The digital twin concept was later divided into 3 types: the digital twin prototype (DTP), the digital twin example (DTI), and the digital twin aggregate (DTA). The DTP consists of the designs, analyzes and processes to build a physical product that, logically, are prior to its existence. The DTI is the digital twin of an individual instance of the product once manufactured. The DTA is the aggregation of several DTIs whose data can be used to simulate the behavior of the physical product. This does not mean that to have a digital twin of something there must be several copies of that something; Digital twins of unique systems can be built,[1]​ for example a hydrographic basin.[14]​ Nor does it mean that only digital twins of systems created by man, or in which he has intervened, can be programmed; Digital twins of completely natural systems can be created.[1]​.

Furthermore, digital twins can be divided into 3 subcategories according to the level of integration of physical data into the computing object: digital model, digital shadow and digital twin (DM, DS and DT for their respective acronyms in English).

It can be said that a digital twin is a type of computer simulation with the particularity that the physical object and the simulated object are very closely connected by cables and sensors. In other computer simulations the computer object and the real object are completely disconnected, or there is no real object.

An example of digital twins is the use of 3D Modeling to create digital companions of physical objects.[15]​[16]​[17]​[7]​[8]​ This modeling can be used to get an idea of what an unmanufactured physical object would look like.[18]​ When it has been manufactured, data from sensors can be used to update the digital twin in real time.[19]​[20]​[21]​ The term "device" is also used. shadow" (shadow device) to refer to a digital twin. The digital twin is intended to accurately reproduce all the relevant behaviors of its physical counterpart.[22] Continuing with the previous example, a digital twin of a turbine will accurately deliver (variable depending on the quality of the programming) the data on the power supplied, but not the data on the dirt deposited on the turbine casing, since that, in principle, is not relevant.

A digital twin can also be used for monitoring, diagnosis and preventive maintenance, thus optimizing the performance of the physical counterpart. Real-time data from sensors can be combined with historical data, human experience, and simulations to bring the twin's output data even closer to the physical output of its counterpart.[23]​ Therefore, digital twins can be used to diagnose problems and improve productivity.[24]​.

Digital twins of autonomous vehicles have been proposed in a simulated traffic environment to overcome current development challenges (to get an autonomous vehicle to work, it must be tested in real traffic, and if it doesn't work, that poses a danger to other drivers). Especially when the algorithms are based on artificial intelligence, which requires large training and validation data sets[25].

The digital twin is completely changing the lifecycle management (PLM) of manufacturing a product, from design to operation.[26]​ PLM is currently time-consuming and expensive.[27]​ The digital twin allows the company to see its products not only through the eyes of the manufacturer, but also through the eyes of the buyer.[28]​[29]​ For example, a company produces a new machine for sawing wood. Having in that same company a copy of that machine sawing physical wood, to see how it behaves, would be expensive and complicated. But with a good digital twin, buyers can be recommended the optimal greasing and adjustment actions at 3 months, 6 months and one year.

The digital twins of production chains have substantially changed physical chains, making it necessary to introduce many more sensors. To control a production chain that does not use a digital twin, it is necessary to place sensors, but if it does use one, many more must be placed, to also collect data on environmental conditions or machine behavior.[28]​.

Due to the Internet of Things, digital twins have become more affordable and could drive the future of the manufacturing industry. Advanced forms of facility management and maintenance become possible due to the existence of their digital twins.[30]​.

Digital twins offer great business potential because they forecast the future of the manufacturing process instead of analyzing the past.[31]​ The representation of reality created by digital twins allows manufacturers to evolve towards ex-ante business practices.[26]​ The following 4 aspects drive the future of manufacturing: modularity, autonomy, connectivity and digital twins.[32]​ As digitalization increases in the stages of a manufacturing process, opportunities arise for greater productivity. This starts with modularity. Autonomy then allows the production system to respond to unexpected events effectively and intelligently. Finally, connectivity, such as the Internet of Things, closes the digitalization loop.[32]​.

