The recent advancements in grid-forming technology for renewable power grids have seen significant innovations, particularly in the areas of fault ride-through techniques and dynamic control strategies for inverters. Researchers are focusing on enhancing the robustness and stability of virtual oscillator-based controllers, addressing the limitations of traditional droop-based methods. Novel fault ride-through architectures are being developed to ensure synchronization and minimize power oscillations during faults, which are critical for maintaining grid integrity. Additionally, the integration of dynamic virtual inertia and damping controls is being explored to improve the resilience of zero-inertia grids against various fault conditions. These developments are paving the way for more reliable and efficient grid-forming solutions, essential for the transition to a fully renewable power grid. Notably, advancements in accurately calculating switching events in electromagnetic transient simulations are also contributing to more precise and reliable modeling of grid dynamics.