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Digital twins are emerging as a key tool for improving the design, testing, and operation of Hall thrusters by integrating real-time data with high-fidelity simulations.
Researchers at Imperial College London have proposed a modular computing framework using machine learning to enhance predictive modeling and optimize thruster performance.
Challenges include high computational costs, real-time data integration, and the need for industry-wide validation standards, but cloud-based solutions and collaboration could accelerate adoption.
Digital twins are emerging as a transformative tool for the development and deployment of Hall thrusters, a critical propulsion technology for space missions. By improving design accuracy, reducing costs, and enabling real-time monitoring, these virtual models offer a new approach to testing and operation. In a study, researchers from Imperial College London’s Plasma Propulsion Laboratory have outlined key requirements and computing infrastructure needed to make digital twins viable for space propulsion.
The Role of Digital Twins in Space Propulsion
Electric propulsion (EP), particularly Hall thrusters, is becoming increasingly essential for satellite station-keeping and interplanetary missions. These thrusters provide fuel efficiency advantages over chemical propulsion, but their qualification and testing processes are expensive and time-consuming. Digital twins, which continuously update based on real-world data, could improve these processes by providing predictive insights into thruster performance and potential failures.
The study proposes digital twins as a solution to streamline EP system development, qualification, and operation. Unlike traditional static simulations, digital twins dynamically refine their models based on real-time sensor data, offering a more accurate and adaptable approach to propulsion system monitoring and optimization.
Overcoming Development Challenges
Hall thrusters require thousands of hours of reliable operation, and current testing methods rely on vacuum chambers that cannot fully replicate space conditions. This limitation increases the risk of discrepancies between ground testing and in-orbit performance, making it difficult to predict long-term reliability. Conventional qualification methods are also costly and lack comprehensive risk assessment frameworks.
Digital twins could mitigate these challenges by continuously incorporating operational data to refine performance models. This real-time feedback would allow engineers to identify issues early, optimize design parameters, and extend thruster lifetimes without the need for extensive physical testing. The ability to simulate performance variations under different conditions would also enhance mission planning and risk management.
Computing Infrastructure and Machine Learning Integration
To function effectively, digital twins must integrate high-fidelity simulations with real-world data while maintaining computational efficiency. The study outlines a modular computing framework composed of multiple sub-models that represent different aspects of a Hall thruster’s operation, including plasma dynamics, gas flow, and electromagnetic fields.
Machine learning plays a key role in improving the predictive power of digital twins. The study introduces a Hierarchical Multiscale Neural Network (HMNN) designed to model thruster behavior over time while minimizing errors. This method balances accuracy and computational efficiency by integrating multiple time scales into a single model. Additionally, a machine-learning-based compressed sensing tool, the Shallow Recurrent Decoder (SHRED), allows for real-time monitoring of thruster performance using minimal sensor data, reducing the need for extensive onboard diagnostics.
Challenges and Future Directions
Despite their potential, digital twins still face significant hurdles. High-fidelity plasma simulations, particularly those using particle-in-cell (PIC) methods, require extensive computational resources. The study presents a reduced-order PIC (RO-PIC) approach that reduces these costs while maintaining predictive accuracy, offering a potential solution for more practical implementations.
Integrating digital twins with real-time spacecraft operations remains another challenge. The study suggests that cloud-based and distributed computing frameworks could help scale the technology, while industry-wide collaboration is needed to establish standardized validation and verification frameworks. These steps would ensure that digital twins meet the reliability requirements necessary for adoption in mission-critical applications.
Broader Impact and Market Potential
The development of digital twins for Hall thrusters could serve as a foundation for broader applications in electric propulsion, including gridded ion thrusters and emerging nuclear fusion propulsion technologies. A key principle in digital twin design is generalizability, ensuring that advancements in one propulsion system can be applied across multiple technologies.
The market potential for digital twins is significant. Industry reports project that the digital twin market across aerospace, manufacturing, and transportation could grow from $6.5 billion in 2021 to $125.7 billion by 2030. With increasing investment from the European Space Agency and other organizations, the adoption of digital twins in space technology is expected to accelerate.
According to the researchers, digital twins offer a transformative approach to Hall thruster design, qualification, and operation by integrating high-fidelity simulations with real-time data. By reducing costs and improving predictive capabilities, they could enhance the reliability of electric propulsion systems for future space missions.
Read more about the study in Space Insider.
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