Particle swarm optimisation-based modified SHE method for cascaded H-bridge multilevel inverters

Low-frequency switching strategies are considered as an effective way of achieving efficient performance in multilevel inverters. Selective harmonic elimination (SHE) is a modulation technique of this category which gives a superior outcome suppressing low-order detrimental harmonics. Limited number...

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Vydáno v:	IET power electronics Ročník 10; číslo 1; s. 18 - 28
Hlavní autoři:	Etesami, Mohammadhossein, Ghasemi, Negareh, Vilathgamuwa, Don Mahinda, Malan, Wynand Louis
Médium:	Journal Article
Jazyk:	angličtina
Vydáno:	The Institution of Engineering and Technology 20.01.2017
Témata:	bridge circuits cascade networks cascaded H‐bridge multilevel inverters Electric potential Electronics floating voltage levels Harmonics harmonics suppression Inverters invertors low‐frequency switching strategies low‐order detrimental harmonics Mathematical analysis modulation technique Multilevel nonlinear equations particle swarm optimisation power conversion harmonics selective harmonic elimination SHE method switching convertors Voltage voltage quality Waveforms voltage quality cascade networks low-frequency switching strategies particle swarm optimisation bridge circuits modulation technique power conversion harmonics floating voltage levels low-order detrimental harmonics switching convertors nonlinear equations invertors selective harmonic elimination SHE method harmonics suppression cascaded H-bridge multilevel inverters
ISSN:	1755-4535, 1755-4543
On-line přístup:	Získat plný text
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Popis
Shrnutí:	Low-frequency switching strategies are considered as an effective way of achieving efficient performance in multilevel inverters. Selective harmonic elimination (SHE) is a modulation technique of this category which gives a superior outcome suppressing low-order detrimental harmonics. Limited number of decision variables offered by SHE in the corresponding non-linear equations hinders obtaining high-quality waveforms. Current research is targeted on two distinct objectives for cascaded H-bridge inverters. First objective is to obtain a high-quality output signal. The second one is accomplishing a realistic solution with compromised voltage quality where a broad operating range becomes mathematically challenging. These aims are achievable by deploying additional degree of freedom in the equation set. In other words, the introduction of floating voltage levels contributes to effectively doubling the number of variables. The enhancement of output waveforms is presented through several illustrations and comparisons. Subsequent laboratory implementation validates the proposal and confirms its feasibility.
Bibliografie:	ObjectType-Article-1 SourceType-Scholarly Journals-1 ObjectType-Feature-2 content type line 23
ISSN:	1755-4535 1755-4543
DOI:	10.1049/iet-pel.2015.0864