Abstract

Emerging large-scale silicon-carbide (SiC)-based modular power converters are pursuing high-performance distributed control systems (DCSs). In particular, fast-switching-enabled novel control schemes raise the need for minimal synchronization error (SE) of communication networks. This article presents the development of a proposed power electronics system network (PESNet) 3.0 that features a sub-nanosecond (ns) SE and gigabits-per-second data rate. The White Rabbit Network (WRN) technology, originally developed for particle accelerators, has been embedded in PESNet 3.0 and tailored to be suited for large-scale high-frequency modular power converters. A simplified node-to-node phase-locked loop (N2N-PLL) and an improved precision time protocol (PTP) model has been proposed to lock both the frequency and phase of two independent clocks on two adjacent nodes. Subsequently, the stability analysis of the N2N-PLL is carried out with its closed-loop transfer function verified by digital perturbation injection (DPI). Finally, the experimental validation of PESNet 3.0 is demonstrated at both controller and converter levels. The latter is on a first-of-it-kind 10-kV SiC-MOSFET-based modular converter prototype operating at 12-kV dc-link voltage, 10-kHz switching frequency, and above 100-V/ns slew rate, verifying +/- 0.5 ns SE at 5 Gb/s data rate.