A neuroendocrine-inspired bionic manufacturing system

Wenbin Gu; Dunbing Tang; Kun Zheng; Lei Wang

doi:10.1007/s11518-011-5169-7

Journal of Systems Science and Systems Engineering ›› 2011, Vol. 20 ›› Issue (3) : 275 -293. DOI: 10.1007/s11518-011-5169-7

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A neuroendocrine-inspired bionic manufacturing system

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Abstract

Due to rapid changes of markets and pressures of competitions, the manufacturing companies are forced to adapt their production ways to support diversity of customer’s needs and increase of new product developments. As biological organisms are quite capable of adapting to environmental changes and stimulus, bio-inspired concepts have been recognized much suitable for adaptive manufacturing system control. This paper, therefore, proposes a novel concept of NeuroEndocrine-Inspired Manufacturing System (NEIMS). The proposed NEIMS control architecture is based on analogies with neuro-control and hormone-regulation principles. It has the capability to explicitly specify production control schemes including control points, material, information flow paths and logical operations, and to agilely deal with the frequent occurrence of unexpected disturbances at the shop floor level. From the cybernetics point of view, the control model of NEIMS indicates adaptive behavior to the changes in products demands due to external environment and malfunction of manufacturing cells as an internal environment. Finally, a prototype system has been set up to enable the NEIMS simulation.

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Adaptive manufacturing system control / bionic manufacturing system / neuroendocrine system / neuro-control / hormone-regulation

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Wenbin Gu, Dunbing Tang, Kun Zheng, Lei Wang. A neuroendocrine-inspired bionic manufacturing system. Journal of Systems Science and Systems Engineering, 2011, 20(3): 275-293 DOI:10.1007/s11518-011-5169-7

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References

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[1]	Brussel H., Van Wyns J., Valckenaers P., Bongaerts L., Peeters P.. Reference architecture for holonic manufacturing systems: PROSA. Computers in Industry, 1998, 37(3): 255-274.

[2]	Brennan R.W., Fletcher M., Norrie D.H.. An agent-based approach to reconfiguration of real-time distributed control systems. IEEE Transactions on Robotics and Automation, 2002, 18(4): 444-451.

[3]	Colombo A.W., Schoop R., Neubert R.. An agent-based intelligent control platform for industrial holonic manufacturing systems. IEEE Transactions on Industrial Electronics, 2006, 53(1): 322-337.

[4]	Deen S.M.. Agent-Based Manufacturing: Advances in the Holonic Approach, 2003, Berlin: Springer-Verlag.

[5]	Farhy L.S.. Modeling of oscillations of endocrine networks with feedback. Methods Enzymology, 2004, 384: 54-81.

[6]	Giret A., Botti V.. Engineering holonic manufacturing systems. Computers in industry, 2009, 60(5): 428-440.

[7]	Guo Q.L., Zhang M.. A novel approach for multi-agent-based intelligent manufacturing system. Information Sciences, 2009, 179(18): 3079-3090.

[8]	Holland, J. (1998). Emergence: from Chaos to Order. Oxford Press

[9]	Keenan D.M., Licinio J., Veldhuis J.D.. A feedback-controlled ensemble model of the stress-responsive hypothalamo-pituitary-adrenal axis. PNAS, 2001, 98(7): 4028-4033.

[10]	Leitao P.. A bio-inspired solution for manufacturing control systems. Innovation in Manufacturing Networks, the Eighth IFIP International Conference on Information Technology for Balanced Automation Systems, 303–314, Porto, Portugal, June 23–25, 2008, 2008, Boston: Springer-Verlag

[11]	Liu B., Ding Y.S., Wang J.H.. An intelligent controller based on ultra-short feedback of neuro-endocrine system. Computer Simulation, 2008, 25(1): 188-191.

[12]	Nahm Y.E., Ishikawa H.. A hybrid multi-agent system architecture for enterprise integration using computer networks. Robotics and Computer-Integrated Manufacturing, 2005, 21: 217-234.

[13]	Ou-Yang C., Juan Y.C.. Applying process mining approach to support the verification of a multi-agent system. Journal of System Science and Systems Engineering, 2010, 19(2): 131-149.

[14]	Okino N.. Bionic manufacturing system. Journal of Manufacturing Systems, 1994, 23(1): 175-187.

[15]	Ryu K., Jung M.. Agent-based fractal architecture and modeling for developing distributed manufacturing systems. International Journal of Production Research, 2003, 41(17): 4233-4255.

[16]	Ryu K., Jung M.. Modeling and specifications of dynamic agents in fractal manufacturing systems. Computers in Industry, 2003, 52(2): 161-182.

[17]	Stein, P.S.G (1999). Neurons, Networks, and Motor Behavior. MIT Press

[18]	Ueda K., Vaario J., Ohkura K.. Modeling of biological manufacturing systems for dynamic reconfiguration. Annals of the CIRP, 1997, 46: 343-346.

[19]	Wang D.S., Nagalingam S.V., Lin G.C.I.. Development of an agent-based virtual CIM architecture for small to medium manufacturers. Robotics and Computer Integrated Manufacturing, 2007, 23(1): 1-16.

[20]	Warnecke H.J.. The Fractal Company: A Revolution in Corporate Culture, 1993, Berlin: Springer-Verlag

[21]	Xiang W., Lee H.P.. Ant colony intelligence in multi-agent dynamic manufacturing scheduling. Engineering Applications of Artificial Intelligence, 2008, 21: 73-85.