ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ACADEMIC MATLAB SIMULATION 2013/14/15 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers With Extension also…
We also write papers for your projects and give guidance for paper publishing.
For Further Details Call Us @
0-9347143789/9949240245
Visit us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries
mail to: asokatechnologies@gmail.com
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
latest 2014-15 ieee projects for eee, power electronics and power systemsAsoka Technologies
ACADEMIC MATLAB SIMULATION 2013/14/15 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers
With Extension also…
We also write papers for your projects and give guidance for paper publishing.
For Further Details Call Us @
0-9347143789/9949240245
Visit us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries
mail to: asokatechnologies@gmail.com
ACADEMIC MATLAB SIMULATION 2013/14 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers With Extension also…
For Further Details Call Us @ 0-9347143789/9949240245
Visit Us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries mail to: asokatechnologies@gmail.com
Ieee power electrincs projects 2016 2017 titles mtechIeee Xpert
This document lists 94 IEEE power electronics projects for 2016-2017, providing project codes, titles, and years. It also provides contact information for IeeeXpert.com, which delivers these projects to electrical engineering students all over India, offering a 100% output satisfaction guarantee or refund. The projects cover topics like converters, inverters, motor drives, renewable energy, and more.
The document lists 50 power electronics projects from IEEE publications in 2014. It includes the project title, domain, and year for each project. MSR Projects is an SSI certified institution that provides training, development and placements. It focuses on power electronics projects from IEEE transactions in 2014 related to topics like DC/DC converters, AC/DC converters, inverters, and renewable energy applications.
This document provides information about power electronics projects available from Vision Groups. It lists 100 project titles within various domains of power electronics, including buck converters, boost converters, AC-DC converters, rectifiers, inverters, motor drives, renewable energy, and more. It also provides contact information for Vision Groups, which offers guidance and support for completing these projects, including project reports, demonstrations, and embedded hardware kits. Students can implement their own project ideas or choose from the lists of titles.
ACADEMIC MATLAB SIMULATION 2013/14/15 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers With Extension also…
We also write papers for your projects and give guidance for paper publishing.
For Further Details Call Us @
0-9347143789/9949240245
Visit us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries
mail to: asokatechnologies@gmail.com
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
latest 2014-15 ieee projects for eee, power electronics and power systemsAsoka Technologies
ACADEMIC MATLAB SIMULATION 2013/14/15 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers
With Extension also…
We also write papers for your projects and give guidance for paper publishing.
For Further Details Call Us @
0-9347143789/9949240245
Visit us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries
mail to: asokatechnologies@gmail.com
ACADEMIC MATLAB SIMULATION 2013/14 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS[PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers With Extension also…
For Further Details Call Us @ 0-9347143789/9949240245
Visit Us at: www.asokatechnologies.in
For Abstracts of IEEE papers and Any Queries mail to: asokatechnologies@gmail.com
Ieee power electrincs projects 2016 2017 titles mtechIeee Xpert
This document lists 94 IEEE power electronics projects for 2016-2017, providing project codes, titles, and years. It also provides contact information for IeeeXpert.com, which delivers these projects to electrical engineering students all over India, offering a 100% output satisfaction guarantee or refund. The projects cover topics like converters, inverters, motor drives, renewable energy, and more.
The document lists 50 power electronics projects from IEEE publications in 2014. It includes the project title, domain, and year for each project. MSR Projects is an SSI certified institution that provides training, development and placements. It focuses on power electronics projects from IEEE transactions in 2014 related to topics like DC/DC converters, AC/DC converters, inverters, and renewable energy applications.
This document provides information about power electronics projects available from Vision Groups. It lists 100 project titles within various domains of power electronics, including buck converters, boost converters, AC-DC converters, rectifiers, inverters, motor drives, renewable energy, and more. It also provides contact information for Vision Groups, which offers guidance and support for completing these projects, including project reports, demonstrations, and embedded hardware kits. Students can implement their own project ideas or choose from the lists of titles.
