Experimental Performance Assessment of Mantis 2, Hybrid Leg-Wheel Mobile Robot

Luca Bruzzone; Pietro Fanghella; Giuseppe Quaglia

doi:10.20965/ijat.2017.p0396

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IJAT Vol.11 No.3 pp. 396-403

doi: 10.20965/ijat.2017.p0396

(2017)

Paper:

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Experimental Performance Assessment of Mantis 2, Hybrid Leg-Wheel Mobile Robot

Luca Bruzzone^,†, Pietro Fanghella^, and Giuseppe Quaglia^**

^*DIME, University of Genoa
Via Opera Pia 15A, 16145 Genoa, Italy

^†Corresponding author

^**DIMEAS, Polytechnic University of Turin, Torino, Italy

Received:

September 27, 2016

Accepted:

November 11, 2016

Online released:

April 28, 2017

Published:

May 5, 2017

Keywords:

hybrid leg-wheel locomotion, ground mobile robot, step climbing

Abstract

Mantis 2 is a small-scale leg-wheel ground mobile robot, designed for exploration, surveillance and inspection tasks in unstructured environments. It is equipped with two actuated front wheels, two passive rear wheels, and two rotating legs with praying Mantis profile, specially conceived for step and obstacle climbing. Locomotion is purely wheeled on regular surfaces, with high energetic efficiency and maneuverability, and with stable camera vision. In case of obstacles or terrain irregularities, the rotating legs increase the motion capability. The main innovation of the second version is the introduction of passive one-way auxiliary wheels on each leg, which improve the efficacy of step climbing. The paper discusses analytical and experimental results on step ascent and descent and locomotion on irregular surfaces.

Cite this article as:

L. Bruzzone, P. Fanghella, and G. Quaglia, “Experimental Performance Assessment of Mantis 2, Hybrid Leg-Wheel Mobile Robot,” Int. J. Automation Technol., Vol.11 No.3, pp. 396-403, 2017.

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References

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[17] G. Quaglia, L. Bruzzone, R. Oderio, and R. Razzoli, “Epi. Q Mobile Robots Family,” Proc. of the ASME 2011 Int. Mechanical Engineering Congress & Exposition IMECE2011, Denver, CO, November 11–17, 2011, Vol.7, pp. 1165-1172, 2011.
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[19] K. J. Huang, S. C. Chen, Y. C. Chou, S.-Y. Shen, C.-H. Li, and P.-C. Lin, “Experimental Validation of a Leg-wheel Hybrid Mobile Robot Quattroped,” 2011 IEEE Int. Conf. on Robotics and Automation, May 9-13, Shanghai, China, pp. 2976-2977, 2011.
[20] Y.-S. Kim, G.-P. Jung, H. Kim, K.-J. Cho, and C.-N. Chu, “Wheel Transformer: A Wheel-Leg Hybrid Robot With Passive Transformable Wheels,” IEEE Trans. on Robotics, Vol.30, No.6, pp. 1487-1498, 2014.
[21] J.-J. Chou and L.-S. Yang, “Innovative Design of a Claw-Wheel Transformable Robot,” 2013 IEEE Int. Conf. on Robotics and Automation (ICRA), Karlsruhe, Germany, May 6-10, pp. 1337-1342, 2013.
[22] L. Bruzzone and P. Fanghella, “Mantis: Hybrid Leg-Wheel Ground Mobile Robot,” Industrial Robot, Vol.41, No.1, pp. 26-36, 2014.
[23] L. Bruzzone and P. Fanghella, “Multibody Simulation of the Dynamic Bbehaviour of a Hybrid Leg-Wheel Ground Mobile Robot,” Proc. of the 33rd IASTED Int. Conf. on Modelling, Identification and Control MIC 2014, February 17–19, Innsbruck, Austria, pp. 237-243, 2014.
[24] L. Bruzzone and P. Fanghella, “Mantis Hybrid Leg-Wheel Robot: Stability Analysis and Motion Law Synthesis for Step Climbing,” Proc. of MESA 2014, 10th IEEE/ASME Int. Conf. on Mechatronic and Embedded Systems and Applications, September 10-12, Senigallia, Ancona, Italy, 2014.
[25] L. Bruzzone and P. Fanghella, “Functional Redesign of Mantis 2.0, a Hybrid Leg-Wheel Robot for Surveillance and Inspection,” J. of Intelligent & Robotic Systems, Vol.81, pp. 215-230, 2016.

