Design and Implementation of a Lizard-Inspired Robot

The purpose of this paper is to design a lizard-inspired robot driven by a single actuator. Lizard-inspired robots in previous studies had the issue of slippage of their supporting legs. To overcome this issue, a lizard-inspired robot consisting of a four-bar linkage mechanism was designed. The purpose of this paper was achieved through three processes. The first process was kinematic analysis, where the turning angle and stride length of the robot were analyzed. The kinematic analysis results were verified via numerical simulations. The second process was the design and fabrication of the robot. For the robot’s design, both a shuffle-walking method utilizing a claw-shaped leg mechanism and a sliding-rod mechanism for equipping the actuator on the robot’s own coordinates were designed. The third process was experimental verification. The first experimental result was that the claw-shaped leg mechanism was capable of generating an 85.26 N difference in the static frictional force in the longitudinal direction. The other three experimental results were that the robot was capable of driving with 3.51%, 3.16%, and 3.53% error compared to the kinematic analyses, respectively.

[1]  Valer Dolga,et al.  Analysis of Jansen Walking Mechanism Using CAD , 2010, ICRA 2010.

[2]  Hidetaka Suzuki,et al.  Motion control of lizard-type quadruped: -Camera mounting mechanism compensating for shaking caused by bending movement-@@@―屈曲運動によるぶれを補償するカメラ搭載機構― , 2016 .

[3]  Yoji Umetani,et al.  The Basic Considerations on Energetic Efficiencies of Walking Vehicle , 1979 .

[4]  David Zarrouk,et al.  Rising STAR: A Highly Reconfigurable Sprawl Tuned Robot , 2018, IEEE Robotics and Automation Letters.

[5]  Pablo González de Santos,et al.  Analyzing energy-efficient configurations in hexapod robots for demining applications , 2012, Ind. Robot.

[6]  Masami Iwase,et al.  Dynamic Analysis and Modeling of Jansen Mechanism , 2013 .

[7]  José António Tenreiro Machado,et al.  Kinematic and dynamic performance analysis of artificial legged systems , 2008, Robotica.

[8]  Norihiro Kamamichi,et al.  2P1-F04 Motion Analysis of Lizard Type Quadruped Robots(Biorobotics (2)) , 2013 .

[9]  Frank Kirchner,et al.  Development of the six‐legged walking and climbing robot SpaceClimber , 2012, J. Field Robotics.

[10]  Nikolaos G. Tsagarakis,et al.  Horse-like walking, trotting, and galloping derived from kinematic Motion Primitives (kMPs) and their application to walk/trot transitions in a compliant quadruped robot , 2013, Biological Cybernetics.

[11]  Masami Iwase,et al.  Speed Control of Jansen Linkage Mechanism for Exquisite Tasks , 2016 .

[12]  Dilip Kumar Pratihar,et al.  Dynamic modeling, stability and energy consumption analysis of a realistic six-legged walking robot , 2013 .

[13]  F. Thomas,et al.  Application of Distance Geometry to Tracing Coupler Curves of Pin-Jointed Linkages , 2013 .

[14]  Jose A. Cobano,et al.  Continuous free-crab gaits for hexapod robots on a natural terrain with forbidden zones: An application to humanitarian demining , 2010, Robotics Auton. Syst..

[15]  Masami Iwase,et al.  A novel approach to gait synchronization and transition for reconfigurable walking platforms , 2015 .

[16]  Federico Thomas,et al.  On closed-form solutions to the position analysis of Baranov trusses , 2012 .

[17]  Hamed Kazemi,et al.  Modeling and robust backstepping control of an underactuated quadruped robot in bounding motion , 2012, Robotica.

[18]  Pablo González de Santos,et al.  Minimizing Energy Consumption in Hexapod Robots , 2009, Adv. Robotics.

[19]  Masami Iwase,et al.  On a Jansen leg with multiple gait patterns for reconfigurable walking platforms , 2015 .

[20]  Huosheng Hu,et al.  A Modular Architecture for Humanoid Soccer Robots with Distributed Behavior Control , 2008, Int. J. Humanoid Robotics.

[21]  Kensuke Murai,et al.  2A2-T04 Performance Test of Lizard Robot in the Field(Walking Robot (2)) , 2012 .

[22]  David Zarrouk,et al.  Single actuator wave-like robot (SAW): design, modeling, and experiments , 2016, Bioinspiration & biomimetics.