THE NONCONVENTIONAL MECHATRONIC SYSTEM
Abstract
Mechatronics is a nonconventional technology which is developed and continues to grow. The mechatronic system is considered the result of the integration of electrical, mechanical and electronic parts, using the informational technology. Per total, this is a nonconventional system. As the technology evolves over time, more and more engineering fields need to adapt and develop. Mechatronics produces a design solution that unifies each of these sub-domains. The development of mechatronic systems involves the use of several disciplines, from mechanical engineering to electronic and computer engineering. Each discipline was developed independently and then integrated to generate a final system. But high-quality projects cannot be done without simultaneously considering all engineering disciplines. Mechatronics brings an intrinsic complexity in the system design process and a lot of research is developed to find out the optimal methods. This article will discuss about the mecatronic nonconventional system components and how the technology is used.
References
[1] Alvarez Cabrera AA, Foeken MJ, Tekin OA et al (2010) Towards automation of control software: a review of challenges in mechatronic design. Mechatronics 20:876–886;
[2] Barbieri G, Fantuzzi C, Borsari R (2014) A model-based design methodology for the development of mechatronic systems. Mechatronics 24:833–843;
[3] Bathelt J, Jonsson A, Bacs C, et al (2005) Applying the new VDI Design Guideline 2206 on mechatronic systems controlled by a PLC. International conference on engineering design (ICED 05), Melbourne, Australia. 15–18 August 2005;
[4] Bishop, R. (Ed.). (2006). Mechatronics. ISBN: 9781315220574, Boca Raton: CRC Press, pp. 1-16;
[5] Bishop, R. (Ed.). (2007). Mechatronic System Control, Logic, and Data Acquisition. ISBN: 9781315221595, Boca Raton: CRC Press, Section I;
[6] Blanchard BS (2012) System engineering management. Wiley, New Jersey;
[7] Blyler J (2004) Interface management. Instrum Meas Mag 7:32–37;
[8] Bradley, David; Russell, David; Ferguson, Ian (March 2015). The Internet of Things-The future or the end of mechatronics, Mechatronics, ISSN 1873-4006, 27: 57–74;
[9] Brezina T, Hadas Z, Vetiska J (2011) Using of co-simulation ADAMS-SIMULINK for development of mechatronic systems. 14th international symposium MECHATRONIKA, Trenin, Slovakia;
[10] Cao Y, Liu Y, Paredis CJJ (2011) System-level model integration of design and simulation for mechatronic systems based on SysML. Mechatronics 21:1063–1075;
[11] Carryer, J., Ohline, R., Kenny, T.: Introduction to Mechatronic Design. Prentice Hall, Boston (2011), ISBN: 978-0131433564;
[12] D. Bradley, D. Dawson, D. Burd, A. Loader: Mechatronics-electronics in Products and Processes (Chapman Hall, London 1991), ISBN 978-0748757428, pp. 2-15, 65-74;
[13] David G. Alciatore, Introduction to Mechatronics and Measurement Systems, 4th ed. (2012), Department of Mechanical Engineering, Colorado State University, ISBN 978-0-07-338023-0; pp.1-20, 431;
[14] de Silva, C. (Ed.). (2008). Mechatronic Systems. ISBN: 9780429125867, Boca Raton: CRC Press, Part IV;
[15] Department of Transportation (2007) Systems engineering for intelligent transportation systems. Springer Science+Business Media, Washington;
[16] Dolga Valer, Mecatronică. Teoria sistemelor, Ed. Politehnica, 2011, ISBN: 978-606-554-235-8;
[17] Dolga Valer, Proiectarea sistemelor mecatronice, Ed. Politehnica, 2007, ISBN 978-973-625-573-1, pp. 1-60;
[18] Fenves S, Foufou S, Bock C, Sriram RD (2006) CPM: a core model for product data. J Comput Inf Sci Eng 8:1–14;
[19] Fisher J (1998) Model-based systems engineering: a new paradigm. ISSN:2156-4868, Incose Insight 1:3–16;
[20] Fotso AB, Wasgint R, Achim R (2012) State of the art for mechatronic design concepts. 8th IEEE/ASME international conference on mechatronic and embedded systems and applications. Suzhou, China. 8–10 July 2012, pp 232–240;
