Multi-criteria optimal placement of robots in constrained environments

S. Zeghloul; J.A. Pamanes-Garcia

doi:10.1017/S0263574700019202

Summary

A general method is presented to automatically determine the placement of manipulators which allows one to optimize multiple kinematic performances indices during the execution of their tasks. It considers the presence of obstacles in the workstation and constraints on the motion of the manipulator's joints. The complete formulation is included, and an example with a six-degree-of-freedom manipulator in a cluttered environment es solved that demonstrates the improvements achieved for the manipulator performances by applying the method.

References

Nelson, B., Pedersen, K. and Donath, M., Locating assembly tasks in a manipulator's workspace IEEE Proc. of the Int. Conf. on Robotics and Automation(1987) pp. 1367-1372.Google Scholar

Chiu, S.L., Task compatibility of manipulators postures Int. J. Robotics Research 7, 5, 13–21 (1988).CrossRef Google Scholar

Fardanesh, B. and Rastegar, J., Minimum cycle time location of a task in the workspace of a robot arm IEEE Proc. of the 21th Conf. on Decision and Control(1988) pp. 2280-2283.Google Scholar

Pámanes-Garcia, J.A., A criterion for optimal placement of robotic manipulators IFAC Proc. of the 6th Symp. on Information Control Problems in Manufacturing Technology(1989) pp. 183-187.Google Scholar

Chedmail, P., Synthèse de Robots et de Sites Robotisés. Modélisation de Robots Souples Thèse de Doctoral d'Etat (Université de Nantes, Ecole Nationale Supérieure de Mécanique, France, 1990).Google Scholar

Pámanes-Garcia, J.A. and Zeghloul, S., Optimal placement of robotic manipulators using multiple kinematic criteria Proc. of the 1991 IEEE Int. Conf. on Robotics and Automation Vol 1(1991) pp. 933-938.Google Scholar

Klein, C.A. and Blaho, B.E., Dexterity measures for the design and control of kinematically redundant manipulators Int. J. Robotics Research 6, 2, 72–83 (1987).CrossRef Google Scholar

Salisbury, J.K. and Craig, J.J., Articulated hands: force control and kinematic issues Int. J. Robotics Research 1, 1, 4–17 (1982).CrossRef Google Scholar

Yoshikawa, J., Manipulability of robotic mechanisms Int. J. Robotic Research 4, No. 2, 3–9 (1985).CrossRef Google Scholar

Liegois, A., Automatic supervisory control of the configuration and behavior of multibody mechanisms IEEE Trans. Sys., Man., Cyber. SMC-7, No. 12, 868–871 (1977).Google Scholar

Zeghloul, S., Developpement d'un Système de C.A.O. Robotique Integrant la Planification de Tâches et la Synthese de Sites Robotise Thèse de Doctoral d'Etat (Université de Poitiers, France 1991)Google Scholar

Zeghloul, S., Murguet, D. and Lallemand, J.P., Outils de simulation et de programmation hors-ligne d'environnement multi-robots Proc. of the 7th IFTOMM Congress on Theory of Machines and Mechanisms Seville,Spain(1987) pp. 1089-1092.Google Scholar

Box, M.J., A new method of constrained optimization and a comparison with other methods, Computer J. 8, 42–52 (1965).Google Scholar

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Zeghloul, S. Blanchard, B. and Pamanes, J. A. 1995. Theory and Practice of Robots and Manipulators. p. 247.

Cloutier, Guy M. Gourdeau, Richard and St-Arneault, Chantale 1996. Dual conformance index-based robotic arm placement and adaptation. Journal of Robotic Systems, Vol. 13, Issue. 4, p. 187.

Abdel-Malek, K 1996. Criterion for the Locality of a Manipulator Arm with Respect to an Operating Point. Proceedings of the Institution of Mechanical Engineers, Part B: Journal of Engineering Manufacture, Vol. 210, Issue. 4, p. 385.

Cloutier, Guy M. and Gourdeau, Richard 1998. Task Constraints Specification via Optimized Hyperellipsoids. The International Journal of Robotics Research, Vol. 17, Issue. 3, p. 294.