Appropriate use of digital twins allows buyers of a product to be warned before a problem appears, which can increase their satisfaction and loyalty.[26]​ Furthermore, as the costs of storing and processing data are falling, the ways to use digital twins are increasing.[28]​.

Geographic digital twins have become popular in urban planning because smart cities increasingly need digital technology. These digital twins often take the form of interactive platforms to capture and display real-time 3D visualizations of urban environments.[33] Some even allow 4D (the usual 3 dimensions plus time, forward and backward, with a slider).

Visualization technologies such as augmented reality (AR) are used to collaborate in urban design by integrating sensor data and application programming interface services with the aim of forming digital twins.[34]​.

Urban planning activities, including maintenance, are increasingly digitalized, in part due to the adoption of building information modeling (BIM). Given the advantages of digital twins, they are considered a logical extension. In the United Kingdom in November 2018, for example, the Center for a Digitally Built Britain published The Gemini Principles,[35]​ (gemini is a Latin root for "twin", which has given words such as "geminated") outlining directions for the development of a "national digital twin".[36]​.

One of the first examples of a functional digital twin was achieved in 1996 during the construction of the Heathrow Express facility at London Heathrow Airport Terminal 1. Consultant Mott MacDonald and BIM pioneer Jonathan Ingram connected motion sensors placed in the cofferdam of the actual construction to the digital object. Thus, by contemplating the digital twin, one could appreciate the movements that were taking place in reality. A digital model was also made for the ground compaction process, which controlled the effects of injecting grout (a type of mortar) in order to stabilize ground movements.[37]​.

Digital twins enable new possibilities in healthcare.[38]​[27]​ They were first proposed to predict the behavior of medical instruments (for example, a computerized axial tomography (CT) machine).[27]​ With a digital twin, lives can be improved in terms of health, sports and education by focusing on healthcare based more on data.[26]​ Technologies are available to build models, not only of machines, but of patients*, continuously adjustable according to physical parameters. (cholesterol, heart rate, age, weight, exercise) that are collected. This can ultimately lead to a virtual patient. In addition, the digital twin makes it easy to compare the health parameters of a specific person with those of the average population to find detailed patterns.[38]​.

It is possible to construct digital twins of a specific patient's organ, in particular the heart.[39]​ With the digital twin of the heart of a person affected by cardiac pathology, doctors can study the optimal implantation of a pacemaker or the possible results of inserting a valve.

The biggest benefit of the digital twin in healthcare is that it can be custom designed to anticipate the responses of individual patients. Digital twins not only lead to better diagnoses of an individual patient, but can also change the expected image of a healthy patient. Previously, "healthy" was considered to be "absent from symptoms of disease." Now "healthy" patients can be compared with the rest of the population to gauge whether they are really that healthy.[38]​ However, digital twins in healthcare also have some disadvantages: they can generate inequality, because the rich will be able to afford them and the poor will not; and they can also identify patterns that generate discrimination.[38][40]​.

The automotive industry has been enhanced by digital twin technology, which is used to facilitate processes and reduce marginal costs. Today, automobile designers expand materiality by incorporating digital possibilities.[41] An example is the analysis of how a specific car drives. From there the incorporation of new features that reduce the risk of accidents may arise.[42]​.

Connectivity

Firstly, the digital twin is connected to its physical counterpart. This is an essential part of digital twin technology, which would not exist without that connection. As already described, this connectivity is achieved through sensors in the physical object and its environment, and through cables or radio transmitters that carry the data to the computer where the digital twin resides.

Digital twins facilitate the outsourcing of the industry. Industry is the secondary sector of the economy. Through digital twins, the industry can offer services (tertiary sector), maintenance for example, thus diversifying its activity and entering new business areas.[43]​.

Homogenization

Digital twins can be considered both a cause and a consequence of data homogenization. As any type of information can be stored and transmitted digitally, if this is done in the form of a digital twin, the information is decoupled from the physical counterpart.[44]​ Digital twins also facilitate the digital storage of information about a product.[41]​.

It is much easier to process digital data at low cost.[41]​ According to Moore's law, computing power will continue to increase exponentially, while its cost decreases. This will lead to lower marginal costs of developing digital twins and making it much cheaper to test, forecast and troubleshoot digital twins than physical models.