[21] Francis S. Tse and Ivan E. Morse, Measurement and Instrumentation in Engineering: Principles and Basic Laboratory Experiments, ISBN: 978-0824780869, CRC Press; 1st edition, New York, 1989;
[22] Gausemeier J, Frank U, Donoth J, Kahl S (2009) Specification technique for the description of self-optimizing mechatronic systems. Res Eng Des 20:201–223;
[23] Gautam N, Singh N (2008) Lean product development: maximizing the customer perceived value through design change (redesign). Int J Prod Econ 114:313–332;
[24] Hamraz B, Caldwell NHM, Ridgman TW, Clarkson PJ (2014) FBS Linkage ontology and technique to support engineering change management. Res Eng Des 26:3–35;
[25] Hazelrigg GA (1996) Systems engineering: an approach to information- based design. Prentice Hall Upper Saddle River, New Jersey;
[26] Hofmann D, Kopp M, Bertsche B (2010) Development in mechatronics—enhancing reliability by means of a sustainable use of information. 2010 IEEE/ASME international conference on advanced intelligent mechatronics, Montreal, Canada;
[27] https://www.siemens.com/businesses/ci/fr/digital-factory.htm;
[28] Isermann, R. (1996). Modeling and design methodology of mechatronic systems. IEEE/ASME Transactions on Mechatronics, 1, 16–28;
[29] Isermann, R. (1997). Supervision, fault-detection and fault-diagnosis methods—An introduction. Control Engineering Practice, 5(5), 639–652;
[30] Isermann, R. (2000), Mechatronic systems: concepts and applications. Transactions of the Institute of Measurement and Control, 22(1), 29–55, ISSN: 0142-3312, Online ISSN: 1477-0369;
[31] Isermann, R. (2006). Fault-diagnosis systems—An introduction from fault detection to fault tolerance. Berlin: Springer, Heidelberg;
[32] Isermann, R. (2009) Mechatronic Systems, Springer, Berlin, Heidelberg, ISBN 978-1-84628-259-1, pp. 317-328;
[33] Isermann, R., & Raab, U. (1993). Intelligent actuators—Ways to autonomous actuating systems. Automatica, 29(5), 1315–1331;
[34] Isermann, R., Lachmann, K.-H., & Matko, D. (1992). Adaptive control systems. International UK, London: Prentice-Hall;
[35] Isermann, R., Schwarz, R., & Stölzl, S. (2002). Fault-tolerant drive-by wire systems. IEEE Control Systems Magazine, 22(October), 64–81;
[36] ISO (1994) Overview and fundamental principles. ISO, Geneva;
[37] ISO10303-233 (2012) Industrial automation systems and integration— Product data representation and exchange—Part 233: application protocol: systems engineering. International organization for standardization, Geneva;
[38] Karnopp, Dean C., Donald L. Margolis, Ronald C. Rosenberg, System Dynamics: Modeling and Simulation of Mechatronic Systems, 4th Edition, Wiley, 2006. ISBN 0-471-70965-4, pp. 4-50;
[39] Kerzhner AA, Paredis CJJ (2012) ASysML-based language for modeling system-level architecture selection decisions. ASME 2012 international design engineering technical conferences and computers and information in engineering conference, Chicago, USA;
[40] Kleiner S, Kramer C (2013) Model based design with systems engineering based on RFLP using V6. Proceedings of the 23rd CIRP Design Conference, Bochum, Germany. 11–13 March, pp 93–102;
[41] Kolberg E, Reich Y, Levin I (2014) Designing winning robots by careful design of their development process Res Eng Design 25, ISSN: 0934-9839, 157–183 (2014);
[42] Komoto H, Tomiyama T (2011) Multi-disciplinary system decomposition of complex mechatronics systems. CIRP Ann Manuf Technol 60:191–194;
[43] Komoto H, Tomiyama T (2012) A framework for computer-aided conceptual design and its application to system architecting of mechatronics products. Comput Des 44:931–946;
[44] Lawrence J. Kamm (1996). Understanding Electro-Mechanical Engineering: An Introduction to Mechatronics. John Wiley & Sons. ISBN 978-0-7803-1031-5;
[45] Le Duigou J, Bernard A, Perry N (2011) Framework for product lifecycle management integration in small and medium enterprises networks. Comput Aided des Appl 8:531–544;
[46] Lefèvre, J., Charles, S., Bosch-Mauchand, M., Eynard, B., Padiolleau, E.: Multidisciplinary Modelling and Simulation for Mechatronic Design. J Des Res. 12, 127–144 (2014), ISSN: 1569-1551;
