Digital twin

A digital twin is the generation or collection of digital data representing a physical object. The concept of digital twin has its roots in engineering and the creation of engineering drawings/graphics. Digital Twins are the outcome of continuous improvement in the creation of product design and engineering activities. Product drawings and engineering specifications progressed from handmade drafting to computer aided drafting/computer aided design (CAD) to model-based systems engineering (MBSE).

The digital twin of a physical object is dependent on the Digital Thread. A digital thread is the lowest level component of a digital twin and the "twin" is dependent on the digital thread to maintain accuracy. Changes to product design are implemented using Engineering Change Orders (ECO). An ECO made to a component item will result in a new version of the item's digital thread, and correspondingly to the digital twin.

Origin and types of digital twins

Digital twins were anticipated by David Gelernter's 1991 book Mirror Worlds.[1][2] It is widely acknowledged in both industry and academic publications[3][4][5][6][7][8] that Michael Grieves of Florida Institute of Technology first applied the digital twin concept in manufacturing. The concept and model of the digital twin was publicly introduced in 2002 by Grieves, then of the University of Michigan, at a Society of Manufacturing Engineers conference in Troy, Michigan.[9] Grieves proposed the digital twin as the conceptual model underlying product lifecycle management (PLM).

An Early Digital Twin Concept by Grieves and Vickers

The concept, which had a few different names, was subsequently called the "digital twin" by John Vickers of NASA in a 2010 Roadmap Report.[10] The digital twin concept consists of three distinct parts: the physical product, the digital/virtual product, and connections between the two products. The connections between the physical product and the digital/virtual product is data that flows from the physical product to the digital/virtual product and information that is available from the digital/virtual product to the physical environment.

The concept was divided into types later.[11] The types are the digital twin prototype (DTP), the digital twin instance (DTI), and the digital twin aggregate (DTA). The DTP consists of the designs, analyses, and processes to realize a physical product. The DTP exists before there is a physical product. The DTI is the digital twin of each individual instance of the product once it is manufactured. The DTA is the aggregation of DTIs whose data and information can be used for interrogation about the physical product, prognostics, and learning. The specific information contained in the digital twins is driven by use cases. The digital twin is a logical construct, meaning that the actual data and information may be contained in other applications.

A digital twin in the workplace is often considered part of robotic process automation (RPA) and, per industry-analyst firm Gartner, is part of the broader and emerging "hyperautomation" category.

Examples

An example of how digital twins are used to optimize machines is with the maintenance of power generation equipment such as power generation turbines, jet engines and locomotives.

Another example of digital twins is the use of 3D modeling to create digital companions for the physical objects.[12][13][14][5][6] It can be used to view the status of the actual physical object, which provides a way to project physical objects into the digital world.[15] For example, when sensors collect data from a connected device, the sensor data can be used to update a "digital twin" copy of the device's state in real time.[16][17][18] The term "device shadow" is also used for the concept of a digital twin.[19] The digital twin is meant to be an up-to-date and accurate copy of the physical object's properties and states, including shape, position, gesture, status and motion.[20]

A digital twin also can be used for monitoring, diagnostics and prognostics to optimize asset performance and utilization. In this field, sensory data can be combined with historical data, human expertise and fleet and simulation learning to improve the outcome of prognostics.[21] Therefore, complex prognostics and intelligent maintenance system platforms can use digital twins in finding the root cause of issues and improve productivity.

Digital twins of autonomous vehicles and their sensor suite embedded in a traffic and environment simulation have also been proposed as a means to overcome the significant development, testing and validation challenges for the automotive application,[22] in particular when the related algorithms are based on artificial intelligence approaches that require extensive training data and validation data sets.

Further examples of industry applications:

Manufacturing industry

The physical manufacturing objects are virtualized and represented as digital twin models (avatars) seamlessly and closely integrated in both the physical and cyber spaces.[32] Physical objects and twin models interact in a mutually beneficial manner.

