How the cps works?

The word cyber or cyber refers to what is related to or involves computers or computer networks, when the term 'Cyber-Physical Systems' (CPS) is used, reference is made to a union between a world of physical components capable of being autonomous with a digital world capable of controlling what happens in the physical. These are systems in which a computing capacity with a network infrastructure is capable of coordinating or controlling physical processes at different scales through the use of information and communication technologies

An example of a system that is related to safer driving is stability control, which is an example of a system that is related to self-drive.

Another example is the intelligent electrical networks or "Smart Grids" where cybernetic processes make it possible to manage the energy supply in wide-coverage networks, cities, regions or countries, in addition to acting in pursuit of optimal and efficient energy management based on the capacity of energy producers and the consumption characteristics of customers.

The Internet of Things, also known as the Internet of Things, can be seen as a subset of the rest of the network, focusing on physical devices that are controllable and available as part of a network connected to the internet. We could mention smart homes that incorporate video surveillance systems accessible from the internet, and household appliances, lamps, and alarms that are capable of being controlled from mobile phones with internet access.

The industrial internet of things is about the integration of internet of things into industrial processes. It is about using machinery, product transportation, and industrial infrastructure in a more efficient way.

I4.0, or industry 4.0 is synonymous with the fourth industrial revolution, this is a smart factory concept that incorporates CPS + IIoT with artificial intelligence in such a way that a high adaptability to the needs of the markets and consequently of the processes is achieved. production, together with the most efficient and intelligent use of resources.

Transport, energy, health, manufacturing, infrastructure and smart cities are just a few of the application domains that are important to theCPS.

The combined advances of multiple technologies driven by the trend of involving multidisciplinary work teams are marking a technological change where new types of systems and "systems of systems" are emerging within domains as mentioned in preliminary paragraphs, the CPS are becoming autonomous, intelligent, connected and collaborative, resulting in the emergence of Cyber ​​Physical Systems of Systems (CPSoS).

There are five examples of changes related to societies, their well-being and development that can be mentioned in the scenarios for the future potential of the CPS.

Let's imagine, for example, a company that integrates its work processes through software, a marketing system that achieves online sales and that these in turn are sent as records of an ERP system which interacts with the manufacturing and personalization processes of purchases, that is to say that a digital transaction is capable of intelligently and autonomously triggering a physical manufacturing process.

The systems and processes incorporate more and more artificial intelligence components because of the dynamics of the transactions, the volumes of data, and the behavior of the markets.

To achieve something like this, the challenges are mainly: technological in terms of the performance of software tools, managing an adequate coupling to constant innovation and accelerated changes based on time, economic regarding investment, return and models such as circular economy, training of professionals capable of addressing integrated solutions in collaborative and multidisciplinary work teams, the legislation that affects the implementation of SCPs and changes in societies (generational, behavioral, consumer).

Interoperability between systems is a big challenge, since the tendency is to integrate different approaches, providers, devices, and communication protocols, which introduces a large component of complexity in the design and development of the system.

If we analyze the complexity of computers integrated into electronic systems of automobiles,robots, devices for medical use and, in general, electronic instruments of daily life, it can be seen that it is increasing from the perspective of engineering and friendlier. It's important that embedded software defects don't pose a risk to people's lives or the economy, because from the user's point of view it's important that they are reliable.

Electronics, software engineering, computer networks, communications electronics, economics and finance use their own languages and methodologies. In order to provide a framework that allows these disciplines to cooperate with each other and generate collaborative work models that can be implemented effectively, lines of research are required.

The word cyber or cyber refers to what is related to or involves computers or computer networks, when the term 'Cyber-Physical Systems' (CPS) is used, reference is made to a union between a world of physical components capable of being autonomous with a digital world capable of controlling what happens in the physical. These are systems in which a computing capacity with a network infrastructure is capable of coordinating or controlling physical processes at different scales through the use of information and communication technologies.

An example of a system that is related to safer driving is stability control, which is an example of a system that is related to self driving. Another example is the intelligent electrical networks or "Smart Grids" where cybernetic processes make it possible to manage the energy supply in wide-coverage networks, cities, regions or countries, in addition to acting in pursuit of optimal and efficient energy management based on the capacity of energy producers and the consumption characteristics of customers.

The Internet of Things, also known as the Internet of Things, can be seen as a subset of the rest of the network, focusing on physical devices that are controllable and available as part of a network connected to the internet.

We could mention smart homes that incorporate video surveillance systems accessible from the internet, and household appliances, lamps, and alarms that are capable of being controlled from mobile phones with internet access.

The industrial internet of things is about the integration of internet of things into industrial processes. It is about using machinery, product transportation, and industrial infrastructure in a more efficient way.

I4.0, or industry 4.0 is synonymous with the fourth industrial revolution, this is a smart factory concept that incorporates CPS + IIoT with artificial intelligence in such a way that a high adaptability to the needs of the markets and consequently of the processes is achieved. production, together with the most efficient and intelligent use of resources.

Transport, energy, health, manufacturing, infrastructure and smart cities are just a few of the application domains that are important to the role of CPS.