[47] Li Q, Zhang WJ, Chen L (2001) Design for control-a concurrent engineering approach for mechatronic systems design. IEEE/ ASME Trans Mechatron 6:161–169;
[48] Lionel Birglen, Mécatronique, Dunod, 2016, 416 p. (ISBN 9782100744787);
[49] NF E 01-010 2008 – AFNOR (French standard NF E 01-010);
[50] Nowak P, Rose B, Saint-Marc L, et al (2004) Towards a design process model enabling the integration of product, process and organization. 5th international conference on integrated design and manufacturing in mechanical engineering (IDMME’04), Bath, UK, pp 91–103;
[51] Pahl G, Beitz W (1988) Engineering design: a systematic approach, 1st edn. The Design Council, London;
[52] Pratt MJ (2001) Introduction to ISO 10303—the STEP standard for product data exchange. J Comput Inf Sci Eng 1:102–103;
[53] Qamar A, Paredis CJJ (2012) Dependency modelling and model management in mechatronic. Proceedings of the ASME 2012; international design engineering technical conferences and computers and information in engineering conference (IDETC/ CIE 2012), Chicago, USA;
[54] Robert Munnig Schmidt, Georg Schitter, Adrian Rankers and Jan van Eijk, The Design of High-Performance Mechatronics – 2nd revised edition. IOS Press, 2014, ISBN 978-1614993674, pp. 333-342;
[55] Rüdiger G. Ballas, Günther Pfeiffer, Roland Werthschützky: Elektromechanische Systeme in Mikrotechnik und Mechatronik. 2. Auflage. Springer, 2009, ISBN 978-3-540-89317-2;
[56] Sellgren U, Törngren M, Malvius D, Biehl M (2009) PLM for Mechatronics integration. International conference on product lifecycle management, Bath, UK, 6–8 July 2009;
[57] Shetty D, Kolk RA (2010) Mechatronics system design, SI version. Cengage Learning, Boston, ISBN: 978-1439061985 pp. 1-39;
[58] Sohlenius, G.: Concurrent Engineering. CIRP Ann - Manuf Technol. 4, 645--655 (1992), ISSN: 0007-8506;
[59] Stone R, Wood K (2000) Development of a functional basis for design. J Mech Des 122:359–370;
[60] Tomiyama T, Gu P, Jin Y et al (2009) Design methodologies: industrial and educational applications. CIRP Ann Manuf Technol 58:543–565;
[61] Tomizuka M (2002) Mechatronics: from the 20th to 21st century. Control Eng Pract 10:877–886;
[62] Torry-Smith JM, Mortensen NH, Achiche S (2013) A proposal for a classification of product-related dependencies in development of mechatronic products; ISBN: 978-87-7475-366-7 Res Eng Des 25:53–74;
[2] Barbieri G, Fantuzzi C, Borsari R (2014) A model-based design methodology for the development of mechatronic systems. Mechatronics 24:833–843;
[3] Bathelt J, Jonsson A, Bacs C, et al (2005) Applying the new VDI Design Guideline 2206 on mechatronic systems controlled by a PLC. International conference on engineering design (ICED 05), Melbourne, Australia. 15–18 August 2005;
[4] Bishop, R. (Ed.). (2006). Mechatronics. ISBN: 9781315220574, Boca Raton: CRC Press, pp. 1-16;
[5] Bishop, R. (Ed.). (2007). Mechatronic System Control, Logic, and Data Acquisition. ISBN: 9781315221595, Boca Raton: CRC Press, Section I;
[6] Blanchard BS (2012) System engineering management. Wiley, New Jersey;
[7] Blyler J (2004) Interface management. Instrum Meas Mag 7:32–37;
[8] Bradley, David; Russell, David; Ferguson, Ian (March 2015). The Internet of Things-The future or the end of mechatronics, Mechatronics, ISSN 1873-4006, 27: 57–74;
[9] Brezina T, Hadas Z, Vetiska J (2011) Using of co-simulation ADAMS-SIMULINK for development of mechatronic systems. 14th international symposium MECHATRONIKA, Trenin, Slovakia;
[10] Cao Y, Liu Y, Paredis CJJ (2011) System-level model integration of design and simulation for mechatronic systems based on SysML. Mechatronics 21:1063–1075;
[11] Carryer, J., Ohline, R., Kenny, T.: Introduction to Mechatronic Design. Prentice Hall, Boston (2011), ISBN: 978-0131433564;
[12] D. Bradley, D. Dawson, D. Burd, A. Loader: Mechatronics-electronics in Products and Processes (Chapman Hall, London 1991), ISBN 978-0748757428, pp. 2-15, 65-74;
