iFAN Ecosystem: A Unified AI, Digital Twin, Cyber-Physical Security, and Robotics Environment for Advanced Nuclear Simulation and Operations

As nuclear facilities experience digital transformation and advanced reactor development, AI integration, cyber-physical security, and other emerging technologies such as autonomous robot operations are increasingly developed. However, evaluation and deployment is challenged by the lack of dedicated virtual testbeds. The Immersive Framework for Advanced Nuclear (iFAN) ecosystem is developed, a comprehensive digital twin framework with a realistic 3D environment with physics-based simulations. The iFAN ecosystem serves as a high-fidelity virtual testbed for plant operation, cybersecurity, physical security, and robotic operation, as it provides real-time data exchange for pre-deployment verification. Core features include virtual reality, reinforcement learning, radiation simulation, and cyber-physical security. In addition, the paper investigates various applications through potential operational scenarios. The iFAN ecosystem provides a versatile and secure architecture for validating the next generation of autonomous and cyber-resilient nuclear operations.

iFANnpp: Nuclear Power Plant Digital Twin for Robots and Autonomous Intelligence

Robotics has gained significant attention due to its autonomy and ability to automate in the nuclear industry. However, the increasing complexity of robots has led to a growing demand for advanced simulation and control methods to predict robot behavior and optimize plant performance. Most existing digital twins only address parts of systems and do not offer an overall design of nuclear power plants. Furthermore, they are often designed for specific algorithms or tasks, making them unsuitable for broader research applications or other potential projects. In response, we propose a comprehensive nuclear power plant designed to enhance real-time monitoring, operational efficiency, and predictive maintenance. We selected to model a full-scope nuclear power plant in Unreal Engine 5 to incorporate the complexities and various phenomena. The high-resolution simulation environment is integrated with a General Pressurized Water Reactor Simulator, a high-fidelity physics-driven software, to create a realistic flow of nuclear power plant and a real-time updating virtual environment. Furthermore, the virtual environment provides various features and a Python bridge for researchers to test custom algorithms and frameworks easily. The digital twin's performance is presented, and several research ideas - such as multi-robot task scheduling and robot navigation in the radiation area - using implemented features are presented.