Digital Twin
🧑🔬 DI in Industry (DIiI)
Neu-Ulm University of Applied Sciences
February 1, 2023
Introduction
Companies can begin the journey by starting with just one digital twin that has a data product at its core, evolving it over time to provide increasingly powerful predictive capabilities and the foundation of an enterprise metaverse. McKinsey & Co.
Relevance
Digital twins are among the most promising digital technologies being developed at present.
Digital twin technology provides capabilities to enable new business models and decision support systems by incorporating data collected from multiple sources and analytic capabilities (e.g., visualizations, behavioral insights).
The concept has seen increasing interest in recent years in both academia and industry as indicated by the growth of publications, articles, and commercial marketing (VanDerHorn and Mahadevan 2021).
Origins
The concept originates is nearly 15 years old and stems from the field of product lifecylce management (Grieves 2014).
The development of the concept was motivated shift from the predominantly paper-based and manual product data to a digital model of the product.
Focusing on connecting physical with digital systems, the digital twin has similarities to concepts like Cyber Physical Systems (CPS, control of production systems) and Internet of Things (IoT, networking physical devices).
Definition
VanDerHorn and Mahadevan (2021) propose a consolidated and generalized definition, with clearly established characteristics to distinguish what constitutes a digital twin and what does not.
A digital twin is “a virtual representation of a physical system (and its associated environment and processes) that is updated through the exchange of information between the physical and virtual systems.” VanDerHorn and Mahadevan (2021, 2)
The digital twin can be characterized by three primary components:
- A physical reality,
- a virtual representation, and
- interconnections that exchange information between the physical reality and virtual representation
Components
Dicussion
Based on the definitions, a simple 3-D visualization or stand-alone simulation would not be considered a digital twin.
What are key requirements of a digital twin?
Related concepts
The concept of digital twins bears similarities to more traditional digital modeling approaches (e.g., computer-aided design (CAD) and product lifecycle management (PLM) tools).
However, two key requirements for a digital twin that make it unique from traditional digital modeling approaches (VanDerHorn and Mahadevan 2021, 5).:
- A digital twin represents a single instance of the system of interest
(not a class or fleet of systems) and - the digital twin updates its description of that system as it changes over time.
Systems of digital twins
Business value can be increased by interconnecting digital twins to complex ecosystems.
Such interconnected digital twins allow, e.g., to
- simulate the complex relationships among different entities and generate richer behavioral insights and
- incorporate dependencies and correlations into the models (by analyzing the interactoins)
Example
Combining the digital twins of customers with the twins of retail and online shops would enable the creation of outstanding omnichannel experiences that seamlessly support the customer journey across all channels.
Implementation types
According to VanDerHorn and Mahadevan (2021), current industry implementations of digital twins can be generally grouped into three categories:
- Digital twin component solutions (e.g., provided by Microsoft),
- commercial off-the-shelf solutions (e.g., provided by OEMs like GE or Siemens), or
- custom hybrid combinations.
Examples
McKinsey and Co. outline following examples for digital twins:
- SoFi stadium (in California)
- To help optimize stadium management and operations, a digital twin aggregates multiple data sources, including information about the stadium’s structure and real-time footfall data.
- SpaceX
- A digital twin of the Dragon capsule enables operators to monitor and adjust trajectories, loads, and propulsion systems. The goal is to maximize reliability and safety during transport.
- Anheuser-Busch InBev
- A brewing and supply chain digital twin enables brewers to adjust inputs (for instance, “add more hops to mixer #3”) based on active conditions and can automatically compensate for production bottlenecks when, for example, vats are full. It also gives the company’s production engineers remote assistance and AR capabilities for live troubleshooting on how to fix pump leaks and other common issues.
Future application fields
The growing consensus is that digital twin implementation will expand in many areas including healthcare as promising field (Saracco 2019).
Digital twin applications in healthcare and education imply that the concept will be extended from artificial systems to people.
The availability of millions of digital twins of people would make inference possible (e.g., by applying AI) and help practitioners gain knowledge that could be used for precision medicine and proactive health care.
Technology challenges
Saracco (2019, 62) outlines following challenges related to the design and implementation of digital twins:
Interoperability of digital models: there are different ways to create digital models, which hampers portability of models within and across different areas.
Data interconnection: synchronization between the physical twin and its virtual representation requires pervasive and affordable communication channels (e.g., 5G or LoraWan).
Extended digital twins: when the concept evolves to go beyond mirroring and shadowing a physical counterpart (e.g., by taking action on behalf of its physical counterparts), twins need to be open to data exchanges beyond the twin relationship, while preserving their identities and the association with their physical doubles.
Data privacy, availability, and ownership: data architecture must ensure that data is secure, portable, and can be controlled by the owner.