A hybrid system using synthetic-pretrained denoisers for trajectory reconstruction, Lorenz ODE fitting for short forecasts, and histogram-tail substitution for long-time statistics achieved 83.83551 on the Lorenz challenge leaderboard.
CTF4Nuclear: Common Task Framework for Nuclear Fission and Fusion Models
3 Pith papers cite this work. Polarity classification is still indexing.
abstract
The demand for clean energy is ever increasing, with new nuclear technologies presenting a complementary solution to renewable energies. However, designing and operating these systems is exceptionally difficult, given the complexity of the physical phenomena that interact to form the system dynamics. While high-fidelity simulations help to understand the non-linear, multi-physics interactions within a reactor, they are computationally expensive and rarely suitable for real-time applications. Furthermore, model-based approaches are inherently sensitive to simplifying assumptions required to derive their governing equations and parameters, leading to inevitable discrepancies with real-world measurements. In contrast, Machine Learning (ML) methods have the potential to generate reliable surrogate models which may be able to quickly predict the system's behaviour. However, the number of data-driven methods that can potentially be used for this task is large and diverse. In a safety-critical setting such as nuclear engineering, a fair comparison of different ML methods, and a clear understanding of their advantages and limitations, is of paramount importance. To address this, we introduce a Common Task Framework (CTF) for ML in nuclear engineering, building upon previous efforts in dynamical systems and seismology. This CTF considers a curated set of datasets from different nuclear and nuclear-adjacent systems. The CTF evaluates the performance of a method on 12 established metrics, alongside a new paradigm focused on system monitoring from sparse measurements only. We illustrate the framework by benchmarking standard ML baselines against these datasets, revealing current method limitations. Our vision is to replace ad hoc comparisons with standardized evaluations on hidden test sets, raising the bar for rigour and reproducibility in scientific ML for the nuclear industry.
years
2026 3verdicts
UNVERDICTED 3representative citing papers
Adaptive ESN framework with scenario-specific techniques like exact state synchronization and histogram-guided selection achieves 74.91 on the CTF-4-Science Lorenz benchmark.
Divide-and-conquer modeling using scenario-specific techniques reaches a public score of 79.63 on the CTF-4-Science Lorenz benchmark.
citing papers explorer
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Metric-Aware Hybrid Forecasting for the CTF4Science Lorenz Challenge
A hybrid system using synthetic-pretrained denoisers for trajectory reconstruction, Lorenz ODE fitting for short forecasts, and histogram-tail substitution for long-time statistics achieved 83.83551 on the Lorenz challenge leaderboard.
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Adaptive Reservoir Computing for Multi-Scenario Chaotic System Forecasting
Adaptive ESN framework with scenario-specific techniques like exact state synchronization and histogram-guided selection achieves 74.91 on the CTF-4-Science Lorenz benchmark.
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Divide-and-Conquer Modeling for the CTF-4-Science Lorenz Benchmark
Divide-and-conquer modeling using scenario-specific techniques reaches a public score of 79.63 on the CTF-4-Science Lorenz benchmark.