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Cyber–physical system

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Cyber-Physical Systems (CPS) are integrations of computation with physical processes.[1] In cyber-physical systems, physical and software components are deeply intertwined, able to operate on different spatial and temporal scales, exhibit multiple and distinct behavioral modalities, and interact with each other in ways that change with context.[2][3] CPS involves transdisciplinary approaches, merging theory of cybernetics, mechatronics, design and process science.[4][5][6][7] The process control is often referred to as embedded systems. In embedded systems, the emphasis tends to be more on the computational elements, and less on an intense link between the computational and physical elements. CPS is also similar to the Internet of Things (IoT), sharing the same basic architecture; nevertheless, CPS presents a higher combination and coordination between physical and computational elements.[4][8]

Examples of CPS include smart grid, autonomous automobile systems, medical monitoring, industrial control systems, robotics systems, recycling[4] and automatic pilot avionics.[3][9] Precursors of cyber-physical systems can be found in areas as diverse as aerospace, automotive, chemical processes, civil infrastructure, energy, healthcare, manufacturing, transportation, entertainment, and consumer appliances.[4][9]

Overview

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Unlike more traditional embedded systems, a full-fledged CPS is typically designed as a network of interacting elements with physical input and output instead of as standalone devices.[5] The notion is closely tied to concepts of robotics and sensor networks with intelligence mechanisms proper of computational intelligence leading the pathway. Ongoing advances in science and engineering improve the link between computational and physical elements by means of intelligent mechanisms, increasing the adaptability, autonomy, efficiency, functionality, reliability, safety, and usability of cyber-physical systems.[10] This will broaden the potential of cyber-physical systems in several directions, including: intervention (e.g., collision avoidance); precision (e.g., robotic surgery and nano-level manufacturing); operation in dangerous or inaccessible environments (e.g., search and rescue, firefighting, and deep-sea exploration); coordination (e.g., air traffic control, war fighting); efficiency (e.g., zero-net energy buildings); and augmentation of human capabilities (e.g. in healthcare monitoring and delivery).[11]

Mobile cyber-physical systems

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Mobile cyber-physical systems, in which the physical system under study has inherent mobility, are a prominent subcategory of cyber-physical systems. Examples of mobile physical systems include mobile robotics and electronics transported by humans or animals. The rise in popularity of smartphones has increased interest in the area of mobile cyber-physical systems. Smartphone platforms make ideal mobile cyber-physical systems for a number of reasons, including:

For tasks that require more resources than are locally available, one common mechanism for rapid implementation of smartphone-based mobile cyber-physical system nodes utilizes the network connectivity to link the mobile system with either a server or a cloud environment, enabling complex processing tasks that are impossible under local resource constraints.[13] Examples of mobile cyber-physical systems include applications to track and analyze CO2 emissions,[14] detect traffic accidents, insurance telematics[15] and provide situational awareness services to first responders,[16][17] measure traffic,[18] and monitor cardiac patients.[19]

Examples

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Common applications of CPS typically fall under sensor-based communication-enabled autonomous systems. For example, many wireless sensor networks monitor some aspect of the environment and relay the processed information to a central node. Other types of CPS include smart grid,[20] autonomous automotive systems, medical monitoring, process control systems, distributed robotics, recycling[4] and automatic pilot avionics.

A real-world example of such a system is the Distributed Robot Garden at MIT in which a team of robots tend a garden of tomato plants. This system combines distributed sensing (each plant is equipped with a sensor node monitoring its status), navigation, manipulation and wireless networking.[21]

A focus on the control system aspects of CPS that pervade critical infrastructure can be found in the efforts of the Idaho National Laboratory and collaborators researching resilient control systems. This effort takes a holistic approach to next generation design, and considers the resilience aspects that are not well quantified, such as cyber security,[22] human interaction and complex interdependencies.

Another example is MIT's ongoing CarTel project where a fleet of taxis work by collecting real-time traffic information in the Boston area. Together with historical data, this information is then used for calculating fastest routes for a given time of the day.[23]

CPS are also used in electric grids to perform advanced control, especially in the smart grids context to enhance the integration of distributed renewable generation.The Special remedial action scheme are needed to limit the current flows in the grid when wind farm generation is too high. Distributed CPS are a key solution for this type of issues [24]

In industry the cyber-physical systems empowered by Cloud technologies have led to novel approaches[25][26][27] that paved the path to Industry 4.0 as the European Commission IMC-AESOP project with partners such as Schneider Electric, SAP, Honeywell, Microsoft etc. demonstrated.

