• Title/Summary/Keyword: LeSATA$^{(R)}$

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Development of Leg Stiffness Controllable Artificial Tendon Actuator (LeSATA®) Part I - Gait Analysis of the Metatarsophalangeal Joint Tilt Angles Soonhyuck - (하지강성 가변 인공건 액추에이터(LeSATA®)의 개발 Part I - Metatarsophalangeal Joint Tilt Angle의 보행분석 -)

  • Han, Gi-Bong;Eo, Eun-Kyung;Oh, Seung-Hyun;Lee, Soon-Hyuck;Kim, Cheol-Woong
    • Transactions of the KSME C: Technology and Education
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    • v.1 no.2
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    • pp.153-165
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    • 2013
  • The established gait analysis studies have regarded leg as one single spring. If we can design a knee-ankle actuating mechanism as a primary actuator for supporting knee extension, it might be possible to revolutionary store or release elastic strain energy, which is consumed during the gait cycle, and as a result leg stiffness is expected to increase. An ankle joint actuating mechanism that stores and releases the energy in ankle joint is expected to support and solve excessive artificial leg stiffness caused by the knee actuator (primary actuator) to a reasonable extent. If unnecessary kinematic energy is released with the artificial speed reduction control designed to prevent increase in gait speed caused by increase in time passed, it naturally brings question to the effectiveness of the actuator. As opposed to the already established studies, the authors are currently developing knee-ankle two actuator system under the concept of increasing lower limb stiffness by controlling the speed of gait in relative angular velocity of the two segments. Therefore, the author is convinced that compensatory mechanism caused by knee actuating must exist only in ankle joint. Ankle joint compensatory mechanism can be solved by reverse-examining the change in metatarso-phalangeal joint (MTPJ) tilt angle (${\theta}_1=0^{\circ}$, ${\theta}_2=17^{\circ}$, ${\theta}_3=30^{\circ}$) and the effect of change in gait speed on knee activity.