[13] David G. Alciatore, Introduction to Mechatronics and Measurement Systems, 4th ed. (2012), Department of Mechanical Engineering, Colorado State University, ISBN 978-0-07-338023-0; pp.1-20, 431;
[14] de Silva, C. (Ed.). (2008). Mechatronic Systems. ISBN: 9780429125867, Boca Raton: CRC Press, Part IV;
[15] Department of Transportation (2007) Systems engineering for intelligent transportation systems. Springer Science+Business Media, Washington;
[16] Dolga Valer, Mecatronică. Teoria sistemelor, Ed. Politehnica, 2011, ISBN: 978-606-554-235-8;
[17] Dolga Valer, Proiectarea sistemelor mecatronice, Ed. Politehnica, 2007, ISBN 978-973-625-573-1, pp. 1-60;
[18] Fenves S, Foufou S, Bock C, Sriram RD (2006) CPM: a core model for product data. J Comput Inf Sci Eng 8:1–14;
[19] Fisher J (1998) Model-based systems engineering: a new paradigm. ISSN:2156-4868, Incose Insight 1:3–16;
[20] Fotso AB, Wasgint R, Achim R (2012) State of the art for mechatronic design concepts. 8th IEEE/ASME international conference on mechatronic and embedded systems and applications. Suzhou, China. 8–10 July 2012, pp 232–240;
[21] Francis S. Tse and Ivan E. Morse, Measurement and Instrumentation in Engineering: Principles and Basic Laboratory Experiments, ISBN: 978-0824780869, CRC Press; 1st edition, New York, 1989;
[22] Gausemeier J, Frank U, Donoth J, Kahl S (2009) Specification technique for the description of self-optimizing mechatronic systems. Res Eng Des 20:201–223;
[23] Gautam N, Singh N (2008) Lean product development: maximizing the customer perceived value through design change (redesign). Int J Prod Econ 114:313–332;
[24] Hamraz B, Caldwell NHM, Ridgman TW, Clarkson PJ (2014) FBS Linkage ontology and technique to support engineering change management. Res Eng Des 26:3–35;
[25] Hazelrigg GA (1996) Systems engineering: an approach to information- based design. Prentice Hall Upper Saddle River, New Jersey;
[26] Hofmann D, Kopp M, Bertsche B (2010) Development in mechatronics—enhancing reliability by means of a sustainable use of information. 2010 IEEE/ASME international conference on advanced intelligent mechatronics, Montreal, Canada;
[27] https://www.siemens.com/businesses/ci/fr/digital-factory.htm;
[28] Isermann, R. (1996). Modeling and design methodology of mechatronic systems. IEEE/ASME Transactions on Mechatronics, 1, 16–28;
[29] Isermann, R. (1997). Supervision, fault-detection and fault-diagnosis methods—An introduction. Control Engineering Practice, 5(5), 639–652;
[30] Isermann, R. (2000), Mechatronic systems: concepts and applications. Transactions of the Institute of Measurement and Control, 22(1), 29–55, ISSN: 0142-3312, Online ISSN: 1477-0369;
[31] Isermann, R. (2006). Fault-diagnosis systems—An introduction from fault detection to fault tolerance. Berlin: Springer, Heidelberg;
[32] Isermann, R. (2009) Mechatronic Systems, Springer, Berlin, Heidelberg, ISBN 978-1-84628-259-1, pp. 317-328;
[33] Isermann, R., & Raab, U. (1993). Intelligent actuators—Ways to autonomous actuating systems. Automatica, 29(5), 1315–1331;
[34] Isermann, R., Lachmann, K.-H., & Matko, D. (1992). Adaptive control systems. International UK, London: Prentice-Hall;
[35] Isermann, R., Schwarz, R., & Stölzl, S. (2002). Fault-tolerant drive-by wire systems. IEEE Control Systems Magazine, 22(October), 64–81;
[36] ISO (1994) Overview and fundamental principles. ISO, Geneva;
[37] ISO10303-233 (2012) Industrial automation systems and integration— Product data representation and exchange—Part 233: application protocol: systems engineering. International organization for standardization, Geneva;
[38] Karnopp, Dean C., Donald L. Margolis, Ronald C. Rosenberg, System Dynamics: Modeling and Simulation of Mechatronic Systems, 4th Edition, Wiley, 2006. ISBN 0-471-70965-4, pp. 4-50;
[39] Kerzhner AA, Paredis CJJ (2012) ASysML-based language for modeling system-level architecture selection decisions. ASME 2012 international design engineering technical conferences and computers and information in engineering conference, Chicago, USA;