Design

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A challenge in the development of embedded and cyber-physical systems is the large differences in the design practice between the various engineering disciplines involved, such as software and mechanical engineering. Additionally, as of today there is no "language" in terms of design practice that is common to all the involved disciplines in CPS. Today, in a marketplace where rapid innovation is assumed to be essential, engineers from all disciplines need to be able to explore system designs collaboratively, allocating responsibilities to software and physical elements, and analyzing trade-offs between them. Recent advances show that coupling disciplines by using co-simulation will allow disciplines to cooperate without enforcing new tools or design methods.[28] Results from the MODELISAR project show that this approach is viable by proposing a new standard for co-simulation in the form of the Functional Mock-up Interface.

Importance

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The US National Science Foundation (NSF) has identified cyber-physical systems as a key area of research.[29] Starting in late 2006, the NSF and other United States federal agencies sponsored several workshops on cyber-physical systems.[30][31][32][33][34][35][36][37][38]

See also

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References

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  1. ^ Lee, Edward A. "Cyber Physical Systems: Design Challenges". 11th IEEE Symposium on Object Oriented Real-Time Distributed Computing (ISORC).
  2. ^ "US National Science Foundation, Cyber-Physical Systems (CPS)"
  3. ^ a b Hu, J.; Lennox, B.; Arvin, F., "Robust formation control for networked robotic systems using Negative Imaginary dynamics" Automatica, 2022.
  4. ^ a b c d e Patil T., Rebaioli L., Fassi I., "Cyber-physical systems for end-of-life management of printed circuit boards and mechatronics products in home automation: A review" Sustainable Materials and Technologies, 2022.
  5. ^ a b Hu, J.; Niu, H.; Carrasco, J.; Lennox, B.; Arvin, F., "Fault-tolerant cooperative navigation of networked UAV swarms for forest fire monitoring" Aerospace Science and Technology, 2022.
  6. ^ Hancu, O.; Maties, V.; Balan, R.; Stan, S. (2007). "Mechatronic approach for design and control of a hydraulic 3-dof parallel robot". The 18th International DAAAM Symposium, "Intelligent Manufacturing & Automation: Focus on Creativity, Responsibility and Ethics of Engineers".
  7. ^ Suh, S.C., Carbone, J.N., Eroglu, A.E.: Applied Cyber-Physical Systems. Springer, 2014.
  8. ^ Rad, Ciprian-Radu; Hancu, Olimpiu; Takacs, Ioana-Alexandra; Olteanu, Gheorghe (2015). "Smart Monitoring of Potato Crop: A Cyber-Physical System Architecture Model in the Field of Precision Agriculture". Conference Agriculture for Life, Life for Agriculture. 6: 73–79.
  9. ^ a b Khaitan et al., "Design Techniques and Applications of Cyber Physical Systems: A Survey", IEEE Systems Journal, 2014.
  10. ^ C.Alippi: Intelligence for Embedded Systems. Springer Verlag, 2014, 283pp, ISBN 978-3-319-05278-6.
  11. ^ "Cyber-physical systems". Program Announcements & Information. The National Science Foundation, 4201 Wilson Boulevard, Arlington, Virginia 22230, USA. 2008-09-30. Retrieved 2009-07-21.
  12. ^ "Virtual Machine for running Java Applications on a CPS". Archived from the original on 2012-05-29. Retrieved 2012-04-12.
  13. ^ White, Jules; Clarke, S.; Dougherty, B.; Thompson, C.; Schmidt, D. "R&D Challenges and Solutions for Mobile Cyber-Physical Applications and Supporting Internet Services" (PDF). Springer Journal of Internet Services and Applications. Archived from the original (PDF) on 2016-08-04. Retrieved 2011-02-21.
  14. ^ J. Froehlich, T. Dillahunt, P. Klasnja, J. Mankoff, S. Consolvo, B. Harrison, and J. Landay, "UbiGreen: investigating a mobile tool for tracking and supporting green transportation habits," in Proceedings of the 27th international conference on Human factors in computing systems. ACM, 2009, pp. 1043–1052.
  15. ^ P. Handel, I. Skog, J. Wahlstrom, F. Bonawide, R. Welsh, J. Ohlsson, and M. Ohlsson: Insurance telematics: opportunities and challenges with the smartphone solution, Intelligent Transportation Systems Magazine, IEEE, vol.6, no.4, pp. 57-70, winter 2014, doi:10.1109/MITS.2014.2343262
