• Title/Summary/Keyword: Undulatory Locomotion

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Gaits Control for Skating Motion with Nonholonomic Constraint (논홀로노믹 구속을 고려한 스케이트 운동의 연속적인 생성방법)

  • Hwang, Chang-Soon
    • Journal of the Korean Society for Precision Engineering
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    • v.26 no.6
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    • pp.59-67
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    • 2009
  • This paper addresses the control method for skating motion with a nonholonomic constraint. In order to generate a human-like skating motion, the behaviors of motion are distinctively analyzed into transient state and steady state. A close investigation of the behaviors evolved the characteristic of successive motions with transient state and steady state. Simulation results were intuitively comprehensible, and the effectiveness of control method was demonstrated for skating motion.

Design and Implementation of Snake Robot with 8 Module (8개의 모듈로 구성된 뱀 로봇)

  • 박병진;서재용;하상형;전홍태
    • Proceedings of the IEEK Conference
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    • 2002.06e
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    • pp.189-192
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    • 2002
  • This paper has been studied the movement of snake robot. In this paper we developed a simulator to simulate the creeping locomotion of a snake robot. This Robot makes possible to analyze the creeping locomotion with the normal-direction slip coupled to gliding along the tangential direction. Using the nonslip condition of the wheels, the robot gains propulsion by means of constrained forces on the wheels caused by bending the joints. The results of simulations show that smooth lateral undulatory motion is achived.

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Fabrication of MDOF IPMC Actuators to Generate Undulatory Motion (파동형 움직임이 가능한 다자유 IPMC 구동기 제작)

  • Jeon, Jin-Han;Oh, Il-Kwon
    • Proceedings of the Korean Society for Noise and Vibration Engineering Conference
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    • 2006.11a
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    • pp.119-123
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    • 2006
  • The ionic-polymer-metal-composite actuators have the best merit for bio-mimetic locomotion because of their large bending performance. Especially, they have the advantage for mimicking a fish-like motion because IPMCs are useful to be actuated in water. So we have developed IPMC actuators with multiple electrodes for realization of biomimetic motion. Generally, the IPMC actuator has been fabricated in electroless plating technique, while it needs very long fabrication time and shows poor repeatability in the actuation performance owing to the variables in chemical fabrication process. Therefore, the novel fabrication methods were investigated by combining electroless plating and electroplating techniques capable of patterning precisely. On the whole, two different methods were compared and analyzed with similar thickness level of Platinum electrodes. Present results show that mixing chemical reduction and electroplating can be a promising candidate for electrode patterning.

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Characterization of Dynamic Behavior of C. elegans in Different Physical Environments (PIV 및 TFM 측정 기법을 이용한 예쁜꼬마선충의 동적 패턴 가시화 연구)

  • Park, Jin-Sung;Yun, Byoung Hwan;Shin, Jennifer H.
    • Journal of the Korean Society of Visualization
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    • v.12 no.2
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    • pp.18-22
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    • 2014
  • Caenorhabditis elegans (C. elegans) is an undulatory nematode which exhibits two distinct locomotion types of swimming and crawling. Although in its natural habitat C. elegans lives in a non-Newtonian fluidic environment, our current understanding has been limited to the behavior of C. elegans in a simple Newtonian fluid. Here, we present some experimental results on the penetrating behavior of C. elegans at the interface from liquid to solid environment. Once C. elegans, which otherwise swims freely in a liquid, makes a contact to the solid gel boundary, it begins to penetrate vertically to the surface by changing its stroke motion characterized by a stiffer body shape and a slow stroke frequency. The particle image velocimetry (PIV) analysis reveals the flow streamlines produced by the stroke of worm. For the worm that crawls on a solid surface, we utilize a technique of traction force microscopy (TFM) to find that the crawling nematode forms localized force islands along the body where makes direct contacts to the gel surface.

THRUST GENERATION AND PROPULSIVE EFFICIENCY OF A BIOMIMETIC FOIL MOVING IN A LOW REYNOLDS NUMBER FLOW (저 레이놀즈 수에서 이동하는 생체모사익의 추력 생성 및 추진효율)

  • An, Sang-Joon;Choi, Jong-Hyeok;Maeng, Joo-Sung;Han, Cheol-Heui
    • Journal of computational fluids engineering
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    • v.15 no.2
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    • pp.41-46
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    • 2010
  • In this paper, the fluid dynamic forces and performances of a moving airfoil in the low Reynolds number flow is addressed. In order to simulate the necessary propulsive force for the moving airfoil in a low Reynolds number flow, a lattice-Boltzmann method is used. The critical Reynolds and Strouhal numbers for the thrust generation are investigated for the four propulsion types. It was found that the Normal P&D type produces the largest thrust with the highest efficiency among the investigated types. The leading edge of the airfoil has an effect of deciding the force production types, whereas the trailing edge of the airfoil plays an important role in augmenting or reducing the instability produced by the leading edge oscillation. It is believed that present results can be used to decide the optimal propulsion types for the given Reynolds number flow.