Another consequence of the homogenization and decoupling of information is that the user experience converges. As the information of a physical object is digitized, that same object can, in the digital world, be split into several, to study different aspects.[41]​ The digital twin allows any number of agents to share detailed information about a physical object without time or location restrictions.[45]​ In his white paper on digital twin technology in the manufacturing industry, Michael Grieves highlights the following about the consequences of homogenization:[46]​.

Reprogrammable and intelligent

Since the digital twin is a computer system, it can be reprogrammed. A consequence of this reprogrammable nature is the emergence of functionality.[47]​ Taking the example of an engine again, its digital twin can be used to collect data on its performance, both in its exact physical configuration and if the pistons or valves are slightly modified. In this way an improved version of the product can be promoted.

Digital traces

Another feature is that digital twins leave digital traces (stored data). Engineers can consult these traces in order to, for example, when a machine fails, see when and how the behavior of the physical counterpart began to differ from the digital one, in order to diagnose the problem.[48] The manufacturer can also use this diagnosis to improve their designs, so that the failure occurs less in the future.

Modularity

Modularity means the ability to be divided into parts that can be treated separately.[32]​ If a product is modular, and something needs to be changed in it, only the module where that something is located can be changed. Digital twin technology allows manufacturers to track their machines and see potential areas for improvement.

The concept of a digital twin consists of 3 different parts: the physical object or system, the computer object, and the connections between them. These connections are the data and its transmission media (cables, radio frequency, laser, ultrasound, etc.). Data is taken from the physical object and its environment using sensors and meters and entered into the computing object. This object does not have to present a visual appearance on the screen similar to that of the physical object. A perfectly functional digital twin may simply consist of sensors, wiring, a computer, and lines of computer code. The important thing is that it takes the necessary variables from the physical object and its environment to faithfully reproduce its behavior, and that the treatment of these variables is appropriate.

For a digital twin to be reliable, it must have collected data from the physical object not only under normal conditions, but also in anomalous situations. Even so, if the physical inputs are very different from those expected, or the data communication is not correct, or unforeseen events occur (an internal crack in the physical object, for example), the outputs of the digital twin may differ from those of the physical object.

From the same physical system (for example a river) different digital twins can be built that reside on different computers and are managed by separate teams of people, and that take different aspects into account. Continuing with the example, a digital twin could simulate the behavior of the river in the face of strong storms, while another could predict the progression of a polluting spill.

A digital twin in the workplace is often considered part of robotic process automation (RPA). For the industrial analysis company Gartner it is part of the emerging, and broader, category of "hyperautomation."

The digital twin concept was later divided into 3 types: the digital twin prototype (DTP), the digital twin example (DTI), and the digital twin aggregate (DTA). The DTP consists of the designs, analyzes and processes to build a physical product that, logically, are prior to its existence. The DTI is the digital twin of an individual instance of the product once manufactured. The DTA is the aggregation of several DTIs whose data can be used to simulate the behavior of the physical product. This does not mean that to have a digital twin of something there must be several copies of that something; Digital twins of unique systems can be built,[1]​ for example a hydrographic basin.[14]​ Nor does it mean that only digital twins of systems created by man, or in which he has intervened, can be programmed; Digital twins of completely natural systems can be created.[1]​.

Furthermore, digital twins can be divided into 3 subcategories according to the level of integration of physical data into the computing object: digital model, digital shadow and digital twin (DM, DS and DT for their respective acronyms in English).

It can be said that a digital twin is a type of computer simulation with the particularity that the physical object and the simulated object are very closely connected by cables and sensors. In other computer simulations the computer object and the real object are completely disconnected, or there is no real object.

