Journal of Power Electronics & Power Systems
https://engineeringjournals.stmjournals.in/index.php/JoPEPS
<p> </p><p align="center"><strong>Journal of Power Electronics & Power Systems (JoPEPS)</strong></p><p align="center"> <strong>ISSN (Online):</strong><strong> </strong>2249–863X</p><p align="center"><strong>ISSN(Print)</strong>: 2321–4244</p><p align="center"><strong> </strong></p><p align="center"><strong>(Editor-in-Chief)</strong></p><p align="center"><strong>Dr. Prof. Yog Raj Sood</strong> </p><p align="center">Department of Electrical Engineering, National Institute of Technology, Hamirpur</p><p> <strong> </strong></p><p> </p><p align="center"><strong>Click </strong><a href="/index.php/JoPEPS/about/editorialTeam"><strong>here</strong></a><strong> for complete Editorial Board</strong><strong> </strong></p><p align="center"><strong>Scientific Journal Impact Factor (SJIF): </strong>6.267<strong></strong></p><p> </p><p><strong>Journal of Power Electronics & Power Systems</strong></p><p> Journal of Power Electronics & Power Systems (JoPEPS) is focused towards the publication of research finding papers in the areas of Power Electronics & Power Systems. </p><p><strong>Journal DOI No</strong>: <strong>10.37591/JoPEPS</strong> </p><p><strong>Indexing:</strong> The Journal is indexed in <span data-sheets-value="{"1":2,"2":"Publons, Google Scholar, DRJI, Geneamics, Journals TOC, SJIF"}" data-sheets-userformat="{"2":1059709,"3":{"1":0},"5":{"1":[{"1":2,"2":0,"5":{"1":2,"2":0}},{"1":0,"2":0,"3":3},{"1":1,"2":0,"4":1}]},"6":{"1":[{"1":2,"2":0,"5":{"1":2,"2":0}},{"1":0,"2":0,"3":3},{"1":1,"2":0,"4":1}]},"7":{"1":[{"1":2,"2":0,"5":{"1":2,"2":0}},{"1":0,"2":0,"3":3},{"1":1,"2":0,"4":1}]},"8":{"1":[{"1":2,"2":0,"5":{"1":2,"2":0}},{"1":0,"2":0,"3":3},{"1":1,"2":0,"4":1}]},"9":1,"11":4,"12":0,"14":{"1":2,"2":0},"16":12,"23":1}">Publons (clarivate :Web of Science), Google Scholar, DRJI, Geneamics, Journals TOC, SJIF, Citefactor.</span></p><p><strong>Focus and Scope Covers</strong> </p><ul><li>Power Transmission, Distribution and Generation</li><li>Power Electronics and Communication</li><li>Electric Machinery and Power Engineering Systems</li><li>Energy Management Systems</li><li>Energy Systems Modeling & Simulation</li><li>Energy Development</li><li>Supervisory Control</li></ul><p> </p><p><strong>Submission of Paper:</strong></p><p>All contributions to the journal are rigorously refereed and are selected on the basis of quality and originality of the work. The journal publishes the most significant new research papers or any other original contribution in the form of reviews and reports on new concepts in all areas pertaining to its scope and research being done in the world, thus ensuring its scientific priority and significance.Manuscripts are invited from academicians, students, research scholars and faculties for publication consideration.</p><p> </p><p>Papers are accepted for editorial consideration through email <strong>electrical.excellence@conwiz.in</strong></p><p> </p><p><strong>Plagiarism</strong>: All the articles will be check through <strong>Plagiarism Software</strong> before publication. </p><p><strong>Abbreviation</strong>: (JoPEPS)</p><p><strong>Frequency</strong>: Three issues per year</p><p> </p><p><a href="http://stmjournals.com/pdf/EditorsGuidelines.pdf">Peer Reviewed Policy</a></p><p><a href="/index.php/JoPEPS/about/editorialTeam">Editorial Board</a></p><p><a href="http://stmjournals.com/pdf/Author-Guidelines-stmjournals.pdf">Instructions to Authors</a></p><p> </p><p><a title="Editorial Board" href="/index.php/JoPEPS/about/editorialTeam" target="_blank"><img src="/public/site/images/enggstm/11.jpg" alt="" /></a></p><p><strong>Publisher:</strong> STM Journals, an imprint of CELNET (Consortium e-Learning Network Pvt. Ltd.)</p><p><strong>Address:</strong> A-118, 1st Floor, Sector-63, Noida, Uttar Pradesh-201301, India</p><p><strong>Phone no.:</strong> (+91)120-4781-215 </p><p><strong>Email</strong>: tanvi.singh@conwiz.in // electrical.excellence@conwiz.in</p>en-USJournal of Power Electronics & Power Systems<p><strong>Journal Title: </strong></p><p><strong>Title of the Paper: </strong></p><p><strong>Corresponding Author’s Information: </strong></p><p><strong>Name: Address: </strong></p><p><strong>E-mail: </strong></p><p><strong>Contact Number: </strong></p><p><strong>It is herein agreed that: The copyright to the above-listed unpublished and original article is transferred to STM Journals. </strong></p><p><strong>This copyright transfer covers the exclusive right to reproduce and distribute the contribution, including reprints, translations, photographic reproductions, microform, electronic form (offline, online), or any other reproductions of similar nature. </strong></p><p><strong>I/We declare that above manuscript is not published already in part or whole (except in the form of abstract) in any journal or magazine for private or public circulation, and, is not under consideration of publication elsewhere.