Litcius/Paper detail

Dissipativity-Based Multiport Stability Root-Cause Identification and Mitigation for Solid-State Transformers

Xiangyu Meng, Dong Xie, Hongjian Lin, Chunxu Lin, Xinglai Ge, Zhigang Liu

2026IEEE Transactions on Industrial Electronics10 citationsDOI

Abstract

For solid-state transformers (SSTs) in high-power grid-connected applications, improperly designed control loops can excite strong inherent AC-DC port coupling, leading to low-frequency oscillation issues, especially under weak grid conditions. To address this problem, this article establishes a multiport admittance matrix for the SST, encompassing its AC <inline-formula xmlns:mml="http://www.w3.org/1998/Math/MathML" xmlns:xlink="http://www.w3.org/1999/xlink"> <tex-math notation="LaTeX">$\boldsymbol{dq}$</tex-math> </inline-formula> axes and primary DC port, to characterize its inherent dynamics. Subsequently, a multiport dissipativity analysis is conducted to evaluate the robust stability of SST. By leveraging the decomposition of passivity conditions into distinct self- and coupling-dissipativity indices, the specific root causes of instability are diagnosed. This framework reveals that a severe coupling-dissipativity failure, induced by the internal dynamics of the synchronization loop, is the dominant instability mechanism rather than a localized self-dissipativity issue. Guided by this diagnosis, a stabilizing controller featuring dynamics-free orthogonal signal reconstruction is designed to reshape the admittance characteristics of the SST. This enhancement specifically targets the identified coupling-dissipativity deficiencies, thereby resolving the root cause of the instability. Finally, the stability analysis and the effectiveness of the enhancement strategy are validated on a down-scaled SST prototype. Experimental results demonstrate that the criterion accurately predicts the coupling-induced oscillations and that the enhanced controller guarantees stable operation under challenging weak-grid conditions.

Topics & Concepts

Control theory (sociology)Admittance parametersAdmittancePassivityTransformerController (irrigation)GridComputer scienceInstabilityStability (learning theory)Root causeEngineeringSynchronization (alternating current)Control engineeringPhasorPole–zero plotIdentification (biology)Oscillation (cell signaling)Electrical impedanceSIGNAL (programming language)Matrix (chemical analysis)ImmittanceControl systemElectronic engineeringFerroresonance in electricity networksVoltageRobust controlFrequency responseMicrogrid Control and OptimizationMagneto-Optical Properties and ApplicationsPower Transformer Diagnostics and Insulation