High-impact and low-probability (HILP) events can cause severe damage to power systems.
Networked microgrids (MGs) with distributed generation resources provide a viable solution …

High-impact and low-probability (HILP) extreme events can cause severe damage to power
systems. Microgrids (MGs) with distributed generation resources provide a viable solution for …

High-impact and low-probability extreme events can cause severe damage to power
systems, especially for distribution systems. Microgrids (MGs) with distributed generation …

Increasing the frequency of natural hazards affecting critical infrastructures such as power
systems has necessitated upgrading planning and operation strategies to cope with such an …

In response to extreme events, substantial research efforts have focused on developing load
restoration strategies for networked microgrids (MGs). However, existing distributed control …

Power system resilience is defined as the ability of power grids to anticipate, withstand,
adapt and recover from high-impact low-probability (HILP) events. There are both long-term …

In this paper, the impact of uncertainties in loads, renewable generation, market price
signals, and event occurrence time on the feasible islanding and survivability of microgrids …

With the increased frequency of adverse weather and manmade events in recent years, the
issue of the power distribution system (PDS) resiliency has become drastically important …

Micro-grids provide opportunities to enhance reliability and flexibility in power systems. In
recent years, resiliency of power grids has attracted many research interests. Moreover, the …

Microgrids have emerged as a practical solution to improve the power system resilience
against unpredicted failures and power outages. Microgrids offer substantial benefits for …