The combined advances of multiple technologies driven by the trend of involving multidisciplinary work teams are marking a technological change where new types of systems and "systems of systems" are emerging within domains as mentioned in preliminary paragraphs, the CPS are becoming autonomous, intelligent, connected and collaborative, resulting in the emergence of Cyber ​​Physical Systems of Systems (CPSoS).

There are five examples of changes related to societies, their well-being and development that can be mentioned in the scenarios for the future potential of the CPS.

Let's imagine, for example, a company that integrates its work processes through software, a marketing system that achieves online sales and that these in turn are sent as records of an ERP system which interacts with the manufacturing and personalization processes of purchases, that is to say that a digital transaction is capable of intelligently and autonomously triggering a physical manufacturing process.

The systems and processes incorporate more and more artificial intelligence components because of the dynamics of the transactions, the volumes of data, and the behavior of the markets.

To achieve something like this, the challenges are mainly: technological in terms of the performance of software tools, managing an adequate coupling to constant innovation and accelerated changes based on time, economic regarding investment, return and models such as circular economy, training of professionals capable of addressing integrated solutions in collaborative and multidisciplinary work teams, the legislation that affects the implementation of SCPs and changes in societies (generational, behavioral, consumer).

Interoperability between systems is a big challenge, since the tendency is to integrate different approaches, providers, devices, and communication protocols, which introduces a large component of complexity in the design and development of the system.

If we analyze the complexity of computers integrated into electronic systems of automobiles,robots, devices for medical use and, in general, electronic instruments of daily life, it can be seen that it is increasing from the perspective of engineering and friendlier. It's important that embedded software defects don't pose a risk to people's lives or the economy, because from the user's point of view it's important that they are reliable.

Electronics, software engineering, computer networks, communications electronics, economics and finance use their own languages and methodologies. In order to provide a framework that allows these disciplines to cooperate with each other and generate collaborative work models that can be implemented effectively, lines of research are required.

The word cyber or cyber refers to what is related to or involves computers or computer networks, when the term 'Cyber-Physical Systems' (CPS) is used, reference is made to a union between a world of physical components capable of being autonomous with a digital world capable of controlling what happens in the physical. These are systems in which a computing capacity with a network infrastructure is capable of coordinating or controlling physical processes at different scales through the use of information and communication technologies

An example of a system that is related to safer driving is stability control, which is an example of a system that is related to self driving. Another example is the intelligent electrical networks or "Smart Grids" where cybernetic processes make it possible to manage the energy supply in wide-coverage networks, cities, regions or countries, in addition to acting in pursuit of optimal and efficient energy management based on the capacity of energy producers and the consumption characteristics of customers.

The Internet of Things, also known as the Internet of Things, can be seen as a subset of the rest of the network, focusing on physical devices that are controllable and available as part of a network connected to the internet. We could mention smart homes that incorporate video surveillance systems accessible from the internet, and household appliances, lamps, and alarms that are capable of being controlled from mobile phones with internet access.

The industrial internet of things is about the integration of the internet of things into industrial processes. It is about using machinery, product transportation, and industrial infrastructure in a more efficient way.

I4.0, or industry 4.0 is synonymous with the fourth industrial revolution, this is a smart factory concept that incorporates CPS + IIoT with artificial intelligence in such a way that a high adaptability to the needs of the markets and consequently of the processes is achieved. production, together with the most efficient and intelligent use of resources.

Transport, energy, health, manufacturing, infrastructure and smart cities are just a few of the application domains that are important to theCPS.

The combined advances of multiple technologies driven by the trend of involving multidisciplinary work teams are marking a technological change where new types of systems and "systems of systems" are emerging within domains as mentioned in preliminary paragraphs, the CPS are becoming autonomous, intelligent, connected and collaborative, resulting in the emergence of Cyber ​​Physical Systems of Systems (CPSoS).

There are five examples of changes related to societies, their well-being and development that can be mentioned in the scenarios for the potential future of the CPS.

Let's imagine, for example, a company that integrates its work processes through software, a marketing system that achieves online sales and that these in turn are sent as records of an ERP system which interacts with the manufacturing and personalization processes of purchases, that is to say that a digital transaction is capable of intelligently and autonomously triggering a physical manufacturing process. The systems and processes incorporate more and more artificial intelligence components because of the dynamics of the transactions.

To achieve something like this, the challenges are mainly: technological in terms of the performance of software tools, managing an adequate coupling to constant innovation and accelerated changes based on time, economic regarding investment, return and models such as circular economy, training of professionals capable of addressing integrated solutions in collaborative and multidisciplinary work teams, the legislation that affects the implementation of SCPs and changes in societies (generational, behavioral, consumer).

Interoperability between systems is a big challenge, since the tendency is to integrate different approaches, providers, devices, and communication protocols, which introduces a large component of complexity in the design and development of the system.

If we analyze the complexity of computers integrated into electronic systems of automobiles,robots, devices for medical use and, in general, electronic instruments of daily life, it can be seen that it is increasing from the perspective of engineering and more friendly. It's important that embedded software defects don't pose a risk to people's lives or the economy, because from the user's point of view it's vital that they are reliable.

Electronics, software engineering, computer networks, communications electronics, economics and finance use their own languages and methodologies.

In order to provide a framework that allows these disciplines to cooperate with each other and generate collaborative work models that can be implemented effectively, lines of research are required.