Ouezdou, F. B. Re´gnier, S. and Mavroidis, C. 1999. Kinematic Synthesis of Manipulators Using a Distributed Optimization Method. Journal of Mechanical Design, Vol. 121, Issue. 4, p. 492.

Abdel-Malek, K. Yu, W. and Yang, J. 2004. Placement of Robot Manipulators to Maximize Dexterity. International Journal of Robotics and Automation, Vol. 19, Issue. 1,

Asokan, T. Seet, G. Lau, M. and Low, E. 2005. Optimum positioning of an underwater intervention robot to maximise workspace manipulability. Mechatronics, Vol. 15, Issue. 6, p. 747.

Guangzhong He Hongming Gao Guangjun Zhang and Lin Wu 2006. Using Adaptive Genetic Algorithm to the Placement of Serial Robot Manipulator. p. 1.

Mitsi, S. Bouzakis, K.-D. Sagris, D. and Mansour, G. 2008. Determination of optimum robot base location considering discrete end-effector positions by means of hybrid genetic algorithm. Robotics and Computer-Integrated Manufacturing, Vol. 24, Issue. 1, p. 50.

Yang, Jingzhou (James) Yu, Wei Kim, Joo and Abdel-Malek, Karim 2009. On the placement of open-loop robotic manipulators for reachability. Mechanism and Machine Theory, Vol. 44, Issue. 4, p. 671.

Vosniakos, George-Christopher and Matsas, Elias 2010. Improving feasibility of robotic milling through robot placement optimisation. Robotics and Computer-Integrated Manufacturing, Vol. 26, Issue. 5, p. 517.

Santos, Rogério Rodrigues dos Steffen, Valder and Saramago, Sezimária de Fátima Pereira 2010. Optimal Task Placement of a Serial Robot Manipulator for Manipulability and Mechanical Power Optimization. Intelligent Information Management, Vol. 02, Issue. 09, p. 512.

Kim, Joo H. and Joo, Chang B. 2013. Optimal motion planning of redundant manipulators with controlled task infeasibility. Mechanism and Machine Theory, Vol. 64, Issue. , p. 155.

Saafi, Houssem Laribi, Med Amine and Zeghloul, Said 2015. Redundantly actuated 3-RRR spherical parallel manipulator used as a haptic device: improving dexterity and eliminating singularity. Robotica, Vol. 33, Issue. 5, p. 1113.

Ren, Shunan Yang, Xiangdong Xu, Jing Wang, Guolei Xie, Ying and Chen, Ken 2016. Determination of the base position and working area for mobile manipulators. Assembly Automation, Vol. 36, Issue. 1, p. 80.

Erdős, Gábor Kardos, Csaba Kemény, Zsolt Kovács, András and Váncza, József 2016. Process planning and offline programming for robotic remote laser welding systems. International Journal of Computer Integrated Manufacturing, Vol. 29, Issue. 12, p. 1287.

Chiba, Ryosuke Arai, Tamio Ueyama, Tsuyoshi Ogata, Taiki and Ota, Jun 2016. Working Environment Design for Effective Palletizing with a 6-DOF Manipulator. International Journal of Advanced Robotic Systems, Vol. 13, Issue. 2,

Nguyen, Quoc Cuong Kim, Youngjun and Kwon, HyukDong 2017. Optimization of layout and path planning of surgical robotic system. International Journal of Control, Automation and Systems, Vol. 15, Issue. 1, p. 375.

Ren, Shunan Xie, Ying Yang, Xiangdong Xu, Jing Wang, Guolei and Chen, Ken 2017. A Method for Optimizing the Base Position of Mobile Painting Manipulators. IEEE Transactions on Automation Science and Engineering, Vol. 14, Issue. 1, p. 370.

Tomić, Marija Jovanović, Kosta Chevallereau, Christine Potkonjak, Veljko and Rodić, Aleksandar 2018. Toward optimal mapping of human dual-arm motion to humanoid motion for tasks involving contact with the environment. International Journal of Advanced Robotic Systems, Vol. 15, Issue. 1,

Download full list

Article contents

Multi-criteria optimal placement of robots in constrained environments

Summary

Keywords

Access options

References

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

Multi-criteria optimal placement of robots in constrained environments

Summary

Keywords

Access options

References

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests