Abstract
Robot-based platforms and processes have integrated the security and efficiency of data into a comprehensive range of domains like manufacturing, industrial, logistical, agricultural, healthcare, and Internet services. Smart cyberattacks have been on the rise, specifically targeting corporate and industrial robotic systems. These attacks are executed once the IoT, Internet, and organization integration is implemented with the industrial units. The authors implemented security criteria-based indices for Cyber-Physical systems (CPS) with industrial components and embedded sensors that process the information logs and processes. The authors proposed an attack tree-based secure framework that does not include every CPS device; however, it takes into consideration the critical exploitable vulnerabilities to execute the attacks. The authors categorized each physical device and integrated sensors based on logs and information in a sensor indices device library. This research simulated the real-time exploitation of vulnerabilities in CPS robotic systems using the proposed framework in the form of a two-phased process. This validates the enhanced data security output of the integrated sensor and physical nodes with the intelligent monitor and controller system health monitor during real-time cyberattacks. This research simulated common cyberattacks on cyber-physical controller servers based on cross-site scripting and telnet pivoting. The authors gathered known and unknown vulnerabilities and exploited them with a tree-based attack algorithm. The authors calculated the average time for cyberattackers with different skills when trying to compromise CPS devices and systems.