Ieee 2014 2015 matlab simulink power electronics projects titlespowerprojects
We offer IEEE 2014 matlab simulation projects, IEEE 2015 matlab simulation projects for B.E, M.E, B.Tech, M.Tech final year students in engineering colleges. We provide all project support with project training.
This document lists 120 academic projects related to power electronics and electrical engineering from 2014-2015. It provides project codes, titles, and years for M.Tech students in EEE-Simulation. It also includes contact information for anyone seeking further details on the projects.
Ieee 2014 2015 matlab power electronics projects titles list globalsoft techn...IEEEMATLABPROJECTS
To Get any Project for CSE, IT ECE, EEE Contact Me @ 09666155510, 09849539085 or mail us - ieeefinalsemprojects@gmail.com-Visit Our Website: www.globalsofttechnologies.org
This document lists 107 power electronics projects conducted by SAK Informatics between 2014-2015. It provides the project codes, titles, and years for each project. It also lists the contact information for Mahesh Pala and the company email address.
This document lists 100 M.E/M.Tech EEE projects from IEEE papers published in 2013-2014. It provides contact information for Buddhatechnologies, an organization that may provide more details on these projects. The projects cover topics related to power electronics, renewable energy integration, electric machines, motor drives, microgrids, and power quality. Project titles include novel converter topologies, control methods for inverters, active power filters, and applications in solar, wind, and electric vehicles.
The document lists 75 IEEE project titles from 2014-2015 related to power electronics. Most of the projects involve bidirectional DC-DC converters, boost converters, buck converters, buck-boost converters, and BLDC motor drives. The projects were conducted under various domains including bidirectional DC-DC conversion, BLDC motors, boost conversion, buck conversion, buck-boost conversion, and general DC-DC conversion. The document provides contact information for a technology company that may provide more details on the listed projects.
This document lists 46 potential IEEE project titles related to power electronics from 2014-2015. The project titles cover a range of topics including photovoltaic applications, AC-DC converters, DC-DC converters, battery energy management, electric vehicles, and more. Contact information is provided to discuss potential projects.
This document provides an overview and design of an electrical submersible pump (ESP) system for an oil and gas well. It includes sections on the general ESP design process, well data collection, production capacity calculation, gas calculation, total dynamic head calculation, pump selection to meet flow rate requirements, selection of a seal section, motor, power cable, and motor controller. It also describes ESP software developed for the design process and an economic study showing the project has a positive net present value, indicating it is profitable.
Hand movements based control of an intelligent wheelchair Using Accelerometer...IJERD Editor
This document describes a wheelchair control system using an accelerometer and sensors. The system uses an ADXL335 accelerometer to sense hand movements and control a wheelchair's direction through a microcontroller. An ultrasonic sensor detects obstacles and stairs, while an IR sensor detects obstacles. The accelerometer data is converted to digital and sent to a microcontroller to control DC motors and move the wheelchair forward, backward, left, right or stop based on hand tilts. Additional sensors prevent collisions and falling. The system provides affordable and hands-free wheelchair control. Future work may include GPS, GSM for emergencies, or alternative control methods like eye tracking.
This document describes a project report on the measurement, protection, and graphical observation of a DC motor using an ATmega-16 microcontroller. The project was completed by three students to fulfill the requirements for a Bachelor of Technology degree. The project involved designing a circuit to measure voltage, current, speed, and torque of a DC motor. The measured values were displayed on a 16x4 LCD and two graphs were plotted on a 128x64 graphical LCD showing the N-I characteristics curve of the motor and a voltage vs. time graph. The circuit provided protection by stopping the motor if parameter values exceeded set limits. The overall goal was to control and observe the DC motor's parameters using a low-cost, portable embedded system.
The document lists 97 electrical projects for engineering students on the website http://www.edgefxkits.com. The projects cover a wide range of topics and involve using components like Arduino, PIC microcontrollers, sensors and more. They include projects involving solar energy systems, motor speed control, wireless power transfer, home automation and electrical load management. The conclusion states that students can gain theoretical and practical knowledge from these projects by choosing ones that interest them.