Industry-level dynamics

The digital twin is disrupting the entire product lifecycle management (PLM), from design, to manufacturing to service and operations.[33] Nowadays, PLM is very time consuming in terms of efficiency, manufacturing, intelligence, service phases and sustainability in product design. A digital twin can merge the product physical and virtual space.[34] The digital twin enables companies to have a digital footprint of all of their products, from design to development and throughout the entire product life cycle.[35][36] Broadly speaking, industries with manufacturing business are highly disrupted by digital twins. In the manufacturing process, the digital twin is like a virtual replica of the near-time occurrences in the factory. Thousands of sensors are being placed throughout the physical manufacturing process, all collecting data from different dimensions, such as environmental conditions, behavioural characteristics of the machine and work that is being performed. All this data is continuously communicating and collected by the digital twin.[35]

Due to the Internet of Things, digital twins have become more affordable and could drive the future of the manufacturing industry. A benefit for engineers lays in real-world usage of products that are virtually being designed by the digital twin. Advanced ways of product and asset maintenance and management come within reach as there is a digital twin of the real 'thing' with real-time capabilities.[37]

Digital twins offer a great amount of business potential by predicting the future instead of analyzing the past of the manufacturing process.[38] The representation of reality created by digital twins allows manufacturers to evolve towards ex-ante business practices.[33] The future of manufacturing drives on the following four aspects: modularity, autonomy, connectivity and digital twin.[39] As there is an increasing digitalization in the stages of a manufacturing process, opportunities are opening up to achieve a higher productivity. This starts with modularity and leading to higher effectiveness in the production system. Furthermore, autonomy enables the production system to respond to unexpected events in an efficient and intelligent way. Lastly, connectivity like the Internet of Things, makes the closing of the digitalization loop possible, by then allowing the following cycle of product design and promotion to be optimized for higher performance.[39] This may lead to increase in customer satisfaction and loyalty when products can determine a problem before actually breaking down.[33] Furthermore, as storage and computing costs are becoming less expensive, the ways in which digital twins are used are expanding.[35]

Embedded digital twin

Remembering that a definition of digital twin is a real time digital replica of a physical device, manufacturers are embedding digital twin in their device. Proven advantages are improved quality, earlier fault detection and better feedback on product usage to product designer.[40]

Urban planning and the built environment industry

Geographic digital twins have been popularised in urban planning practice, given the increasing appetite for digital technology in the Smart Cities movement. These digital twins are often proposed in the form of interactive platforms to capture and display real-time 3D and 4D spatial data in order to model urban environments (cities) and the data feeds within them.[41]

Visualisation technologies such as augmented reality (AR) systems are being used as both collaborative tools for design and planning in the built environment integrating data feeds from embedded sensors in cities and API services to form digital twins. For example, AR can be used to create augmented reality maps, buildings and data feeds projected onto tabletops for collaborative viewing by built environment professionals.[42]

In the built environment, partly through the adoption of building information modeling processes, planning, design, construction, and operation and maintenance activities are increasingly being digitised, and digital twins of built assets are seen as a logical extension - at an individual asset level and at a national level. In the United Kingdom in November 2018, for example, the Centre for Digital Built Britain published The Gemini Principles,[43] outlining principles to guide development of a "national digital twin".[44]

Healthcare industry

Healthcare is recognized as an industry being disrupted by the digital twin technology.[45][34] The concept of digital twin in the healthcare industry was originally proposed and first used in product or equipment prognostics.[34] With a digital twin, lives can be improved in terms of medical health, sports and education by taking a more data-driven approach to healthcare.[33] The availability of technologies makes it possible to build personalized models for patients, continuously adjustable based on tracked health and lifestyle parameters. This can ultimately lead to a virtual patient, with detailed description of the healthy state of an individual patient and not only on previous records. Furthermore, the digital twin enables individual's records to be compared to the population in order to easier find patterns with great detail.[45] The biggest benefit of the digital twin on the healthcare industry is the fact that healthcare can be tailored to anticipate on the responses of individual patients. Digital twins will not only lead to better resolutions when defining the health of an individual patient but also change the expected image of a healthy patient. Previously, 'healthy' was seen as the absence of disease indications. Now, 'healthy' patients can be compared to the rest of the population in order to really define healthy.[45] However, the emergence of the digital twin in healthcare also brings some downsides. The digital twin may lead to inequality, as the technology might not be accessible for everyone by widening the gap between the rich and poor. Furthermore, the digital twin will identify patterns in a population which may lead to discrimination.[45][46]