An example of digital twins is the use of 3D Modeling to create digital companions of physical objects.[15]​[16]​[17]​[7]​[8]​ This modeling can be used to get an idea of what an unmanufactured physical object would look like.[18]​ When it has been manufactured, data from sensors can be used to update the digital twin in real time.[19]​[20]​[21]​ The term "device" is also used. shadow" (shadow device) to refer to a digital twin. The digital twin is intended to accurately reproduce all the relevant behaviors of its physical counterpart.[22] Continuing with the previous example, a digital twin of a turbine will accurately deliver (variable depending on the quality of the programming) the data on the power supplied, but not the data on the dirt deposited on the turbine casing, since that, in principle, is not relevant.

A digital twin can also be used for monitoring, diagnosis and preventive maintenance, thus optimizing the performance of the physical counterpart. Real-time data from sensors can be combined with historical data, human experience, and simulations to bring the twin's output data even closer to the physical output of its counterpart.[23]​ Therefore, digital twins can be used to diagnose problems and improve productivity.[24]​.

Digital twins of autonomous vehicles have been proposed in a simulated traffic environment to overcome current development challenges (to get an autonomous vehicle to work, it must be tested in real traffic, and if it doesn't work, that poses a danger to other drivers). Especially when the algorithms are based on artificial intelligence, which requires large training and validation data sets[25].

The digital twin is completely changing the lifecycle management (PLM) of manufacturing a product, from design to operation.[26]​ PLM is currently time-consuming and expensive.[27]​ The digital twin allows the company to see its products not only through the eyes of the manufacturer, but also through the eyes of the buyer.[28]​[29]​ For example, a company produces a new machine for sawing wood. Having in that same company a copy of that machine sawing physical wood, to see how it behaves, would be expensive and complicated. But with a good digital twin, buyers can be recommended the optimal greasing and adjustment actions at 3 months, 6 months and one year.

The digital twins of production chains have substantially changed physical chains, making it necessary to introduce many more sensors. To control a production chain that does not use a digital twin, it is necessary to place sensors, but if it does use one, many more must be placed, to also collect data on environmental conditions or machine behavior.[28]​.

Due to the Internet of Things, digital twins have become more affordable and could drive the future of the manufacturing industry. Advanced forms of facility management and maintenance become possible due to the existence of their digital twins.[30]​.

Digital twins offer great business potential because they forecast the future of the manufacturing process instead of analyzing the past.[31]​ The representation of reality created by digital twins allows manufacturers to evolve towards ex-ante business practices.[26]​ The following 4 aspects drive the future of manufacturing: modularity, autonomy, connectivity and digital twins.[32]​ As digitalization increases in the stages of a manufacturing process, opportunities arise for greater productivity. This starts with modularity. Autonomy then allows the production system to respond to unexpected events effectively and intelligently. Finally, connectivity, such as the Internet of Things, closes the digitalization loop.[32]​.

Appropriate use of digital twins allows buyers of a product to be warned before a problem appears, which can increase their satisfaction and loyalty.[26]​ Furthermore, as the costs of storing and processing data are falling, the ways to use digital twins are increasing.[28]​.

Geographic digital twins have become popular in urban planning because smart cities increasingly need digital technology. These digital twins often take the form of interactive platforms to capture and display real-time 3D visualizations of urban environments.[33] Some even allow 4D (the usual 3 dimensions plus time, forward and backward, with a slider).

Visualization technologies such as augmented reality (AR) are used to collaborate in urban design by integrating sensor data and application programming interface services with the aim of forming digital twins.[34]​.

Urban planning activities, including maintenance, are increasingly digitalized, in part due to the adoption of building information modeling (BIM). Given the advantages of digital twins, they are considered a logical extension. In the United Kingdom in November 2018, for example, the Center for a Digitally Built Britain published The Gemini Principles,[35]​ (gemini is a Latin root for "twin", which has given words such as "geminated") outlining directions for the development of a "national digital twin".[36]​.

One of the first examples of a functional digital twin was achieved in 1996 during the construction of the Heathrow Express facility at London Heathrow Airport Terminal 1. Consultant Mott MacDonald and BIM pioneer Jonathan Ingram connected motion sensors placed in the cofferdam of the actual construction to the digital object. Thus, by contemplating the digital twin, one could appreciate the movements that were taking place in reality. A digital model was also made for the ground compaction process, which controlled the effects of injecting grout (a type of mortar) in order to stabilize ground movements.[37]​.

