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Spider monkey optimization (SMO) – lattice Levenberg–Marquardt recursive least squares based grid synchronization control scheme for a three-phase PV system

Dipak Kumar Dash Pradip Kumar Sadhu Bidyadhar Subudhi
Archives of Control Sciences | 2021 | vol. 31 | No 3 | 707-730 | DOI: 10.24425/acs.2021.138698
Keywords solar PV array VSC SMO DC-DC converter lattice Levenberg–Marquardt recursive least squares hysteresis current controller
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Abstract

This paper presents a new grid integration control scheme that employs spider monkey optimization technique for maximum power point tracking and Lattice Levenberg Marquardt Recursive estimation with a hysteresis current controller for controlling voltage source inverter. This control scheme is applied to a PV system integrated to a three phase grid to achieve effective grid synchronization. To verify the efficacy of the proposed control scheme, simulations were performed. From the simulation results it is observed that the proposed controller provides excellent control performance such as reducing THD of the grid current to 1.75%.
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Authors and Affiliations

Dipak Kumar Dash
1
Pradip Kumar Sadhu
1
Bidyadhar Subudhi
2
  1. Department of Electrical Engineering, Indian Institute of Technology (ISM), Dhanbad, India
  2. School of Electrical Sciences, Indian Institute of Technology Goa, GEC Campus, Farmagudi, Ponda-401403, Goa, India

A novel circuit topology of modified switched boost hybrid resonant inverter fitted induction heating equipment

Ananyo Bhattacharya Kaushik Sit Pradip Kumar Sadhu Nitai Pal
Archives of Electrical Engineering | 2016 | vol. 65 | No 4 December | 815-826 | DOI: 10.1515/aee-2016-0057
Keywords modified switched boost high frequency hybrid resonant inverter induction heating controllability VSI and PSIM
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Abstract

A novel circuit topology of modified switched boost high frequency hybrid resonant inverter fitted induction heating equipment is presented in this paper for efficient induction heating. Recently, induction heating technique is becoming very popular for both domestic and industrial purposes because of its high energy efficiency and controllability. Generally in induction heating, a high frequency alternating magnetic field is required to induce the eddy currents in the work piece. High frequency resonant inverters are incorporated in induction heating equipment which produce a high frequency alternating magnetic field surrounding the coil. Previously this high frequency alternating magnetic field was produced by voltage source inverters. But VSIs have several demerits. So, in this paper, a new scheme of modified switched boost high frequency hybrid resonant inverter fitted induction heating equipment has been depicted which enhances the energy efficiency and controllability and the same is validated by PSIM.

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Authors and Affiliations

Ananyo Bhattacharya
Kaushik Sit
Pradip Kumar Sadhu
Nitai Pal

Parameters estimation and life cycle economic analysis of a PV powered tri-cycle in India

Soumya Das Pradip Kumar Sadhu Anup Majhi Udayan Ghatak Tuhin Bandyopadhya
Archives of Electrical Engineering | 2018 | vol. 67 | No 3 | 655–665 | DOI: 10.24425/123670
Keywords PV tri-cycle LCEA fuel-based
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Abstract

This paper is devoted towards life cycle economic analysis (LCEA) of a solar photovoltaic (PV) powered tri-cycle. The paper is meant to propose a more systematic approach in determining the optimum use of scarce resources in order to determine the most cost-effective option of the solar tri-cycle. This analysis is based on the life cycle cost of this solar vehicle, involving its comparison with the customary fuel-based tri-cycle which exhibits the relatively less expenditure of the solar alternative. The economic analysis takes into account the fact that over 20 years, the overall price of solar component, replacement and electricity charges, is much lower as compared to that of a fuel-based tri-cycle in India taking into consideration the fuel cost, maintenance and annual inflation over the same period.

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Authors and Affiliations

Soumya Das
Pradip Kumar Sadhu
Anup Majhi
Udayan Ghatak
Tuhin Bandyopadhya

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