K. Dhineshkumar scite author profile

K. Dhineshkumar

5Publications

22Citation Statements Received

18Citation Statements Given

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Performance analysis of PV powered multilevel inverter

Dhineshkumar¹,

Subramani²,

Geetha³

et al. 2019

IJECE

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<p>This article deals with the PV based DC/DC boost chopper integrated nine level inverter. This topology requires 7 switches in minimum to obtain a nine level stepped wave output. So the main objective of this paper is to develop a 9 level AC output using PV based DC/DC boost chopper. In the case of conventional multi-level inverter, 16 switches were utilized and the number of sources needed was also more. Here the proposed system comprises of single PV panel and the switches used are also less. Also PV is integrated with DC/DC boost chopper is used to increase the source input level of the inverter. Using MATLAB platform, the proposed system is simulated with a resistive and inductive load. The similar results are obtained in prototype which validates the designed converter.</p>

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Kalman Filter Algorithm for Mitigation of Power System Harmonics

Dhineshkumar¹,

Subramani²

2018

IJECE

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<p>The maiden application of a variant of Kalman Filter (KF) algorithms known as Local Ensemble Transform Kalman Filter (LET-KF) are used for mitigation and estimation power system harmonics are proposed in this paper. The proposed algorithm is applied for estimating the harmonic parameters of power signal containing harmonics, sub-harmonics and inter-harmonics in presence of random noise. The KF group of algorithms are tested and applied for both stationary as well as dynamic signal containing harmonics. The proposed LET-KF algorithm is compared with conventional KF based algorithms like KF, Ensemble Kalman Filter (En-KF) algorithms for harmonic estimation with the random noise values 0.001, 0.05 and 0.1. Among these three noises, 0.01 random noise results will give better than other two noises. Because the phase deviation and amplitude deviation less in 0.01 random noise. The proposed algorithm gives the better results to improve the efficiency and accuracy in terms of simplicity and computational features. Hence there are less multiplicative operations, which reduce the rounding errors. It is also less expensive as it reduces the requirement of storing large matrices, such as the Kalman gain matrix used in other KF based methods.</p>

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Design and Implementation of 13 Levels Multilevel Inverter for Photovoltaic System

Subramani

Dhineshkumar²,

Palanivel

2018

J. Phys.: Conf. Ser.

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Analysis of Extended Z-source Inverter for Photovoltaic System

Prakash

Subramani

Dhineshkumar³

et al. 2018

J. Phys.: Conf. Ser.

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Design and Implementation of nine level multilevel Inverter

Dhineshkumar¹,

Subramani

2018

J. Phys.: Conf. Ser.

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K. Dhineshkumar

Performance analysis of PV powered multilevel inverter

Kalman Filter Algorithm for Mitigation of Power System Harmonics

Design and Implementation of 13 Levels Multilevel Inverter for Photovoltaic System

Analysis of Extended Z-source Inverter for Photovoltaic System

Design and Implementation of nine level multilevel Inverter

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