Automotive industry

The automobile industry has been improved by digital twin technology. Digital twins in the automobile industry are implemented by using existing data in order to facilitate processes and reduce marginal costs. Currently, automobile designers expand the existing physical materiality by incorporating software-based digital abilities.[47] A specific example of digital twin technology in the automotive industry is where automotive engineers use digital twin technology in combination with the firm's analytical tool in order to analyze how a specific car is driven. In doing so, they can suggest incorporating new features in the car that can reduce car accidents on the road, which was previously not possible in such a short time frame.[48]

Another example is the application of the digital twin paradigm to the vehicle-to-cloud based advanced driver-assistance systems (ADAS) on connected vehicles.[49] In the system, the cloud server creates a digital world based on the received data, processes it with the proposed models, and sends it back to the connected vehicles in the real world. Drivers can benefit from this digital twin paradigm and improve their driving experience, even if all computations are conducted in the digital world (cloud).

How to properly visualize digital twin information to vehicle drivers remains an open question. The guidance and command computed in the digital world needs to be visualized to drivers in the real world through human-machine interfaces, thus assisting the decision making of their driving maneuvers as a feature of ADAS. One novel solution is to fuse image data (both RGB and depth) coming from on-board cameras, with cloud data coming from digital twin, and overlay the digital twin information on top of existing objects from the driver's field of view.[50] Such digital twin information may include status of surrouding vehicles or crossing vehicles from other directions, status of surrouding vehicles' drivers, or predictions of surrounding vehicles' future behaviors. Human-machine interfaces of digital twin can be designed with an external screen on the vehicle, or with Head-up display through Augmented reality technology.[51]

The characteristics of digital twin technology

Digital technologies have certain characteristics that distinguish them from other technologies. These characteristics, in turn, have certain consequences. Digital twins have the following characteristics.

Connectivity

One of the main characteristics of digital twin technology is its connectivity. The recent development of the Internet of Things (IoT) brings forward numerous new technologies. The development of IoT also brings forward the development of digital twin technology. This technology shows many characteristics that have similarities with the character of the IoT, namely its connective nature. First and foremost, the technology enables connectivity between the physical component and its digital counterpart. The basis of digital twins is based on this connection, without it, digital twin technology would not exist. As described in the previous section, this connectivity is created by sensors on the physical product which obtain data and integrate and communicate this data through various integration technologies. Digital twin technology enables increased connectivity between organizations, products, and customers.[36] For example, connectivity between partners in a supply chain can be increased by enabling members of this supply chain to check the digital twin of a product or asset. These partners can then check the status of this product by simply checking the digital twin.

Also, connectivity with customers can be increased.

Servitization is the process of organizations that are adding value to their core corporate offerings through services.[52] In the case of the example of engines, the manufacturing of the engine is the core offering of this organization, they then add value by providing a service of checking the engine and offering maintenance.

Homogenization

Digital twins can be further characterized as a digital technology that is both the consequence and an enabler of the homogenization of data. Due to the fact that any type of information or content can now be stored and transmitted in the same digital form, it can be used to create a virtual representation of the product (in the form of a digital twin), thus decoupling the information from its physical form.[53] Therefore, the homogenization of data and the decoupling of the information from its physical artifact, have allowed digital twins to come into existence. However, digital twins also enable increasingly more information on physical products to be stored digitally and become decoupled from the product itself.[47]

As data is increasingly digitized, it can be transmitted, stored and computed in fast and low-cost ways.[47] According to Moore's law, computing power will continue to increase exponentially over the coming years, while the cost of computing decreases significantly. This would, therefore, lead to lower marginal costs of developing digital twins and make it comparatively much cheaper to test, predict, and solve problems on virtual representations rather than testing on physical models and waiting for physical products to break before intervening.