This article is published under a Creative Commons Attribution-NoDerivatives 4.0 Internationa License.

[1] [1] R. R. Murphy, “Rescue Robotics for Homeland Security,” Communications of the ACM – Homeland Security, Vol.47, No.3, pp. 66-68, 2004.

[2] [2] R. Playter, M. Buehler, and M. Raibert, “Bigdog,” Proc. of the SPIE Defense & Security Symp., Unmanned Systems Technology, 2006.

[3] [3] E. Semsch, M. Jakob, D. Pavlicek, and M. Pechoucek, “Autonomous UAV Surveillance in Complex Urban Environments,” IEEE/WIC/ACM Intl. Joint Conf. on Web Intelligence and Intelligent Agent Technologies (WI-IAT’09), Vol.2, pp. 82-85, 2009.

[4] [4] E. Cetinsoy, “Design and Flight Tests of a Holonomic Quadrotor UAV with Sub-Rotor Control Surfaces,” 2013 IEEE Intl. Conf. on Mechatronics and Automation, pp. 1197-1202, 2013.

[5] [5] M. Ikeda, S. Hikasa, K. Watanabe, and I. Nagai, “Motion Analysis of a Manta Robot for Underwater Exploration by Propulsive Experiments and the Design of Central Pattern Generator,” Int. J. Automation Technol., Vol.8, No.2, pp. 231-237, 2014.

[6] [6] K. D. Le, H. D. Nguyen, and D. Ranmuthugala, “Development and Control of a Low-Cost, Three-Thruster, Remotely Operated Underwater Vehicle,” Int. J. Automation Technol., Vol.9, No.1, pp. 67-75, 2015.

[7] [7] K. Kato, H. Seki, and M. Hikizu, “3-D Obstacle Detection Using Laser Range Finder with Polygonal Mirror for Powered Wheelchair,” Int. J. Automation Technol., Vol.9, No.4, pp. 373-380, 2015.

[8] [8] Y. Zhuang, N. Jiang, H. Hu, and F. Yan, “3-D-Laser-Based Scene Measurement and Place Recognition for Mobile Robots in Dynamic Indoor Environments,” IEEE Trans. on Instrumentation and Measurement, Vol.62, No.2, pp. 438-450, 2013.

[9] [9] J. Neves, F. Narducci, S. Barra, and H. Y. Proença, “Biometric recognition in surveillance scenarios: a survey,” Artificial Intelligence Review, 22 March, pp. 1-27, 2016.

[10] [10] R. Siegwart and I. R. Nourbakhsh, Introduction to Autonomous Mobile Robots, Cambridge, MA: MIT Press, 2011.

[11] [11] A. Seeni, B. Schafer, B. Rebele, and N. Tolyarenko, “Robot Mobility Concepts for Extraterrestrial Surface Exploration,” Proc. of the IEEE Aerospace Conf., 2008.

[12] [12] L. Bruzzone and G. Quaglia, “Locomotion Systems for Ground Mobile Robots in Unstructured Environments,” Mechanical Sciences, Vol.3, pp. 49-62, 2012.

[13] [13] R. Altendorfer, N. Moore, H. Komsuoglu, M. Buehler, H. B. Jr. Brown, D. McMordie, U. Saranli, R. Full, and D. E. Koditschek, “RHex: a biologically inspired hexapod runner,” Auton. Robot., Vol.11, No.3, pp. 207-213, 2001.

