Mechatronics

Mechatronics is the combination of mechanical engineering, electronic engineering, computer engineering, software engineering, control engineering, and systems design engineering in order to design, and manufacture useful products.^[1][2] Mechatronics is a multidisciplinary field of engineering, that is to say it rejects splitting engineering into separate disciplines. Originally, mechatronics just included the combination between mechanics and electronics, hence the word is only a portmanteau of mechanics and electronics. However, as technical systems have become more and more complex the word has been "updated" during recent years to include more technical areas.

French standard NF E 01-010 gives the following definition: “approach aiming at the synergistic integration of mechanics, electronics, control theory, and computer science within product design and manufacturing, in order to improve and/or optimize its functionality".

Contents 1 Description 2 Course structure 3 Application 4 Physical implementations 5 Variant of the field 6 See also 7 Further reading 8 References

Description

A mechatronics engineer unites the principles of mechanics, electronics, and computing to generate a simpler, more economical and reliable system. Mechatronics is centered on mechanics, electronics, computing, control engineering, molecular engineering (from nanochemistry and biology), and optical engineering, which, combined, make possible the generation of simpler, more economical, reliable and versatile systems. The portmanteau "mechatronic" was coined by Tetsuro Mori, the senior engineer of the Japanese company Yaskawa in 1969. An industrial robot is a prime example of a mechatronics system; it includes aspects of electronics, mechanical , and computing to do its day-to-day jobs.

Engineering cybernetics deals with the question of control engineering of mechatronic systems. It is used to control or regulate such a system (see control theory). Through collaboration, the mechatronic modules perform the production goals and inherit flexible and agile manufacturing properties in the production scheme. Modern production equipment consists of mechatronic modules that are integrated according to a control architecture. The most known architectures involve hierarchy, polyarchy, heterarchy, and hybrid. The methods for achieving a technical effect are described by control algorithms, which might or might not utilize formal methods in their design. Hybrid systems important to mechatronics include production systems, synergy drives, planetary exploration rovers, automotive subsystems such as anti-lock braking systems and spin-assist, and every-day equipment such as autofocus cameras, video, hard disks, and CD players.

Course structure

Mechatronics students take courses from across the various fields listed below:

• Mechanical engineering and materials science
• Electronic engineering
• Computer engineering
• Computer science
• Systems and control engineering
• Optomechanics (optical engineering)
• Robotics

Application

• Machine vision
• Automation and robotics
• Servo-mechanics
• Sensing and control systems
• Automotive engineering, automotive equipment in the design of subsystems such as anti-lock braking systems
• Computer-machine controls, such as computer driven machines like IE CNC milling machines
• Expert systems
• Industrial goods
• Consumer products
• Mechatronics systems
• Medical mechatronics,medical imaging systems
• Structural dynamic systems
• Transportation and vehicular systems
• Mechatronics as the new language of the automobile
• Diagnostic, reliability, and control system techniques
• Computer aided and integrated manufacturing systems
• Computer-aided design
• Engineering and manufacturing systems
• Packaging
• Microcontrollers / PLC's
• Mobile apps

Physical implementations

For most mechatronic systems, the main issue is no more how to implement a control system, but how to implement actuators and what is the energy source. Within the mechatronic field, mainly two movement: the piezo-electric actuators and motors, or the electromagnetic actuators and motors. Maybe the most famous mechatronics systems are the well known camera autofocus system or camera anti-shake systems.

Concerning the energy sources, most of the applications use batteries. But a new trend is arriving and is the energy harvesting, allowing transforming into electricity mechanical energy from shock, vibration, or thermal energy from thermal variation, and so on.

Variant of the field

An emerging variant of this field is biomechatronics, whose purpose is to integrate mechanical parts with a human being, usually in the form of removable gadgets such as an exoskeleton. Such an entity is often identified in science fiction as a cyborg. This is the "real-life" version of cyberware.

Another emerging variant is Electronical or electronics design centric ECAD/MCAD co-design. Electronical is where the integration and co-design between the design team and design tools of an electronics centric system and the design team and design tools of that systems physical/mechanical enclosure takes place.

See also

• Mechanical Engineering Technology
• Cybernetics
• Electromechanics
• List of engineering topics
• National Instruments
• Robotics
• Systems Engineering
• Mechatronics Journals

Further reading

• Bolton W., [1], Dorling Kinderson India Pvt limited, 2008
• Bishop, Robert H., Mechatronics: an introduction. CRC Press, 2006.
• De Silva, Clarence W., Mechatronics: an integrated approach. CRC Press, 2005
• Onwubolu, Godfrey C., Mechatronics: principles and applications. Butterworth-Heinemann, 2005.

References

Books

• Bradley, Dawson et al., Mechatronics, Electronics in products and processes, Chapman and Hall Verlag, London, 1991.
• 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 Bestselling system dynamics book using bond graph approach.
• Cetinkunt, Sabri, Mechatronics, John Wiley & Sons, Inc, 2007 ISBN 978-0-4714798-1
• James J. Nutaro (2010). Building software for simulation: theory and algorithms, with applications in C++. Wiley. 

Journals

• IEEE/ASME Transactions on Mechatronics.
• Mechatronics Journal – Elsevier

Websites

• List of publications concerning examples of mechatronic applications and realisation

Standards

• NF E 01-010 2008 – AFNOR (French standard NF E 01-010)
• XP E 01-013 2009 – AFNOR (French standard NF E 01-013)

Citations

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