Distributed Energy Resources and Electric Vehicle
Analysis and Optimisation of Network Operations
Herausgeber: Ahmad, Aijaz; Rawal, Keerti; Jagtap, Kushal
Distributed Energy Resources and Electric Vehicle
Analysis and Optimisation of Network Operations
Herausgeber: Ahmad, Aijaz; Rawal, Keerti; Jagtap, Kushal
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Explore the prospective developments in energy systems and transportation through an in-depth examination of "Distributed Energy Resources and Electric Vehicles: Analysis and Optimisation of Network Operations."
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Explore the prospective developments in energy systems and transportation through an in-depth examination of "Distributed Energy Resources and Electric Vehicles: Analysis and Optimisation of Network Operations."
Produktdetails
- Produktdetails
- Verlag: CRC Press
- Seitenzahl: 264
- Erscheinungstermin: 29. Februar 2024
- Englisch
- Abmessung: 234mm x 156mm x 18mm
- Gewicht: 576g
- ISBN-13: 9781032318721
- ISBN-10: 1032318724
- Artikelnr.: 69432837
- Verlag: CRC Press
- Seitenzahl: 264
- Erscheinungstermin: 29. Februar 2024
- Englisch
- Abmessung: 234mm x 156mm x 18mm
- Gewicht: 576g
- ISBN-13: 9781032318721
- ISBN-10: 1032318724
- Artikelnr.: 69432837
Aijaz Ahmad received his B.E. (Electrical Engg.) degree from National Institute of Technology (NIT), Srinagar, India in 1984, M.Tech. and Ph.D. from Indian Institute of Technology, New Delhi, India in 1991 and 1998 respectively. He was a Lecturer and later Assistant Professor in the Electrical Engineering Department, NIT, Srinagar. Since 2006 he has been working there as a Professor. In between he remained Head of the Department from 2012-2015. His main research interests are Power System Operation & Optimization, Power System Restructuring and Deregulation, Flexible AC Transmission, Energy System Planning & Auditing. Aijaz Ahmad is a Member IEEE, Fellow of Institution of Engineers (India), Life Member of Indian Society for Technical Education and Member Global Science and Technology Forum. Kushal Jagtap received his B.E. (Electrical Electronics and Power Engg.) degree from the Government College of Engineering Aurangabad, Maharashtra, India in 2007 and, M.Tech. (Power System) and Ph.D. from Indian Institute of Technology Roorkee, India in 2012 and 2018, respectively. His PhD thesis title was "Loss Allocation in a Radial Distribution System with Distributed Generation." He joined as a PostDoc fellow under the project title "Impact of Electric Vehicles on Demand Side Management" at the Indian Institute of Technology Madras, India in 2018. He is presently working as an Assistant Professor in the Electrical Engineering Department, NIT Srinagar since 2018. His main research interests and major topics taught during the last three years are Loss Allocation, Distributed Generation, Power System Operation & Optimization, Power System Restructuring and Deregulation, and Flexible AC Transmission. Kushal Jagtap has been a Member IEEE for the last three years. Keerti Rawal received her B.Tech (Electrical Engineering) from National Institute of Technology Jaipur, Rajasthan, India in 2013 and M.E. (Electrical Engineering) from Indian Institute of Science Bangalore in 2015. Keerti Rawal is currently pursuing PhD in Department of Electrical Engineering NIT Srinagar. She is exploring the impacts of integration of renewable energy resources and storage on the electrical grid, primarily focussing on electricity markets and energy analytics in her doctoral research. Her key interests are energy market, power system optimization, energy analytics, distributed optimization, energy forecasting, electric vehicles, control strategies, spinning reserves, and energy storage technologies. She has been a student member of IEEE for 4 years.
1. Comprehensive Review of Grid Operation with Distributed Resources and
Charging Stations for Electric Vehicles. 2. A Comprehensive Study of Life
Cycle Assessments of Electric Vehicles and IC Engine Vehicles. 3. Electric
Vehicle Charging Infrastructure: Optimal Location Problem Modeling Options
and Solution Techniques. 4. Comprehensive Study on Electric Vehicles:
Integration with Renewable Energy, Charging Infrastructure, Model
Variations, Regulatory Frameworks, and Assessing Operational Efficiency of
Hybrid Electric Vehicles. 5. Wireless Chargers for Electric Vehicles. 6.
Review of Control Strategy with Different Loading Conditions Considering
Demand Side Management. 7. Coordinated Operation of Electric Vehicle
Charging Stations (EVCS) and Distributed Power Generation in Grids Using AI
Technology. 8. Model Predictive Control of Grid-Connected Wind Energy
Conversion System Using VSC-Based Shunt Controllers. 9. Model Predictive
Control of Multiple Renewable Energy Sources in Hybrid DC Microgrids for
Power Flow Control. 10. Analysis of an IUPQC Device Using Conventional PID
and FOPID Controllers in a Wind Energy Conversion System. 11.