Another consequence of the homogenization and decoupling of information is that the user experience converges. As information from physical objects is digitized, a single artifact can have multiple new affordances.[47] Digital twin technology allows detailed information about a physical object to be shared with a larger number of agents, unconstrained by physical location or time.[54] In his white paper on digital twin technology in the manufacturing industry, Michael Grieves noted the following about the consequences of homogenization enabled by digital twins:[55]

In the past, factory managers had their office overlooking the factory so that they could get a feel for what was happening on the factory floor. With the digital twin, not only the factory manager, but everyone associated with factory production could have that same virtual window to not only a single factory, but to all the factories across the globe. (Grieves, 2014, p. 5)

Reprogrammable and smart

As stated above, a digital twin enables a physical product to be reprogrammable in a certain way. Furthermore, the digital twin is also reprogrammable in an automatic manner. Through the sensors on the physical product, artificial intelligence technologies, and predictive analytics,[56] A consequence of this reprogrammable nature is the emergence of functionalities. If we take the example of an engine again, digital twins can be used to collect data about the performance of the engine and if needed adjust the engine, creating a newer version of the product. Also, servitization can be seen as a consequence of the reprogrammable nature as well. Manufactures can be responsible for observing the digital twin, making adjustments, or reprogramming the digital twin when needed and they can offer this as an extra service.

Digital traces

Another characteristic that can be observed, is the fact that digital twin technologies leave digital traces. These traces can be used by engineers for example, when a machine malfunctions to go back and check the traces of the digital twin, to diagnose where the problem occurred.[57] These diagnoses can in the future also be used by the manufacturer of these machines, to improve their designs so that these same malfunctions will occur less often in the future.

Modularity

In the sense of the manufacturing industry, modularity can be described as the design and customization of products and production modules.[39] By adding modularity to the manufacturing models, manufacturers gain the ability to tweak models and machines. Digital twin technology enables manufacturers to track the machines that are used and notice possible areas of improvement in the machines. When these machines are made modular, by using digital twin technology, manufacturers can see which components make the machine perform poorly and replace these with better fitting components to improve the manufacturing process.