The document describes a final year project report submitted by Muhammad Ahkam Khan and Muhammad Waqar to the Department of Electrical Engineering at National University of Computer and Emerging Sciences in Peshawar, Pakistan in June 2013 for their Bachelor of Electrical Engineering degree, on developing a wireless gesture controlled robot.
This document describes a head movement controlled wheelchair that was developed by students to help people with limited mobility. The wheelchair can be controlled through tilt movements of the user's head, allowing paraplegics and quadriplegics to navigate using only head motions. Sensors are able to detect the head tilts and send signals to motors that drive the wheelchair in the corresponding directions. This provides an alternative control method that is easier to use than traditional wheelchairs for those with mobility impairments affecting their limbs. The system was tested successfully through computer simulations.
This project aims to help physically challenged people control electrical devices and communicate their basic needs using only head movements. The system uses a MEMS sensor and microcontroller to detect head movements and control relays connected to lights, fans, etc. It also includes a voice chip that can verbally communicate the user's needs. The components and circuit diagrams are described to showcase how the system works.
This document proposes a head motion controlled wheelchair that allows quadriplegic patients to move independently. It uses an accelerometer attached to the patient's head to sense tilt motions and control a wheelchair in four directions. The system includes obstacle detection sensors and vital monitoring to alert caregivers if needed. It aims to improve mobility and safety for disabled individuals.
This document describes a gesture controlled car that can be operated through hand gestures detected by an accelerometer worn on the hand. It consists of an accelerometer, microcontroller, motor driver, motors, RF module, encoder and decoder ICs. The accelerometer senses hand tilts and generates control signals to move the car in four directions. This technology allows for more natural interaction than traditional interfaces and has applications in entertainment, remote control, industrial control, military robotics and medical surgery. Gesture control is expected to become more advanced and widespread with further technological progress.
The objective of this project was to design a power wheelchair with a novel control system for quadriplegics with head or hand mobility. The control system translates the position of the user's hand into speed and directional control of the wheelchair. Hand movement was measured using accelerometer sensor-based motion- tracking of an sensor array on the back of the user's hand.
accelerometer based gesture controlled robotic arm Padmakar Mangrule
This document summarizes a seminar on controlling an industrial robotic arm using accelerometer-based gestures. The seminar covered:
1. A gesture-controlled robot that can be operated through hand gestures detected by a small transmitting device worn on the hand, containing an accelerometer.
2. The gesture device contains an accelerometer to detect motion, a comparator to convert analog signals to digital, an encoder to convert signals to radio format, and an RF transmitter to send commands wirelessly.
3. The robot contains an RF receiver to receive commands, a decoder to convert radio signals to motor commands, a microcontroller (ARM 7) to process commands, and a motor driver to operate the robotic arm.
Hand gesture based wheel chair for disablevedabobbala
This document presents a project to develop a wheelchair control system using MEMS technology to recognize hand gestures. A MEMS 3-axis acceleration sensor detects the direction of the user's hand movement and sends signals to a microcontroller. The microcontroller then controls two DC geared motors and an H-bridge circuit to move the wheelchair in directions like left, right, front, or back depending on the hand gesture. A lead-acid battery provides power to the entire system. The goal is to enable physically disabled users to control the wheelchair through hand motions.
This project is to develop a wheel chair for physically disabled people
The wheel chair is controlled by hand movement/hand gestures
The gestures are recognized by an accelerometer sensor
An ultrasonic sensor is used to detect the obstacles in front of the chair
The signals from the sensors are processed, and the wheel chair is controlled by Atmega-328 micro controller
Ieee 2014 2015 matlab simulink power electronics projects titlespowerprojects
We offer IEEE 2014 matlab simulation projects, IEEE 2015 matlab simulation projects for B.E, M.E, B.Tech, M.Tech final year students in engineering colleges. We provide all project support with project training.
