Cyber-physical Energy Systems

Cyber-physical energy systems integrate physical components, such as devices and mechanisms, with computer algorithms that control and manage them either locally or remotely. These systems represent the interaction between physical infrastructure, communication networks, and advanced control and management algorithms. 

With the shift toward decarbonization and the growing penetration of variable renewable energy sources, cyber-physical systems are becoming indispensable in maintaining the balance of supply and demand. The power grid is rapidly evolving into a complex cyber-physical system, requiring the coordination and management of millions of distributed devices. Notable examples include smart controlled charging for electric vehicles and the participation of household appliances in demand response programs. 

However, the deployment of such systems introduces critical concerns regarding stability, robustness, reliability, and security. As these systems become more pervasive, addressing these concerns is essential to ensure their safe and efficient operation. 

The testing and validation of cyber-physical energy systems involve addressing several critical challenges, including: 

• Performance Testing: Evaluating the operational performance of cyber-physical systems under varying conditions and scenarios. 

• Interoperability: Ensuring seamless communication and functionality between diverse system components. 

• Standards Compliance: Testing systems for compliance with existing and emerging standards to guarantee compatibility and reliability. 

• Cybersecurity Testing: Assessing vulnerabilities and ensuring robust protection against cyber threats to safeguard the integrity of cyber-physical systems. 

• Development of Benchmark Test Systems: Creating representative benchmark systems that enable consistent and reproducible testing of cyber-physical energy systems.