Katharina Kaiser, Gustavo Valverde, Gabriela Hug Β· Feb 09, 2026
Thermostatically controlled loads, electric vehicles, and other flexible devices can reduce power peaks in distribution networks by coordinating their use under some level of central control and limited information about the devices. A novel optimization-based control scheme has been proposed to flatten total load curves by restricting operating times while preserving customer comfort. The improved scheme achieves greater peak reductions in summer compared to the original formulation, nearly matching half of the potential daily peak reduction achieved by an ideal controller with perfect knowledge.
Why This Matters
This paper is relevant to power system engineers as it proposes a novel optimization-based control scheme for reducing residential peak loads, which can help grid operators and utility planners mitigate the impact of peak demand on low-voltage distribution networks. The results have practical significance for utilities planning and operating their systems, particularly in regions with high penetration of renewable energy sources.
Fen Wu Β· Feb 08, 2026
The paper addresses the robust $\mathcal{H}_2$ synthesis problem for LFT systems subject to structured uncertainty and white-noise disturbances, providing convex synthesis conditions in terms of linear matrix inequalities (LMIs) for both robust and gain-scheduled controller design. The proposed framework preserves the classical interpretation of the $\mathcal{H}_2$ criterion while providing certified robustness guarantees. Numerical examples demonstrate improved disturbance rejection compared to conventional robust $\mathcal{H}_{\infty}$-based designs.
Why This Matters
This paper's work on robust and gain-scheduling ${\cal H}_2$ control techniques for parameter-dependent systems is relevant to power system engineers, as it can be applied to mitigate the impact of uncertainty and disturbances on grid operations, such as improving disturbance rejection in ISO operations or enhancing resilience to grid failures. The proposed framework can also be used in FERC filings and NERC standards for grid reliability assessment.
Antonio AlcΓ‘ntara, Spyros Chatzivasileiadis Β· Feb 08, 2026
A trustworthiness layer for foundation models in power systems is introduced using stratified conformal prediction, providing adaptive and statistically valid confidence bounds for each output. This method enhances the accuracy of power system modeling by offering richer and more accurate information than traditional methods, with 2x-3x higher precision at faster speeds. The developed trustworthiness layer can also generalize to unseen high-order contingencies.
Why This Matters
This paper's contribution to developing a trustworthiness layer for foundation models in power systems is crucial for grid operators and utility planners, as it enables more accurate and reliable contingency assessment, which is essential for ensuring grid stability and reliability under various fault scenarios, such as N-k contingencies.
Arslan Ahmad, Ian Dobson Β· Feb 07, 2026
Quantifying resilience for distribution system customers involves tracking impact of routine smaller outages using conventional reliability indices, but large blackout events' customer minutes interrupted are difficult to quantify. A new resilience metric called System Average Large Event Duration Index SALEDI is proposed to logarithmically transform customer minutes interrupted, providing a more accurate measure. SALEDI has been compared with alternatives and illustrated in practice with standard outage data from five utilities.
Why This Matters
This paper's contribution to the development of the System Average Large Event Duration Index (SALEDI) provides a practical tool for power system engineers to quantify customer resilience in large blackout events, which is essential for grid operators and utility planners to ensure reliable and efficient operations. It has direct relevance to ISO operations and NERC standards, enabling utilities to better plan and respond to extreme events.
Β· Feb 09, 2026
A primal-dual-based active fault-tolerant control scheme has been proposed for cyber-physical systems, enabling optimality guarantees and stability in post-fault steady-state operation. This approach casts the problem as a constrained optimization problem and provides a framework that enforces network-level constraints and ensures exponential stability. The scheme's effectiveness is demonstrated through numerical experiments on a DC microgrid.
Β· Feb 09, 2026
Thermostatically controlled loads and electric vehicles can be used to reduce power peaks in low-voltage distribution networks by coordinating their operation centrally, using limited information about the devices. A novel optimization-based control scheme with prediction capabilities was proposed and tested, achieving greater peak reductions than an original formulation and nearly half of the potential average daily peak reduction achieved by an ideal controller. The improved scheme showed technical feasibility and design flexibility for real-world applications.
Β· Feb 08, 2026
The paper introduces a framework for robust and gain-scheduled ${\cal H}_2$ control techniques for linear fractional transformation systems subject to structured uncertainty and white-noise disturbances. It derives convex synthesis conditions in terms of linear matrix inequalities (LMIs) that enable both robust and gain-scheduled controller design for parameter-dependent systems. The proposed method provides certified robustness guarantees while preserving the classical interpretation of the ${\cal H}_2$ criterion.
Β· Feb 08, 2026
A trustworthiness layer for foundation models in power systems introduces adaptive, statistically valid confidence bounds for each output of a foundation model, allowing users to obtain uncertainty estimates and support conservative decisions. This method enhances GridFM with statistically valid prediction intervals, providing richer and more accurate information than traditional methods, while running faster. The new approach demonstrates improved precision and speed compared to DC Power Flow and AC Power Flow for N-k contingency assessment.