This document lists 120 academic projects related to power electronics and electrical engineering from 2014-2015. It provides project codes, titles, and years for M.Tech students in EEE-Simulation. It also includes contact information for anyone seeking further details on the projects.
Ieee 2014 2015 matlab power electronics projects titles list globalsoft techn...IEEEMATLABPROJECTS
To Get any Project for CSE, IT ECE, EEE Contact Me @ 09666155510, 09849539085 or mail us - ieeefinalsemprojects@gmail.com-Visit Our Website: www.globalsofttechnologies.org
This document lists 107 power electronics projects conducted by SAK Informatics between 2014-2015. It provides the project codes, titles, and years for each project. It also lists the contact information for Mahesh Pala and the company email address.
This document lists 100 M.E/M.Tech EEE projects from IEEE papers published in 2013-2014. It provides contact information for Buddhatechnologies, an organization that may provide more details on these projects. The projects cover topics related to power electronics, renewable energy integration, electric machines, motor drives, microgrids, and power quality. Project titles include novel converter topologies, control methods for inverters, active power filters, and applications in solar, wind, and electric vehicles.
The document lists 75 IEEE project titles from 2014-2015 related to power electronics. Most of the projects involve bidirectional DC-DC converters, boost converters, buck converters, buck-boost converters, and BLDC motor drives. The projects were conducted under various domains including bidirectional DC-DC conversion, BLDC motors, boost conversion, buck conversion, buck-boost conversion, and general DC-DC conversion. The document provides contact information for a technology company that may provide more details on the listed projects.
This document lists 46 potential IEEE project titles related to power electronics from 2014-2015. The project titles cover a range of topics including photovoltaic applications, AC-DC converters, DC-DC converters, battery energy management, electric vehicles, and more. Contact information is provided to discuss potential projects.
This document provides an overview and design of an electrical submersible pump (ESP) system for an oil and gas well. It includes sections on the general ESP design process, well data collection, production capacity calculation, gas calculation, total dynamic head calculation, pump selection to meet flow rate requirements, selection of a seal section, motor, power cable, and motor controller. It also describes ESP software developed for the design process and an economic study showing the project has a positive net present value, indicating it is profitable.
Hand movements based control of an intelligent wheelchair Using Accelerometer...IJERD Editor
This document describes a wheelchair control system using an accelerometer and sensors. The system uses an ADXL335 accelerometer to sense hand movements and control a wheelchair's direction through a microcontroller. An ultrasonic sensor detects obstacles and stairs, while an IR sensor detects obstacles. The accelerometer data is converted to digital and sent to a microcontroller to control DC motors and move the wheelchair forward, backward, left, right or stop based on hand tilts. Additional sensors prevent collisions and falling. The system provides affordable and hands-free wheelchair control. Future work may include GPS, GSM for emergencies, or alternative control methods like eye tracking.
This document describes a project report on the measurement, protection, and graphical observation of a DC motor using an ATmega-16 microcontroller. The project was completed by three students to fulfill the requirements for a Bachelor of Technology degree. The project involved designing a circuit to measure voltage, current, speed, and torque of a DC motor. The measured values were displayed on a 16x4 LCD and two graphs were plotted on a 128x64 graphical LCD showing the N-I characteristics curve of the motor and a voltage vs. time graph. The circuit provided protection by stopping the motor if parameter values exceeded set limits. The overall goal was to control and observe the DC motor's parameters using a low-cost, portable embedded system.
The document lists 97 electrical projects for engineering students on the website http://www.edgefxkits.com. The projects cover a wide range of topics and involve using components like Arduino, PIC microcontrollers, sensors and more. They include projects involving solar energy systems, motor speed control, wireless power transfer, home automation and electrical load management. The conclusion states that students can gain theoretical and practical knowledge from these projects by choosing ones that interest them.