</strong></p><p><strong> I/ We warrant(s) that his/her/their contribution is original, except for such excerpts from copyrighted works as may be included with the permission of the copyright holder and author thereof, that it contains no libelous statements, and does not infringe on any copyright, trademark, patent, statutory right, or propriety right of others. </strong></p><p><strong>I/We will not publish his/her/their above said contribution anywhere else without the prior written permission of the publisher unless it has been changed substantially. I/We also agree to the authorship of the article in the following order: Author(s) Name Signature(s) </strong></p><p><strong>1. ________________ </strong></p><p><strong>2. ________________ </strong></p><p><strong>3. ________________ </strong></p><p><strong>4. ________________ </strong></p><p><strong>The author(s) agree to the terms of this Copyright Notice, which will apply to this submission if and when it is published by this journal (comments if any to the editor can be added below).</strong></p>A review of the intelligent techniques for load forecasting of UHBVNL
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7621
<p>The primary aim of load forecasting is to know the change in power demand with the variable factors on a short-term, medium-term, and long-term basis and to evolve our power system network according to the changing variables. It ensures correct values to the operations, stability, demand management, scheduling generating capacity, efficiency, reliability, accuracy, economy, controlling, scheduling, security analysis, environmental sustainability, etc. Various forecasting techniques are there which are making it more accurate with the advancing knowledge. This work develops a combination of medium- and long-term models for a 33KV feeder that supplies a university distribution zone and the factors affecting the medium-term load forecasting. This research paper brings the forecasting techniques and the factors that impact power consumption and their significance in medium-term load forecasting.</p>Neha KhuranaAnkush .Gopal KrishanMansi Hooda
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-03-142024-03-14133303810.37591/.v13i3.7621Modeling of Maximum Power Point Tracking Controllers for Wind Generation System using Hill Climb Searching Technique
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7721
<p>In this paper, based on a low-cost, small-scale application, presents a Maximum Power Point Tracking (MPPT) controller for wind generation systems (WGS). The Hill Climb Search approach served as the foundation for the development of the MPPT algorithm. To account for the inertia of wind turbines, an enhanced hill-climb searching approach has been created as a fundamental component of the max-power extraction algorithm. Under varying wind conditions, the generator can monitor the wind turbine system's ideal operating points with the help of the suggested control algorithm. Over time, the tracking process becomes more rapid. MATLAB/SIMULINK was used to assess this proposed algorithm&#39;s efficacy. The wind speed affects how much power a wind energy system can produce. Maintaining thewind turbines maximum power production under all wind speed circumstances is a difficult challenge because of its nonlinear feature.</p>Sanjeev Kumar KushawahaKalpana Meena
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-03-142024-03-14133394710.37591/.v13i3.7721A Study of a Non-Isolated DC-DC Converter Based on High Voltage Gain
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7601
<p>This article implements a best non-isolated DC-DC<br />Converter for solar photovoltaic system-driven DC MicroGrid<br />applications through high voltage gain methodology. At first, a<br />hybrid boosting converter with bipolar voltage multiplier method is<br />proposed and studied for photovoltaic-based DC MicroGrids. But<br />the cost and functionality of this converter are a big problem. To<br />eradicate these problems with a proposed modified SEPIC<br />converter and this converter is studied for producing high voltage<br />gain. Formerly performance of hybrid boosting converter and<br />modified SEPIC converter are simulated in PSIM software. As a<br />final point, the simulation results are compared and verified that<br />the modified SEPIC converter suits best for solar photovoltaic<br />system-based DC Microgrids to provide essential power levels to<br />the residential electrical loads.</p>G. JayalaxmiR. V. S. L. Kumari
