Frequency-domain analytical model for a cascaded multilevel STATCOM

Dragan Jovcic; Ronny Sternberger

doi:10.1109/TPWRD.2008.921122

Frequency-domain analytical model for a cascaded multilevel STATCOM

Dragan Jovcic, Ronny Sternberger

Engineering

Research output: Contribution to journal › Article › peer-review

11 Citations (Scopus)

Abstract

This paper develops a frequency-dependent analytical representation for a multilevel cascaded converter, with fundamental frequency switching. The gain and phase angle are studied with the firing angle as a parameter, where the converter is subjected to oscillatory excitation at a range of frequencies. This paper presents analytical formulae for a single cell and for a generic cascade multilevel converter where the number of cells is a parameter. Also, the formula for fundamental frequency studies is separately developed. The equivalent capacitance concept is introduced and its convergence to a constant value for high frequencies is demonstrated. The analytical formulae are tested against detailed digital simulation and good matching is reported. The formulae developed in this study will be of particular importance in studying interactions between a multilevel STATCOM and the host ac grid (similar to harmonic resonance) and in studying converter transient responses.

Original language	English
Pages (from-to)	2139-2147
Number of pages	9
Journal	IEEE Transactions on Power Delivery
Volume	23
Issue number	4
DOIs	https://doi.org/10.1109/TPWRD.2008.921122
Publication status	Published - Oct 2008

Keywords

frequency response
multilevel converter
static VAR compensators
cascade networks
switching converters
transient response

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10.1109/TPWRD.2008.921122

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title = "Frequency-domain analytical model for a cascaded multilevel STATCOM",

abstract = "This paper develops a frequency-dependent analytical representation for a multilevel cascaded converter, with fundamental frequency switching. The gain and phase angle are studied with the firing angle as a parameter, where the converter is subjected to oscillatory excitation at a range of frequencies. This paper presents analytical formulae for a single cell and for a generic cascade multilevel converter where the number of cells is a parameter. Also, the formula for fundamental frequency studies is separately developed. The equivalent capacitance concept is introduced and its convergence to a constant value for high frequencies is demonstrated. The analytical formulae are tested against detailed digital simulation and good matching is reported. The formulae developed in this study will be of particular importance in studying interactions between a multilevel STATCOM and the host ac grid (similar to harmonic resonance) and in studying converter transient responses.",

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T1 - Frequency-domain analytical model for a cascaded multilevel STATCOM

AU - Jovcic, Dragan

AU - Sternberger, Ronny

PY - 2008/10

Y1 - 2008/10

N2 - This paper develops a frequency-dependent analytical representation for a multilevel cascaded converter, with fundamental frequency switching. The gain and phase angle are studied with the firing angle as a parameter, where the converter is subjected to oscillatory excitation at a range of frequencies. This paper presents analytical formulae for a single cell and for a generic cascade multilevel converter where the number of cells is a parameter. Also, the formula for fundamental frequency studies is separately developed. The equivalent capacitance concept is introduced and its convergence to a constant value for high frequencies is demonstrated. The analytical formulae are tested against detailed digital simulation and good matching is reported. The formulae developed in this study will be of particular importance in studying interactions between a multilevel STATCOM and the host ac grid (similar to harmonic resonance) and in studying converter transient responses.

AB - This paper develops a frequency-dependent analytical representation for a multilevel cascaded converter, with fundamental frequency switching. The gain and phase angle are studied with the firing angle as a parameter, where the converter is subjected to oscillatory excitation at a range of frequencies. This paper presents analytical formulae for a single cell and for a generic cascade multilevel converter where the number of cells is a parameter. Also, the formula for fundamental frequency studies is separately developed. The equivalent capacitance concept is introduced and its convergence to a constant value for high frequencies is demonstrated. The analytical formulae are tested against detailed digital simulation and good matching is reported. The formulae developed in this study will be of particular importance in studying interactions between a multilevel STATCOM and the host ac grid (similar to harmonic resonance) and in studying converter transient responses.

KW - frequency response

KW - multilevel converter

KW - static VAR compensators

KW - cascade networks

KW - switching converters

KW - transient response

U2 - 10.1109/TPWRD.2008.921122

DO - 10.1109/TPWRD.2008.921122

M3 - Article

SN - 0885-8977

VL - 23

SP - 2139

EP - 2147

JO - IEEE Transactions on Power Delivery

JF - IEEE Transactions on Power Delivery

IS - 4

ER -

Frequency-domain analytical model for a cascaded multilevel STATCOM

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Keywords

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