Photovoltaic-Based Battery-Integrated E-Rickshaw with Regenerative Braking
Using Real-Time Implementation. 12. Allocation of Distribution System
Losses Considering the Effects of Load Power Factor and Distributed
Generation.
Charging Stations for Electric Vehicles. 2. A Comprehensive Study of Life
Cycle Assessments of Electric Vehicles and IC Engine Vehicles. 3. Electric
Vehicle Charging Infrastructure: Optimal Location Problem Modeling Options
and Solution Techniques. 4. Comprehensive Study on Electric Vehicles:
Integration with Renewable Energy, Charging Infrastructure, Model
Variations, Regulatory Frameworks, and Assessing Operational Efficiency of
Hybrid Electric Vehicles. 5. Wireless Chargers for Electric Vehicles. 6.
Review of Control Strategy with Different Loading Conditions Considering
Demand Side Management. 7. Coordinated Operation of Electric Vehicle
Charging Stations (EVCS) and Distributed Power Generation in Grids Using AI
Technology. 8. Model Predictive Control of Grid-Connected Wind Energy
Conversion System Using VSC-Based Shunt Controllers. 9. Model Predictive
Control of Multiple Renewable Energy Sources in Hybrid DC Microgrids for
Power Flow Control. 10. Analysis of an IUPQC Device Using Conventional PID
and FOPID Controllers in a Wind Energy Conversion System. 11.
Photovoltaic-Based Battery-Integrated E-Rickshaw with Regenerative Braking
Using Real-Time Implementation. 12. Allocation of Distribution System
Losses Considering the Effects of Load Power Factor and Distributed
Generation.
1. Comprehensive Review of Grid Operation with Distributed Resources and
Charging Stations for Electric Vehicles. 2. A Comprehensive Study of Life
Cycle Assessments of Electric Vehicles and IC Engine Vehicles. 3. Electric
Vehicle Charging Infrastructure: Optimal Location Problem Modeling Options
and Solution Techniques. 4. Comprehensive Study on Electric Vehicles:
Integration with Renewable Energy, Charging Infrastructure, Model
Variations, Regulatory Frameworks, and Assessing Operational Efficiency of
Hybrid Electric Vehicles. 5. Wireless Chargers for Electric Vehicles. 6.
Review of Control Strategy with Different Loading Conditions Considering
Demand Side Management. 7. Coordinated Operation of Electric Vehicle
Charging Stations (EVCS) and Distributed Power Generation in Grids Using AI
Technology. 8. Model Predictive Control of Grid-Connected Wind Energy
Conversion System Using VSC-Based Shunt Controllers. 9. Model Predictive
Control of Multiple Renewable Energy Sources in Hybrid DC Microgrids for
Power Flow Control. 10. Analysis of an IUPQC Device Using Conventional PID
and FOPID Controllers in a Wind Energy Conversion System. 11.
Photovoltaic-Based Battery-Integrated E-Rickshaw with Regenerative Braking
Using Real-Time Implementation. 12. Allocation of Distribution System
Losses Considering the Effects of Load Power Factor and Distributed
Generation.
Charging Stations for Electric Vehicles. 2. A Comprehensive Study of Life
Cycle Assessments of Electric Vehicles and IC Engine Vehicles. 3. Electric
Vehicle Charging Infrastructure: Optimal Location Problem Modeling Options
and Solution Techniques. 4. Comprehensive Study on Electric Vehicles:
Integration with Renewable Energy, Charging Infrastructure, Model
Variations, Regulatory Frameworks, and Assessing Operational Efficiency of
Hybrid Electric Vehicles. 5. Wireless Chargers for Electric Vehicles. 6.
Review of Control Strategy with Different Loading Conditions Considering
Demand Side Management. 7. Coordinated Operation of Electric Vehicle
Charging Stations (EVCS) and Distributed Power Generation in Grids Using AI
Technology. 8. Model Predictive Control of Grid-Connected Wind Energy
Conversion System Using VSC-Based Shunt Controllers. 9. Model Predictive
Control of Multiple Renewable Energy Sources in Hybrid DC Microgrids for
Power Flow Control. 10. Analysis of an IUPQC Device Using Conventional PID
and FOPID Controllers in a Wind Energy Conversion System. 11.
Photovoltaic-Based Battery-Integrated E-Rickshaw with Regenerative Braking
Using Real-Time Implementation. 12. Allocation of Distribution System
Losses Considering the Effects of Load Power Factor and Distributed
Generation.