Abstract
This paper presents a self-tuning filter (STF)-based adaptive linear neuron (ADALINE) reference current generation algorithm to enhance the operation of a three-phase three-level neutral-point diode clamped (NPC) inverter-based shunt active power filter (SAPF) under non-ideal (unbalanced and/or distorted) source voltage conditions. SAPF is an effective and versatile mitigation tool for current harmonics. As for its controller, ADALINE-based reference current generation algorithmd have widely been applied and proven to work effectively under balanced and purely sinusoidal source voltage conditions. However, no work has been conducted to study its performance under non-ideal source voltage conditions. In this work, a STF-based fundamental voltage extraction algorithm is integrated with an ADALINE algorithm, serving as synchronizer algorithm to ensure in-phase operation of the generated reference current with the non-ideal source voltage. Hence, it completely eliminates any dependency on conventional synchronizer algorithms such as phase-locked loop (PLL) and zero-crossing detector (ZCD). Additionally, the proposed STF-based ADALINE algorithm implements the modified Widrow-Hoff (W-H) weight updating algorithm for fast generation of reference current. Both simulation and experimental works are performed to verify design concept and effectiveness of the proposed algorithm. Comparative study with another recently reported algorithm is performed to investigate the performance improvement achieved by SAPF while using the proposed algorithm.
Highlights
In power distribution system, harmonic currents generated by extensive usage of nonlinear loads are a major power quality problem which has attracted tremendous research interests
A new self-tuning filter (STF)-based fundamental voltage extraction algorithm which operates as a synchronizer is formulated to ensure fundamental voltage extraction algorithm which operates as a synchronizer is formulated to ensure in-phase operation of shunt-typed active power filter (SAPF) with the operating power system, by coordinating phases of the in-phase operation of SAPF with the operating power system, by coordinating phases of the generated generated reference current with respect to angular position of the operating power system
Comprehensive analyses under various source voltage conditions (balanced, unbalanced and analyses under various source voltage conditions are performed distorted) are performed to evaluate performance of the newly proposed algorithm in comparison to evaluate performance of the newly proposed algorithm in comparison with the recent unified with the recent unified adaptive linear neuron (ADALINE) algorithm
Summary
Harmonic currents generated by extensive usage of nonlinear loads are a major power quality problem which has attracted tremendous research interests. Under balanced-sinusoidal source voltage conditions, the modified W-H ADALINE-based algorithm has widely been applied in SAPF applications and it is proven (both by simulation and experimentally) to be effective in generating reference currents. The design of reference current generation algorithm must take into account various non-ideal conditions of the source voltages, to further enhance effectiveness and flexibility of SAPF in current harmonics mitigation. A simple yet effective STF-based fundamental voltage extraction algorithm is implemented, serving as a synchronizer algorithm to ensure in-phase operation of the generated reference current with the source voltage. By using the STF-based fundamental voltage extraction algorithm, the dependency on conventional synchronizer algorithms is eliminated and at the same time, the SAPF gains the ability to work effectively under unbalanced and distorted source voltage conditions. By referring to the unified ADALINE algorithm, the STF-based ADALINE algorithm is elaborated, highlighting the improvements made
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