The document describes a final year project report submitted by Muhammad Ahkam Khan and Muhammad Waqar to the Department of Electrical Engineering at National University of Computer and Emerging Sciences in Peshawar, Pakistan in June 2013 for their Bachelor of Electrical Engineering degree, on developing a wireless gesture controlled robot.
This document describes a head movement controlled wheelchair that was developed by students to help people with limited mobility. The wheelchair can be controlled through tilt movements of the user's head, allowing paraplegics and quadriplegics to navigate using only head motions. Sensors are able to detect the head tilts and send signals to motors that drive the wheelchair in the corresponding directions. This provides an alternative control method that is easier to use than traditional wheelchairs for those with mobility impairments affecting their limbs. The system was tested successfully through computer simulations.
This project aims to help physically challenged people control electrical devices and communicate their basic needs using only head movements. The system uses a MEMS sensor and microcontroller to detect head movements and control relays connected to lights, fans, etc. It also includes a voice chip that can verbally communicate the user's needs. The components and circuit diagrams are described to showcase how the system works.
This document proposes a head motion controlled wheelchair that allows quadriplegic patients to move independently. It uses an accelerometer attached to the patient's head to sense tilt motions and control a wheelchair in four directions. The system includes obstacle detection sensors and vital monitoring to alert caregivers if needed. It aims to improve mobility and safety for disabled individuals.
This document describes a gesture controlled car that can be operated through hand gestures detected by an accelerometer worn on the hand. It consists of an accelerometer, microcontroller, motor driver, motors, RF module, encoder and decoder ICs. The accelerometer senses hand tilts and generates control signals to move the car in four directions. This technology allows for more natural interaction than traditional interfaces and has applications in entertainment, remote control, industrial control, military robotics and medical surgery. Gesture control is expected to become more advanced and widespread with further technological progress.
The objective of this project was to design a power wheelchair with a novel control system for quadriplegics with head or hand mobility. The control system translates the position of the user's hand into speed and directional control of the wheelchair. Hand movement was measured using accelerometer sensor-based motion- tracking of an sensor array on the back of the user's hand.
accelerometer based gesture controlled robotic arm Padmakar Mangrule
This document summarizes a seminar on controlling an industrial robotic arm using accelerometer-based gestures. The seminar covered:
1. A gesture-controlled robot that can be operated through hand gestures detected by a small transmitting device worn on the hand, containing an accelerometer.
2. The gesture device contains an accelerometer to detect motion, a comparator to convert analog signals to digital, an encoder to convert signals to radio format, and an RF transmitter to send commands wirelessly.
3. The robot contains an RF receiver to receive commands, a decoder to convert radio signals to motor commands, a microcontroller (ARM 7) to process commands, and a motor driver to operate the robotic arm.
Hand gesture based wheel chair for disablevedabobbala
This document presents a project to develop a wheelchair control system using MEMS technology to recognize hand gestures. A MEMS 3-axis acceleration sensor detects the direction of the user's hand movement and sends signals to a microcontroller. The microcontroller then controls two DC geared motors and an H-bridge circuit to move the wheelchair in directions like left, right, front, or back depending on the hand gesture. A lead-acid battery provides power to the entire system. The goal is to enable physically disabled users to control the wheelchair through hand motions.
This project is to develop a wheel chair for physically disabled people
The wheel chair is controlled by hand movement/hand gestures
The gestures are recognized by an accelerometer sensor
An ultrasonic sensor is used to detect the obstacles in front of the chair
The signals from the sensors are processed, and the wheel chair is controlled by Atmega-328 micro controller
1. A DC motor runs on direct current electricity. It has a field winding that produces a magnetic field when energized, and an armature winding that rotates when placed in this magnetic field.
2. The key parts of a DC motor include the yoke, poles, field winding, armature core, armature winding, commutator, and brushes. The field winding produces flux, and the rotation of the armature winding within this flux induces voltage that is used to power the load.