  16. ^ Thompson, C.; White, J.; Dougherty, B.; Schmidt, D. C. (2009). "Optimizing Mobile Application Performance with Model–Driven Engineering" (PDF). Software Technologies for Embedded and Ubiquitous Systems. Lecture Notes in Computer Science. Vol. 5860. p. 36. doi:10.1007/978-3-642-10265-3_4. ISBN 978-3-642-10264-6.
  17. ^ Jones, W. D. (2001). "Forecasting traffic flow". IEEE Spectrum. 38: 90–91. doi:10.1109/6.901153.
  18. ^ Rose, G. (2006). "Mobile Phones as Traffic Probes: Practices, Prospects and Issues". Transport Reviews. 26 (3): 275–291. doi:10.1080/01441640500361108. S2CID 109790299.
  19. ^ Leijdekkers, P. (2006). "Personal Heart Monitoring and Rehabilitation System using Smart Phones". 2006 International Conference on Mobile Business. p. 29. doi:10.1109/ICMB.2006.39. hdl:10453/2740. ISBN 0-7695-2595-4. S2CID 14750674.
  20. ^ S. Karnouskos: Cyber-Physical Systems in the Smart Grid (PDF; 79 kB). In:Industrial Informatics (INDIN), 2011 9th IEEE International Conference on, July 2011. Retrieved 20 Apr 2014.
  21. ^ "The Distributed Robotics Garden". people.csail.mit.edu. 2011. Retrieved November 16, 2011.
  22. ^ Loukas, George (June 2015). Cyber-Physical Attacks A growing invisible threat. Oxford, UK: Butterworh-Heinemann (Elsevier). p. 65. ISBN 9780128012901.
  23. ^ "CarTel [MIT Cartel]". cartel.csail.mit.edu. 2011. Archived from the original on August 11, 2007. Retrieved November 16, 2011.
  24. ^ Liu, R.; Srivastava, A. K.; Bakken, D. E.; Askerman, A.; Panciatici, P. (November–December 2017). "Decentralized State Estimation and Remedial Control Action for Minimum Wind Curtailment Using Distributed Computing Platform". IEEE Transactions on Industry Applications. 53 (6): 5915. doi:10.1109/TIA.2017.2740831. OSTI 1417238.
  25. ^ A. W. Colombo, T. Bangemann, S. Karnouskos, J. Delsing, P. Stluka, R. Harrison, F. Jammes, and J. Lastra: Industrial Cloud-based Cyber- Physical Systems: The IMC-AESOP Approach. Springer Verlag, 2014, ISBN 978-3-319-05623-4.
  26. ^ Wu, D.; Rosen, D.W.; Wang, L.; Schaefer, D. (2014). "Cloud-Based Design and Manufacturing: A New Paradigm in Digital Manufacturing and Design Innovation" (PDF). Computer-Aided Design. 59: 1–14. doi:10.1016/j.cad.2014.07.006. S2CID 9315605.
  27. ^ Wu, D., Rosen, D.W., & Schaefer, D. (2014). Cloud-Based Design and Manufacturing: Status and Promise. In: Schaefer, D. (Ed): Cloud-Based Design and Manufacturing: A Service-Oriented Product Development Paradigm for the 21st Century, Springer, London, UK, pp.1-24.
  28. ^ J .Fitzgerald, P.G. Larsen, M. Verhoef (Eds.): Collaborative Design for Embedded Systems: Co-modelling and Co-simulation. Springer Verlag, 2014, ISBN 978-3-642-54118-6.
  29. ^ Wolf, Wayne (November 2007). "The Good News and the Bad News (Embedded Computing Column". IEEE Computer. 40 (11): 104–105. doi:10.1109/MC.2007.404.
  30. ^ "NSF Workshop On Cyber-Physical Systems". Archived from the original on 2008-05-17. Retrieved 2008-06-09.
  31. ^ "Beyond SCADA: Networked Embedded Control for Cyber Physical Systems". Archived from the original on January 17, 2009. Retrieved 2008-06-09.
  32. ^ "NSF Cyber-Physical Systems Summit". Archived from the original on 2009-05-12. Retrieved 2008-08-01.
  33. ^ "National Workshop on High-Confidence Automotive Cyber-Physical Systems". Archived from the original on 2008-08-27. Retrieved 2008-08-03.
  34. ^ "National Workshop on Composable and Systems Technologies for High-Confidence Cyber-Physical Systems". Archived from the original on 2007-12-15. Retrieved 2008-08-04.
  35. ^ "National Workshop on High-Confidence Software Platforms for Cyber-Physical Systems (HCSP-CPS)". Archived from the original on 2006-12-17. Retrieved 2008-08-04.
  36. ^ "New Research Directions for Future Cyber-Physical Energy Systems". Retrieved 2009-06-05.
  37. ^ "Bridging the Cyber, Physical, and Social Worlds". Archived from the original on 2012-07-16. Retrieved 2011-02-25.
  38. ^ "NIST Foundations for Innovation in Cyber-Physical Systems Workshop". Archived from the original on 2015-08-20. Retrieved 2012-02-08.

Further reading

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