  • Digital Control Twin and Supply Chain

References

  1. Gelernter, David Hillel (1991). Mirror Worlds: or the Day Software Puts the Universe in a Shoebox—How It Will Happen and What It Will Mean. Oxford; New York: Oxford University Press. ISBN 978-0195079067. OCLC 23868481.
  2. "Siemens and General Electric gear up for the internet of things". The Economist. 3 December 2016. That technology allows manufacturers to create what David Gelernter, a pioneering computer scientist at Yale University, over two decades ago imagined as 'mirror worlds'.
  3. Marr, Bernard (March 6, 2017). "What Is Digital Twin Technology - And Why Is It So Important?". Forbes.com. Retrieved September 10, 2019.
  4. Thilmany, Jean (September 21, 2017). "Identical Twins". ASME. Retrieved September 10, 2019.
  5. "Digital twins – rise of the digital twin in Industrial IoT and Industry 4.0". i-SCOOP. Retrieved 2019-09-11.
  6. Trancossi, Michele; Cannistraro, Mauro; Pascoa, Jose (2018-12-30). "Can constructal law and exergy analysis produce a robust design method that couples with industry 4.0 paradigms? The case of a container house". Mathematical Modelling of Engineering Problems. 5 (4): 303–312. doi:10.18280/mmep.050405. ISSN 2369-0739.
  7. Xu, Yan; Sun, Yanming; Liu, Xiaolong; Zheng, Yonghua (2019). "A Digital-Twin-Assisted Fault Diagnosis Using Deep Transfer Learning". IEEE Access. 7: 19990–19999. doi:10.1109/ACCESS.2018.2890566. ISSN 2169-3536.
  8. Greengard, Samuel. "Digital Twins Grow Up". cacm.acm.org. Retrieved 2019-09-11.
  9. Grieves, M., Virtually Intelligent Product Systems: Digital and Physical Twins, in Complex Systems Engineering: Theory and Practice, S. Flumerfelt, et al., Editors. 2019, American Institute of Aeronautics and Astronautics. p. 175-200.
  10. Piascik, R., et al., Technology Area 12: Materials, Structures, Mechanical Systems, and Manufacturing Road Map. 2010, NASA Office of Chief Technologist.
  11. Grieves, M. and J. Vickers, Digital Twin: Mitigating Unpredictable, Undesirable Emergent Behavior in Complex Systems, in Trans-Disciplinary Perspectives on System Complexity, F.-J. Kahlen, S. Flumerfelt, and A. Alves, Editors. 2016, Springer: Switzerland. p. 85-114.
  12. "Shaping the Future of the IoT". YouTube. PTC. Retrieved 22 September 2015.
  13. "On Track For The Future – The Siemens Digital Twin Show". YouTube. Siemens. Retrieved 22 September 2015.
  14. "'Digital twins' could make decisions for us within 5 years, John Smart says". news.com.au. Retrieved 22 September 2015.
  15. "Digital Twin for MRO". LinkedIn Pulse. Transition Technologies. Retrieved 25 November 2015.
  16. Marr, Bernard. "What Is Digital Twin Technology – And Why Is It So Important?". Forbes. Forbes. Retrieved 7 March 2017.
  17. Grieves, Michael. "Digital Twin: Manufacturing Excellence through Virtual Factory Replication" (PDF). Florida Institute of Technology. Retrieved 24 March 2017.
  18. "GE Doubles Down On 'Digital Twins' For Business Knowledge". InformationWeek. Retrieved 26 July 2017.
  19. "Device Shadows for AWS IoT – AWS IoT". docs.aws.amazon.com.
  20. "Digital Twin for SLM". YouTube. Transition Technologies. Retrieved 26 November 2015.
  21. "GE Oil & Gas 2017 Annual Meeting: 'Digital: Exploring what's possible' with Colin Parris". Youtube. GE Oil & Gas. Retrieved 26 July 2017.
  22. Hallerbach, Sven; Xia, Yiqun; Eberle, Ulrich; Koester, Frank (3 April 2018). "Simulation-based Identification of Critical Scenarios for Cooperative and Automated Vehicles". SAE Technical Paper 2018-01-1066. Retrieved 23 December 2018.
  23. Infosys Insights. "The Future For Industrial Services: Digital Twin" (PDF). Retrieved 15 March 2017.
  24. "The jet engine with 'digital twins'". BBC.com. Retrieved 26 July 2017.
  25. TWI Ltd. "Lifecycle Engineering Asset Management Through Digital Twin Technology". www.twi-global.com. Retrieved 14 March 2017.
  26. "How twinning tech will power our future". November 2016. Retrieved 26 July 2017.
  27. Bureau Veritas. "Digital technology to transform AIMS". Retrieved 15 March 2017.
  28. Bacchiega IRS srl, Gianluca (2017-06-01). "Embedded digital twin". Cite journal requires |journal= (help)
  29. "Digital Twins elevate industrial asset performance". Control. Retrieved 26 July 2017.
  30. "Creating a Building's Digital Twin". Wired. November 2017. Retrieved 1 Feb 2017.
  31. "Is Your Utility GIS a Digital Twin — Or a Digital Mutant?". Energy Central. Retrieved 29 Aug 2018.
  32. Yang, Chen; Shen, Weiming; Wang, Xianbin (2018). "The Internet of Things in Manufacturing: Key Issues and Potential Applications". IEEE Systems, Man, and Cybernetics Magazine. 4 (1): 6–15. doi:10.1109/MSMC.2017.2702391. S2CID 42651835.
