Design and implementation of a cascaded transformer coupled multilevel inverter-based shunt active filter under different grid voltage conditions

Self Cite

Summary This paper describes an empirical mode decomposition control algorithm to extract the fundamental component and set the reference for harmonic extraction in a cascaded multilevel inverter–based shunt active filter. The proposed technique is fully reliant on the data samples that are decomposed instantaneously and does not require any weighing factor. The fundamental component of load current is found by applying a novel empirical mode decomposition algorithm from the nonlinear load current samples. Spline interpolation is used to extract the intrinsic mode function. For online implementation, the maxima and minima points of load current are stored using a modified field programming gate array (FPGA)‐based circular buffer circuit. Finally, the proposed cascaded multilevel inverter–based shunt active filter is investigated both by simulation and hardware implementation. The results obtained validates the performance of the proposed control technique under balanced and unbalanced loading conditions.

Section: Cascaded Mli–based Shunt Active Filter Structurementioning

confidence: 99%

Implementation of EMD‐based control algorithm for a cascaded multilevel inverter–based shunt active filter

Dash

Panda

Lenka

2019

Self Cite

“…Also, finding their appropriate use in renewable energy systems, which include smart and micro‐grids. There is always a scope of improvement of efficiency and reduction in the harmonic distortion has always become a concern for the researchers …”

Section: Introductionmentioning

confidence: 99%

Design and implementation of a novel asymmetrical multilevel inverter optimal hardware components

Dhanamjayulu

Arunkumar

Pandian

et al. 2019

Summary The paper developed a new topology for the single‐phase asymmetrical cascaded multilevel inverter and realized with optimal hardware components. This solution aids to substantially reducing the number of semiconductor switches and DC sources, henceforth reduces the gate drivers requirement. The proposed multilevel inverter creates a waveform with a high number of staircase voltage levels compromising with low total harmonic distortion at the outputs. The configuration is asymmetric and generates thirty‐one level different output voltages. MATLAB/Simulink numerical software used to verify the modeling and validated experimentally in laboratory scale prototype. The testing of the inverter executed under both steady state and dynamic load changing conditions. A set of numerical and experimental results are provided and shown clear evidence of satisfying the expectation with theoretical development. The proposed converter is well suitable for renewable energy applications. KEYWORDS asymmetrical invertermultilevel inverterrenewable energystaircase modulation techniquetotal harmonic distortionvoltage source inverter.

“…Multilevel inverter topologies play an important role for medium‐voltage, medium‐, and high‐power level power system applications, such as static compensators (STATCOM), active shunt filter, and renewable energy integration to grid . It has some promising features such as lower harmonic distortion, lesser dv/dt voltage stresses on power semiconductor devices, requires lower voltage rating devices, high power handling capability, lower switching losses, higher conversion efficiency, producing smaller common mode voltage, and lesser electromagnetic interference (EMI) .…”

Section: Introductionmentioning

confidence: 99%

An improved SHM‐PWM scheme for three‐phase seven‐level CHB inverter to improve power quality by fulfilling CIGRE WG 36‐05 and EN 50160 and sharing equal power between the H‐bridge cells

Kundu

Banerjee

2019

Summary This paper presents an improved selective harmonic minimization (SHM)‐pulse width modulation (PWM) scheme using three‐phase seven‐level cascaded H‐bridge (CHB) inverter suitable for medium‐voltage distribution systems by achieving high‐quality voltage waveform with least number of switching instances (ie, each power semiconductor devices switched once in a quarter period). Here, each isolated DC voltage sources have been taken as variable and unequal for the CHB inverter. The efficacy of the proposed SHM‐PWM scheme over selective harmonic elimination (SHE)‐PWM scheme and existing SHM‐PWM scheme has been verified through a comparative inverter performance analysis with equal number of switching instances. Both simulation and experimental results prove that the proposed SHM‐PWM scheme ensures equal percentage of power‐sharing between the H‐bridge cells, achieves desired fundamental voltage component, minimizes each individual odd nontriplen harmonics, and limits %total harmonic distortion (THD) up to 25th‐order harmonics such that, it satisfies the power quality standards CIGRE WG 36‐05 and EN 50160 for the entire modulation index range. It is also seen that the proposed scheme requires least no of switching (three) than other reported SHE‐/SHM‐PWM schemes to meet the aforesaid power quality standards. It also results lower inverter losses and improves efficiency compared with conventional schemes. Finally, the scheme is applied to a closed‐loop control of induction motor driven by back‐to‐back PWM‐controlled converter.