More specifically, this project focuses on applications to connected vehicle systems where vehicles are capable of sharing information via dedicated short range communication (DSRC) network, with the goal of improving fuel efficiency of the system and avoiding collision. Principal Investigator: Pierluigi Pisu Richard Brooks Jim Martin overarching vision of this project is to accelerate the deployment of security measures for cyber-physical systems by developing cyber-attack detection and control countermeasure methodologies for networked distributed cyber-physical systems (CPSs) that are resilient to worst-case cyber-attack scenarios and therefore capable of satisfy more stringent system safety and performance requirements. As CPS continues to evolve, it is crucial to address security concerns, tackle challenges, and foster collaboration between various stakeholders to fully unlock its transformative potential.CPS Connected Vehicle Systems and Cybersecurity CPS: Synergy: Security of Distributed Cyber-Physical Systems with Connected Vehicle Applications By leveraging sensors, communication networks, and intelligent algorithms, CPS enhances the capabilities of physical systems, paving the way for a smarter, more sustainable future. From smart cities to industrial automation, CPS unleashes a new wave of innovation, efficiency, and connectivity. Additionally, addressing privacy concerns and managing the massive amount of data generated by CPS pose ongoing challenges that require careful consideration and regulation.Ĭyber-Physical Systems (CPS) represent a groundbreaking integration of physical and digital technologies, revolutionizing the way we interact with the world. Safeguarding CPS requires robust security measures, including encryption, authentication, access control, and intrusion detection systems. The interconnected nature of CPS exposes them to potential cyber threats and vulnerabilities. Security and Challenges in CPSĪs CPS proliferates, ensuring the security and resilience of these systems becomes crucial. This capability not only enhances operational efficiency but also reduces downtime and maintenance costs. ![]() These systems, equipped with sensors and communication capabilities, interact with the physical environment, adapt to changing conditions, and collaborate with human operators to streamline production workflows.ĬPS also allows for remote monitoring and control of industrial processes, facilitating real-time decision-making and enabling efficient resource allocation. In addition, CPS enables the deployment of autonomous robots and intelligent machines in industrial settings. Real-time data collection and analysis enable adaptive manufacturing, predictive maintenance, and efficient supply chain management. CPS transforms traditional manufacturing facilities into cyber-physical manufacturing systems, integrating sensors, robotics, and intelligent algorithms. In the domain of industrial automation, CPS brings revolutionary advancements that optimize production processes, increase productivity, and enhance safety. Real-time data collection and analysis allow for early detection of faults, ensuring timely maintenance and preventing potential disasters. In addition, CPS enables continuous monitoring of critical urban infrastructure such as bridges, buildings, and water systems. By integrating renewable energy sources, energy storage systems, and smart meters, CPS-enabled smart grids optimize energy distribution, reduce waste, and promote energy efficiency. ![]() CPS also empowers smart grids with real-time monitoring, load balancing, and demand response capabilities. By reducing congestion, enhancing safety, and promoting sustainable mobility, CPS-driven ITS revolutionizes urban transportation. CPS facilitates the development of intelligent transportation systems, enabling real-time monitoring of traffic flow, optimizing signal timing, and implementing adaptive traffic management.
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