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-01-302024-01-30133172910.37591/.v13i3.7601Study and Review of High Gain DC-DC Converters for Renewable Power Applications
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7600
<h1><em>This paper offers a thorough investigation of non-isolated high gain DC-DC converters, specifically designed for their applicability in renewable power systems. These converters demonstrate versatility and efficacy in various domains, including renewable energy applications, DC microgrids, and electric vehicle power management. This study explores their characteristics and advantages in depth, shedding light on their potential for addressing the evolving demands of modern energy systems. Renewable energy systems, such as solar photovoltaic (PV) systems, often produce low-magnitude DC voltage outputs. Consequently, the design and exploration of various high-gain DC-DC converter topologies have become a significant focus in contemporary research. This paper is dedicated to a comprehensive study and review of these converters, with the goal of identifying and selecting an optimal converter for diverse practical applications.</em><em></em></h1>Yenni RamuDevendra PotnuruKishore Babu Y. S.
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-01-302024-01-3013318Evolution of Protection Coordination Methods in Power Distribution Systems: A review
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7611
<p><em>This comprehensive paper presents a broad-ranging exploration of the multifaceted challenges inherent in coordinating over-current relays within distributed generation (DG) systems in the context of power grids. Within these systems, the pivotal roles of both protective devices and the overarching protection system are highlighted, emphasizing their joint responsibility in detecting short-circuit currents and swiftly isolating faulty components. The primary objective of this protection coordination is to ensure the meticulous selection and application of devices to contain and effectively resolve any potential faults that may arise. In the contemporary landscape of highly interconnected electricity systems, encountering abnormal operating conditions is a common occurrence. This reality has led to the development of a myriad of protection techniques meticulously designed to address the diverse and constantly evolving challenges faced in safeguarding these intricate systems. The research in question presents an in-depth examination of a wide spectrum of protection plans and coordination strategies. These strategies likely encompass a diverse array of methodologies, including fault location techniques, adaptive relaying schemes, communication-based protections, and potentially innovative approaches integrating artificial intelligence. The exhaustive analysis undertaken in this research serves to illuminate the intricate complexities involved in protecting distributed generation systems embedded within larger power networks. By critically reviewing and evaluating numerous protections plans and coordination strategies, this paper aims to significantly contribute to advancing our understanding of effectively managing and securing these intricate systems.</em></p>Arathi P. B.Nandini S. PatilSujatha D.
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-01-292024-01-29133916Modeling and Simulation of a Hybrid Solar-Wind System with Adaptive Neural Network MPPT Control in MATLAB/SIMULINK
https://engineeringjournals.stmjournals.in/index.php/JoPEPS/article/view/7586
<p>Over the last ten years, there has been an increasing demand for the electrical power<br />supply. The installation of power generators (PGs) is expensive and time-consuming. Solar power<br />plants are therefore thought to be a practical substitute for supplying the present demand for<br />electricity. The primary challenges with solar plants, however, are output power balancing and<br />critical maintenance. A proper technique is needed to lessen output power balance and<br />maintenance issues in solar facilities. For hybrid photovoltaic (PV) and wind energy systems<br />(WES), this research suggests a novel single maximum power point tracking (MPPT) technique to<br />track maximum power. An artificial neural network (ANN) serves as the foundation for the<br />recommended MPPT method. A source inverter and a separate converter are used to link the<br />hybrid PV and WES systems to the grid.</p>Devendra Kumar VermaVarun KumarY. K. Chauhan
Copyright (c) 2024 Journal of Power Electronics & Power Systems
2024-01-162024-01-16133536110.37591/.v13i2.7586