GE’s EnergoPro platform enables high-fidelity digital twin simulation of industrial power systems. However, default training regimes for its embedded neural control agents often fail under real-world volatility—leading to slow convergence, overfitting to nominal loads, and poor response to transient faults. This paper introduces Adaptive Resilience Training (ART) , a three-stage meta-learning framework for EnergoPro’s control agents. ART combines (1) curriculum learning from synthetic fault injection, (2) adversarial perturbation of load forecasts, and (3) online fine-tuning with truncated backpropagation through time (TBPTT). Using a 14-bus industrial microgrid modeled in EnergoPro GE, we show that ART reduces voltage sag recovery time by 41% and improves out-of-distribution robustness by 33% compared to standard supervised training. Key insights include the importance of phase imbalance augmentation and the discovery of a “resonant overfitting” phenomenon unique to EnergoPro’s solver. The proposed method is implemented as a wrapper script, compatible with GE’s existing API.
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The difference between a user who simply "clicks buttons" and a true power system analyst lies in structured education. By investing in comprehensive , you are not just learning software commands; you are learning engineering intuition backed by simulation rigor. The proposed method is implemented as a wrapper