[40] Kleiner S, Kramer C (2013) Model based design with systems engineering based on RFLP using V6. Proceedings of the 23rd CIRP Design Conference, Bochum, Germany. 11–13 March, pp 93–102;
[41] Kolberg E, Reich Y, Levin I (2014) Designing winning robots by careful design of their development process Res Eng Design 25, ISSN: 0934-9839, 157–183 (2014);
[42] Komoto H, Tomiyama T (2011) Multi-disciplinary system decomposition of complex mechatronics systems. CIRP Ann Manuf Technol 60:191–194;
[43] Komoto H, Tomiyama T (2012) A framework for computer-aided conceptual design and its application to system architecting of mechatronics products. Comput Des 44:931–946;
[44] Lawrence J. Kamm (1996). Understanding Electro-Mechanical Engineering: An Introduction to Mechatronics. John Wiley & Sons. ISBN 978-0-7803-1031-5;
[45] Le Duigou J, Bernard A, Perry N (2011) Framework for product lifecycle management integration in small and medium enterprises networks. Comput Aided des Appl 8:531–544;
[46] Lefèvre, J., Charles, S., Bosch-Mauchand, M., Eynard, B., Padiolleau, E.: Multidisciplinary Modelling and Simulation for Mechatronic Design. J Des Res. 12, 127–144 (2014), ISSN: 1569-1551;
[47] Li Q, Zhang WJ, Chen L (2001) Design for control-a concurrent engineering approach for mechatronic systems design. IEEE/ ASME Trans Mechatron 6:161–169;
[48] Lionel Birglen, Mécatronique, Dunod, 2016, 416 p. (ISBN 9782100744787);
[49] NF E 01-010 2008 – AFNOR (French standard NF E 01-010);
[50] Nowak P, Rose B, Saint-Marc L, et al (2004) Towards a design process model enabling the integration of product, process and organization. 5th international conference on integrated design and manufacturing in mechanical engineering (IDMME’04), Bath, UK, pp 91–103;
[51] Pahl G, Beitz W (1988) Engineering design: a systematic approach, 1st edn. The Design Council, London;
[52] Pratt MJ (2001) Introduction to ISO 10303—the STEP standard for product data exchange. J Comput Inf Sci Eng 1:102–103;
[53] Qamar A, Paredis CJJ (2012) Dependency modelling and model management in mechatronic. Proceedings of the ASME 2012; international design engineering technical conferences and computers and information in engineering conference (IDETC/ CIE 2012), Chicago, USA;
[54] Robert Munnig Schmidt, Georg Schitter, Adrian Rankers and Jan van Eijk, The Design of High-Performance Mechatronics – 2nd revised edition. IOS Press, 2014, ISBN 978-1614993674, pp. 333-342;
[55] Rüdiger G. Ballas, Günther Pfeiffer, Roland Werthschützky: Elektromechanische Systeme in Mikrotechnik und Mechatronik. 2. Auflage. Springer, 2009, ISBN 978-3-540-89317-2;
[56] Sellgren U, Törngren M, Malvius D, Biehl M (2009) PLM for Mechatronics integration. International conference on product lifecycle management, Bath, UK, 6–8 July 2009;
[57] Shetty D, Kolk RA (2010) Mechatronics system design, SI version. Cengage Learning, Boston, ISBN: 978-1439061985 pp. 1-39;
[58] Sohlenius, G.: Concurrent Engineering. CIRP Ann - Manuf Technol. 4, 645--655 (1992), ISSN: 0007-8506;
[59] Stone R, Wood K (2000) Development of a functional basis for design. J Mech Des 122:359–370;
[60] Tomiyama T, Gu P, Jin Y et al (2009) Design methodologies: industrial and educational applications. CIRP Ann Manuf Technol 58:543–565;
[61] Tomizuka M (2002) Mechatronics: from the 20th to 21st century. Control Eng Pract 10:877–886;
[62] Torry-Smith JM, Mortensen NH, Achiche S (2013) A proposal for a classification of product-related dependencies in development of mechatronic products; ISBN: 978-87-7475-366-7 Res Eng Des 25:53–74;
Published
2020-06-30
How to Cite
Sima, L., & Zapciu, M. (2020). THE NONCONVENTIONAL MECHATRONIC SYSTEM. Nonconventional Technologies Review, 24(2). Retrieved from https://www.revtn.ro/index.php/revtn/article/view/280
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Copyright (c) 2020 Liviu Mihai Sima, Miron Zapciu
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