3. DC motors can be shunt wound, series wound, or compound wound depending on how the field and armature windings are connected. Shunt and series motors have different torque-speed characteristics due
The document discusses DC motors. It begins with an introduction to DC motors, noting they convert electrical to mechanical energy. It then covers the principles, construction, types, and applications of DC motors. The principles section explains how DC motors work using electromagnetism and the Lorentz force. Construction includes field and armature windings. There are three main types - shunt, series, and compound motors - which vary in how their field windings are connected. Applications include uses for different motor types like fans, tools, and mills.
Tapworthy: Designing iPhone Interfaces for Delight and UsabilityJosh Clark
This SXSW presentation covers: the elusive ingredients of "tapworthy" apps; why building iPhone apps is like designing a physical gadget; usability gotchas on handheld devices; and how the best iPhone designers turn constraints — limited screen space and fleeting user attention — into advantages for their apps. Along the way, Josh shares behind-the-scenes glimpses into the design process of popular apps including Facebook, Twitterrific, USA Today, Things, and others.
The presentation is by designer, developer, and author Josh Clark, previewing ideas from his upcoming book, "Tap Happy: Designing Great iPhone Apps" from O'Reilly Media.
The document discusses integrating renewable energy, particularly solar power, into the electric grid. It covers regulatory standards in India for distributed generation and grid connectivity. It also examines technical considerations from the perspective of solar generation, including inverter functions and grid codes. Challenges of integrating high levels of renewable energy into the grid are discussed, along with potential solutions like grid automation and smart grid applications. A holistic, integrated approach is needed to deal with the increased complexity of incorporating renewable energy at large scales.
This document provides information about electrical projects using MATLAB/Simulink that can be developed for academic purposes. It lists 84 project codes along with the project title, year, and journal. It also provides contact information for Asokatechnologies, which can develop custom projects, provide guidance for publishing papers, and provide abstracts of past IEEE papers.
Latest 2014/15 B Tech and M Tech IEEE projects for EEE,Power Electronics and ...Asoka Technologies
This document provides information about electrical projects using MATLAB/Simulink that can be developed for academic purposes. It lists 84 project codes and titles from 2013 to 2010 in various journals like IEEE, IJETEE, and more. Custom projects can also be developed. Contact details are provided to discuss project details, abstracts, or queries.
ACADEMIC MATLAB SIMULATION 2014/15/16 PROJECTS FOR
• ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
• POWER ELECTRONICs AND DRIVES[PED]
• POWER SYSTEMS [PS]….
We Can also Develop Your Own Ideas and Your IEEE Papers With Extension also…
We also write papers for your projects and give guidance for paper publishing.
For Further Details Call Us @
0-9347143789/9949240245
Visit us at: www.asokatechnologies.in
For Abstracts of IEEE papers and For Any Queries
Mail us : asokatechnologies@gmail.com
Latest Electrical projects for BTech/MTech using Matlab/SimulinkAsoka Technologies
Asoka Technologies offer latest IEEE Electrical projects for BTech and MTech. We have many projects and we do provide abstract, paper explanation, simulink model explanation and exact results within time.
We do develop your own ideas also.
This document advertises electrical projects using MATLAB/Simulink that can be developed for academic purposes. It provides contact information for Asokatechnologies, which offers to develop customized projects and provide guidance for publishing papers. It then lists over 60 past project codes and titles related to electrical engineering topics like power electronics, drives, power systems, renewable energy, and more.
This document advertises electrical projects using MATLAB/Simulink that can be developed for academic purposes. It provides contact information for Asokatechnologies, which offers MATLAB simulations for electrical and electronics engineering, power electronics and drives, and power systems projects. It also lists over 60 past project codes and titles conducted between 2016-2018 in various IEEE and IET journals.
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
This document advertises electrical projects using MATLAB/Simulink that can be developed for academic purposes. It provides contact information for Asokatechnologies, which offers to develop customized projects and provide guidance for publishing papers. It then lists over 60 past project codes and titles conducted from 2016-2018 in the areas of electrical, electronics, power electronics, and power systems engineering. The projects are published in IEEE and IET journals.
