System Synchronization Based on Complex Frequency

In response to the inertia decline caused by high penetration of renewable generation, traditional synchronization criteria that rely solely on frequency consistency are increasingly inadequate for characterizing the coupled behavior of frequency and voltage dynamics during power-system transients. This paper focuses on the theory of complex-frequency synchronization and develops a theory-simulation analysis framework that offers a new perspective for steady-state and transient analysis of low-inertia power systems. First, the fundamental concepts and theoretical foundations of complex-frequency synchronization are presented in detail. Second, local and global dynamic synchronization criteria are derived and the concept of generalized inertia is introduced, which unifies the conventional inertial support to frequency with the inertia-like support of voltage, thereby providing an accurate measure of region-level coupled support strength for voltage and frequency. Finally, numerical case studies on the IEEE 9-bus system validate the effectiveness of the proposed theoretical methods and criteria, and demonstrate a visualization workflow for key indicators such as disturbance impact zones and generalized-inertia regions.