  33. Steer, Markus (May 2018). "Will There Be A Digital Twin For Everything And Everyone?". www.digitalistmag.com. Retrieved 2018-10-08.
  34. Tao, Fei; Cheng, Jiangfeng; Qi, Qinglin; Zhang, Meng; Zhang, He; Sui, Fangyuan (March 2017). "Digital twin-driven product design, manufacturing and service with big data". The International Journal of Advanced Manufacturing Technology. 94 (9–12): 3563–3576. doi:10.1007/s00170-017-0233-1. S2CID 114484028.
  35. Parrot, Aaron; Warshaw, Lane (May 2017). "Industry 4.0 and the digital twin". Deloitte Insights.
  36. Porter, Michael; Heppelman, James (October 2015). "How smart, connected products are transforming companies". Harvard Business Review. 93: 96–114.
  37. "Digital twin technology and simulation: benefits, usage and predictions 2018". I-Scoop. 2017-11-11.
  38. "Industrial IoT: Rise of Digital Twin in Manufacturing Sector". Biz4intellia.
  39. Rosen, Roland; von Wichert, Georg; Lo, George; Bettenhausen, Kurt D. (2015). "About The Importance of Autonomy and Digital Twins for the Future of Manufacturing". IFAC-PapersOnLine. 48 (3): 567–572. doi:10.1016/j.ifacol.2015.06.141.
  40. Bacchiega, Gianluca. "Creating an Embedded Digital Twin: monitor, understand and predict Device Health Failure" (PDF). Inn4mech - Mechatronics and Industry 4.0 Conference Presentation - 2018.
  41. NSW, Digital (25 February 2020). "NSW Digital win". Retrieved 25 February 2020.
  42. Lock, Oliver (25 February 2020). "HoloCity". doi:10.1145/3359997.3365734. S2CID 208033164. Cite journal requires |journal= (help)
  43. "The Gemini Principles" (PDF). www.cdbb.cam.ac.uk. Centre for Digital Built Britain. 2018. Retrieved 2020-01-01.
  44. Walker, Andy (7 December 2018). "Principles to guide development of national digital twin released". Infrastructure Intelligence. Retrieved 1 June 2020.
  45. Bruynseels, Koen; Santoni de Sio, Filippo; van den Hoven, Jeroen (February 2018). "Digital Twins in Health Care: Ethical Implications of an Emerging Engineering Paradigm". Frontiers in Genetics. 9: 31. doi:10.3389/fgene.2018.00031. PMC 5816748. PMID 29487613.
  46. "Healthcare solution testing for future | Digital Twins in healthcare". Dr. Hempel Digital Health Network. December 2017.
  47. Yoo, Youngjin; Boland, Richard; Lyytinen, Kalle; Majchrzak, Ann (September–October 2012). "Organizing for innovation in the digitized world". Organization Science. 23 (5): 1398–1408. doi:10.1287/orsc.1120.0771. JSTOR 23252314.
  48. Cearley, David W.; Burker, Brian; Searle, Samantha; Walker, Mike J. (3 October 2017). "The top 10 strategic technology trends for 2013" (PDF). Gartner Trends 2018: 1–24.
  49. Wang, Z.; Liao, X.; Zhao, X.; Han, K.; Tiwari, P.; Barth, M. J.; Wu, G. (May 2020). "A Digital Twin Paradigm: Vehicle-to-Cloud Based Advanced Driver Assistance Systems". 2020 IEEE 91st Vehicular Technology Conference (VTC2020-Spring): 1–6. doi:10.1109/VTC2020-Spring48590.2020.9128938.
  50. Liu, Y.; Wang, Z.; Han, K.; Shou, Z.; Tiwari, P.; Hansen, J. H. L. (October 2020). "Sensor Fusion of Camera and Cloud Digital Twin Information for Intelligent Vehicles". 2020 IEEE Intelligent Vehicles Symposium (IV): 182–187. arXiv:2007.04350. doi:10.1109/IV47402.2020.9304643.
  51. Wang, Z.; Han, K.; Tiwari, P. (October 2020). "Augmented Reality-Based Advanced Driver-Assistance System for Connected Vehicles". 2020 IEEE International Conference on Systems, Man, and Cybernetics (SMC): 752–759. arXiv:2008.13381. doi:10.1109/SMC42975.2020.9283462.
  52. Vandermerwe, Sandra; Rada, Juan (Winter 1988). "Servitization of business: Adding value by adding services". European Management Journal. 6 (4): 314–324. doi:10.1016/0263-2373(88)90033-3.
  53. Tilson, David; Lyytinen, Kalle; Sørensen, Carsten (December 2010). "Digital Infrastructures: The Missing IS Research Agenda" (PDF). Information Systems Research. 21 (4): 748–759. doi:10.1287/isre.1100.0318. JSTOR 23015642.
  54. Grieves, Michael; Vickers, John (17 August 2016). Digital Twin: Mitigating Unpredictable, Undesirable Emergent Behavior in Complex Systems. Transdisciplinary Perspectives on Complex Systems. pp. 85–113. doi:10.1007/978-3-319-38756-7_4. ISBN 978-3-319-38754-3.
  55. Grieves, Michael. "Digital twin: manufacturing excellence through virtual factory replication. Retrieved from" (PDF).
  56. Hamilton, Dean (2017-08-25). "Seeing double: why IoT digital twins will change the face of manufacturing". Networkworld. Retrieved September 23, 2018.
  57. Cai, Yi (2017). "Sensor Data and Information Fusion to Construct Digital-twins Virtual Machine Tools for Cyber-physical Manufacturing". Procedia Manufacturing. 10: 1031–1042. doi:10.1016/j.promfg.2017.07.094.
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