[14] [14] R. D. Quinn, G. M. Nelson, R. J. Bachmann, D. A. Kingsley, J. T. Offi, T. J. Allen, and R. E. Ritzmann, “Parallel Complementary Strategies for Implementing Biological Principles into Mobile Robots,” Intl. J. Robot. Res., Vol.22, No.3, pp. 169-186, 2003.

[15] [15] S. D. Herbert, A. Drenner, and N. Papanikolopoulos, “Loper: A Quadruped-Hybrid Stair Climbing Robot,” Proc. 2008 IEEE Conf. on Robotics and Automation, Pasadena, CA, May 19–23, 2008.

[16] [16] R. Siegwart, M. Lauria, P. A. Maeusli, and M. Van Winnendael, “Design and Implementation of an Innovative Micro Rover,” Proc. of Robotics 98, 3rd Conf. and Exposition on Robotics in Challenging Environments, 1998.

[17] [17] G. Quaglia, L. Bruzzone, R. Oderio, and R. Razzoli, “Epi. Q Mobile Robots Family,” Proc. of the ASME 2011 Int. Mechanical Engineering Congress & Exposition IMECE2011, Denver, CO, November 11–17, 2011, Vol.7, pp. 1165-1172, 2011.

[18] [18] G. Quaglia, R. Oderio, L. Bruzzone, and R. Razzoli, “A Modular Approach for a Family of Ground Mobile Robots,” Int. J. of Advanced Robotic Systems, Vol.10, 2013.

[19] [19] K. J. Huang, S. C. Chen, Y. C. Chou, S.-Y. Shen, C.-H. Li, and P.-C. Lin, “Experimental Validation of a Leg-wheel Hybrid Mobile Robot Quattroped,” 2011 IEEE Int. Conf. on Robotics and Automation, May 9-13, Shanghai, China, pp. 2976-2977, 2011.

[20] [20] Y.-S. Kim, G.-P. Jung, H. Kim, K.-J. Cho, and C.-N. Chu, “Wheel Transformer: A Wheel-Leg Hybrid Robot With Passive Transformable Wheels,” IEEE Trans. on Robotics, Vol.30, No.6, pp. 1487-1498, 2014.

[21] [21] J.-J. Chou and L.-S. Yang, “Innovative Design of a Claw-Wheel Transformable Robot,” 2013 IEEE Int. Conf. on Robotics and Automation (ICRA), Karlsruhe, Germany, May 6-10, pp. 1337-1342, 2013.

[22] [22] L. Bruzzone and P. Fanghella, “Mantis: Hybrid Leg-Wheel Ground Mobile Robot,” Industrial Robot, Vol.41, No.1, pp. 26-36, 2014.

[23] [23] L. Bruzzone and P. Fanghella, “Multibody Simulation of the Dynamic Bbehaviour of a Hybrid Leg-Wheel Ground Mobile Robot,” Proc. of the 33rd IASTED Int. Conf. on Modelling, Identification and Control MIC 2014, February 17–19, Innsbruck, Austria, pp. 237-243, 2014.

[24] [24] L. Bruzzone and P. Fanghella, “Mantis Hybrid Leg-Wheel Robot: Stability Analysis and Motion Law Synthesis for Step Climbing,” Proc. of MESA 2014, 10th IEEE/ASME Int. Conf. on Mechatronic and Embedded Systems and Applications, September 10-12, Senigallia, Ancona, Italy, 2014.

[25] [25] L. Bruzzone and P. Fanghella, “Functional Redesign of Mantis 2.0, a Hybrid Leg-Wheel Robot for Surveillance and Inspection,” J. of Intelligent & Robotic Systems, Vol.81, pp. 215-230, 2016.

Experimental Performance Assessment of Mantis 2, Hybrid Leg-Wheel Mobile Robot

Luca Bruzzone*,†, Pietro Fanghella*, and Giuseppe Quaglia**

Luca Bruzzone^,†, Pietro Fanghella^, and Giuseppe Quaglia^**