leg using series damping actuator” Institute of Electrical and
Electronics Engineers (IEEE), Issue. October 2012.
5. Kyle R. Embry.Et.al., “Analysis of Continuously Varying Kinematics for Prosthetic Leg Control Applications” Institute of Electrical and
Electronics Engineers (IEEE), Issue. December 2020.
6. Control system design for a prosthetic leg using series damping actuator Publisher: IEEE (2012) Muhammad Jawad Khan; Muhammad
Raheel Afzal; Noman Naseer; Zafar Ullah Koreshi.
7. Analysis of Continuously Varying Kinematics for Prosthetic Leg Control Applications Publisher: IEEE (2020) Kyle R. Embry; Robert D.
Gregg.
8. Continuous Locomotion-Mode Identification for Prosthetic Legs Based on Neuromuscular–Mechanical Fusion Publisher: IEEE (2011 ) He
Huang; Fan Zhang; Levi J. Hargrove; Zhi Dou; Daniel R. Rogers; Kevin B. Englehart.
9. Real-Time On-Board Recognition of Continuous Locomotion Modes for Amputees With Robotic Transtibial Prostheses Publisher: IEEE
(2018) Dongfang Xu; Yanggang Feng; Jingeng Mai; Qining Wang.
10. Sensory Systems in Microprocessor Controlled Prosthetic Leg Publisher: IEEE(2019) Nur Azah Hamzaid; Nur Hidayah Mohd
Yusof; Farahiyah Jasni.
11. Foot/ankle roll-over characteristics in different heel heights during level walking .World Congress on Medical Physics and Biomedical
Engineering 2006, Choi, H.S., Kim, Y.H., 2007.
12. High heels on human stability and plantar pressure distribution: Effects of heel height and shoe wearing experience. Hapsari, V. D., Xiong,
S., Yang, S., 2014.
13. Johns Hopkins students create high-heeled prosthetic. Washington Post, August 9, 2016, McDaniels, A.K., 2016.
14. Effects of adding weight to the torso on roll-over characteristics of walking, Hansen, A. H., Childress, D. S., 2005.
15. Roll-over shapes of human locomotor systems: Effects of walking speed. Hansen, A. H., Childress, D. S., Knox, E. H., 2004.
(IEEE), Issue.September 2019.
2. He Huang.Et.al.,“Continuous Locomotion-Mode Identification for Prosthetic Legs Based on Neuromuscular–Mechanical Fusion” Institute
of Electrical and Electronics Engineers (IEEE), Issue. July 2011.
3. Dongfang Xu.Et.al.,”Real-Time On-Board Recognition of Continuous Locomotion Modes for Amputees With Robotic Transtibial Prostheses”
Institute of Electrical and Electronics Engineers (IEEE), Issue. September 2018.
4. Muhammad Jawad Khan.Et.al., “Control system design for a prosthetic leg using series damping actuator” Institute of Electrical and
Electronics Engineers (IEEE), Issue. October 2012.
5. Kyle R. Embry.Et.al., “Analysis of Continuously Varying Kinematics for Prosthetic Leg Control Applications” Institute of Electrical and
Electronics Engineers (IEEE), Issue. December 2020.
6. Control system design for a prosthetic leg using series damping actuator Publisher: IEEE (2012) Muhammad Jawad Khan; Muhammad
Raheel Afzal; Noman Naseer; Zafar Ullah Koreshi.
7. Analysis of Continuously Varying Kinematics for Prosthetic Leg Control Applications Publisher: IEEE (2020) Kyle R. Embry; Robert D.
Gregg.
8. Continuous Locomotion-Mode Identification for Prosthetic Legs Based on Neuromuscular–Mechanical Fusion Publisher: IEEE (2011 ) He
Huang; Fan Zhang; Levi J. Hargrove; Zhi Dou; Daniel R. Rogers; Kevin B. Englehart.
9. Real-Time On-Board Recognition of Continuous Locomotion Modes for Amputees With Robotic Transtibial Prostheses Publisher: IEEE
(2018) Dongfang Xu; Yanggang Feng; Jingeng Mai; Qining Wang.
10. Sensory Systems in Microprocessor Controlled Prosthetic Leg Publisher: IEEE(2019) Nur Azah Hamzaid; Nur Hidayah Mohd
Yusof; Farahiyah Jasni.
11. Foot/ankle roll-over characteristics in different heel heights during level walking .World Congress on Medical Physics and Biomedical
Engineering 2006, Choi, H.S., Kim, Y.H., 2007.
12. High heels on human stability and plantar pressure distribution: Effects of heel height and shoe wearing experience. Hapsari, V. D., Xiong,
S., Yang, S., 2014.
13. Johns Hopkins students create high-heeled prosthetic. Washington Post, August 9, 2016, McDaniels, A.K., 2016.
14. Effects of adding weight to the torso on roll-over characteristics of walking, Hansen, A. H., Childress, D. S., 2005.
15. Roll-over shapes of human locomotor systems: Effects of walking speed. Hansen, A. H., Childress, D. S., Knox, E. H., 2004.
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