Cell-based VSC Analysis Methodology: From Graph Laplacian to Converter Degrees of Freedom

TL;DR

This paper introduces a novel graph Laplacian spectral analysis methodology to determine the degrees of freedom in various cell-based VSC converter topologies, enhancing understanding of their operational and control characteristics.

Contribution

It presents a general approach to analyze converter arrangements using graph theory, extending the Clarke transformation concept to complex bi-partite and multi-partite graph-based topologies.

Findings

The methodology effectively characterizes converter DOFs using spectral graph analysis.

It provides a unified framework for different VSC topologies.

Power pattern formulations based on DOFs are introduced for complete system analysis.

Abstract

Power-electronics-based converters are being considerably employed through the power system to interconnect multiple heterogeneous electrical layers. Furthermore, the intrinsic versatility to play with the converter network topology is widely exploited to accommodate a certain number of terminals and ports according with the specific application. On this regard, several converter arrangements can be encountered in power applications. Moreover, to properly establish both the operation and the control, the so-called degrees of freedom (DOFs) need to be assessed per each converter topology. On this matter, similarly to the well-known Clarke transformation, which clearly reveals the DOFs for the star-based topology system, further similar transformations can be achieved to depict the independent set of variables characterizing a certain converter structure. Referring to the cell-based class of Voltage Source Converter (VSC) topologies, including Modular Multilevel Converter (MMC); this article proposes a general methodology to determine the change of variable matrix transformation for several converter arrangements which are related to complete bi-partite and multi-partite graphs. The methodology lies in the graph Laplacian spectral analysis, which remarks the structural normal modes at the converter points of connections. Furthermore, for a complete characterization, the instantaneous power patterns formulations, based on the DOFs, are also introduced.