Digital twins enable new possibilities in healthcare.[38]​[27]​ They were first proposed to predict the behavior of medical instruments (for example, a computerized axial tomography (CT) machine).[27]​ With a digital twin, lives can be improved in terms of health, sports and education by focusing on healthcare based more on data.[26]​ Technologies are available to build models, not only of machines, but of patients*, continuously adjustable according to physical parameters. (cholesterol, heart rate, age, weight, exercise) that are collected. This can ultimately lead to a virtual patient. In addition, the digital twin makes it easy to compare the health parameters of a specific person with those of the average population to find detailed patterns.[38]​.

It is possible to construct digital twins of a specific patient's organ, in particular the heart.[39]​ With the digital twin of the heart of a person affected by cardiac pathology, doctors can study the optimal implantation of a pacemaker or the possible results of inserting a valve.

The biggest benefit of the digital twin in healthcare is that it can be custom designed to anticipate the responses of individual patients. Digital twins not only lead to better diagnoses of an individual patient, but can also change the expected image of a healthy patient. Previously, "healthy" was considered to be "absent from symptoms of disease." Now "healthy" patients can be compared with the rest of the population to gauge whether they are really that healthy.[38]​ However, digital twins in healthcare also have some disadvantages: they can generate inequality, because the rich will be able to afford them and the poor will not; and they can also identify patterns that generate discrimination.[38][40]​.

The automotive industry has been enhanced by digital twin technology, which is used to facilitate processes and reduce marginal costs. Today, automobile designers expand materiality by incorporating digital possibilities.[41] An example is the analysis of how a specific car drives. From there the incorporation of new features that reduce the risk of accidents may arise.[42]​.

Connectivity

Firstly, the digital twin is connected to its physical counterpart. This is an essential part of digital twin technology, which would not exist without that connection. As already described, this connectivity is achieved through sensors in the physical object and its environment, and through cables or radio transmitters that carry the data to the computer where the digital twin resides.

Digital twins facilitate the outsourcing of the industry. Industry is the secondary sector of the economy. Through digital twins, the industry can offer services (tertiary sector), maintenance for example, thus diversifying its activity and entering new business areas.[43]​.

Homogenization

Digital twins can be considered both a cause and a consequence of data homogenization. As any type of information can be stored and transmitted digitally, if this is done in the form of a digital twin, the information is decoupled from the physical counterpart.[44]​ Digital twins also facilitate the digital storage of information about a product.[41]​.

It is much easier to process digital data at low cost.[41]​ According to Moore's law, computing power will continue to increase exponentially, while its cost decreases. This will lead to lower marginal costs of developing digital twins and making it much cheaper to test, forecast and troubleshoot digital twins than physical models.

Another consequence of the homogenization and decoupling of information is that the user experience converges. As the information of a physical object is digitized, that same object can, in the digital world, be split into several, to study different aspects.[41]​ The digital twin allows any number of agents to share detailed information about a physical object without time or location restrictions.[45]​ In his white paper on digital twin technology in the manufacturing industry, Michael Grieves highlights the following about the consequences of homogenization:[46]​.

Reprogrammable and intelligent

Since the digital twin is a computer system, it can be reprogrammed. A consequence of this reprogrammable nature is the emergence of functionality.[47]​ Taking the example of an engine again, its digital twin can be used to collect data on its performance, both in its exact physical configuration and if the pistons or valves are slightly modified. In this way an improved version of the product can be promoted.

Digital traces

Another feature is that digital twins leave digital traces (stored data). Engineers can consult these traces in order to, for example, when a machine fails, see when and how the behavior of the physical counterpart began to differ from the digital one, in order to diagnose the problem.[48] The manufacturer can also use this diagnosis to improve their designs, so that the failure occurs less in the future.

Modularity

Modularity means the ability to be divided into parts that can be treated separately.[32]​ If a product is modular, and something needs to be changed in it, only the module where that something is located can be changed. Digital twin technology allows manufacturers to track their machines and see potential areas for improvement.