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
This document advertises electrical projects using MATLAB/Simulink that can be developed for academic purposes. It provides contact information for Asokatechnologies, which offers to develop customized projects and provide guidance for publishing papers. It then lists over 60 past project codes and titles related to electrical engineering topics like power electronics, renewable energy, motor drives, and power quality.
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
ASOKA TECHNOLOGIES
(B.TECH/M.TECH ELECTRICAL PROJECTS USING MATLAB/SIMULINK)
WE OFFER ACADEMIC MATLAB SIMULATION PROJECTS FOR
1. ELECTRICAL AND ELECTRONICS ENGINEERING [EEE]
2. POWER ELECTRONICS AND DRIVES [PED]
3. POWER SYSTEMS [PS]….etc
We will develop your OWN IDEAS and your IEEE Papers with extension if necessary and also we give guidance for publishing papers…
For Further Details Call Us @
0-9347143789/9949240245
For Abstracts of IEEE papers and for any Queries mail to: asokatechnologies(gmail) and also visit asokatechnologies(blogspot)
Similar to 2015 latest IEEE electrical project list for BTech, Mtech, Phd (20)
This document describes a project to design and simulate a solar photovoltaic charging station for electric vehicles using MATLAB/Simulink. The charging station employs a multi-port design to provide constant voltage DC power from the solar panels to charge vehicle batteries using a constant current/constant voltage method. The performance of the charging system is validated through simulation and experimental results. The conclusion discusses opportunities to enhance such systems through optimization techniques, energy storage, intelligent controllers, and hybrid designs incorporating multiple renewable energy sources.
Generation of Higher Number of Voltage Levels by Stacking Inverters of Lower ...Asoka Technologies
This paper proposes a new method of generating higher number of levels in the voltage waveform by stacking multilevel converters with lower voltage space vector structures. An important feature of this stacked structure is the use of low voltage devices while attaining higher number of levels. This will find extensive applications in electric vehicles since direct battery drive is possible. The voltages of all the capacitors in the structure can be controlled within a switching cycle using the switching state redundancies (pole voltage redundancies). This helps in reducing the capacitor size. Also, the capacitor voltages can be balanced irrespective of modulation index and load power factor. To verify the concept experimentally, a 9-level inverter is developed by stacking two 5-level inverters and an induction motor is run using V/f control scheme. Both steady state and transient results are presented.
Novel symmetric modular hybrid multilevel inverter with reduced number of sem...Asoka Technologies
In this paper, by using a modular hybrid structure, a new topology for symmetric multilevel inverters (MLI) with a small number of semiconductors and low voltage stress across switches is proposed. Despite many other topologies, this topology can inherently produce negative levels and zero levels without using the H-bridge. The voltage stress across a particular switch of the proposed MLI is inversely proportional to the number of the switching of that switch in a voltage period. The proposed structure is based on two types of module, that is, the f-module and the e-module. The e-module uses a capacitive voltage divider to double the number of non-zero levels. The voltages of the capacitors are approximately balanced without complex control methods. The basic structure of the proposed topology is formed by connecting the f-module and the e-module in series with each other, and the cascaded topology is developed by cascading multiple f-modules with an e-module. To investigate the proposed topology and proving its practicability, simulation results with MATLAB/Simulink, investigation of the capacitor voltages, loss calculations and experimental results are presented. A comparative study is also performed to show the merit of the new multilevel inverter over other topologies.
A Variable DC Link based Novel Multilevel Inverter Topology for Low Voltage A...Asoka Technologies
In this paper; a variable dc link based novel multilevel inverter (MLI) topology is proposed. This proposed topology comprises two variable dc links and a modified H-bridge unit. This new single-phase topology offers advantages such as reduction in count of switches; gate drivers and dc sources while simultaneously improving the power quality. The proposed topology has been analyzed for both symmetric and asymmetric modes of operation. A comparative study of the proposed topology with some recent MLI topologies has been presented. The comparative study indicates that the proposed topology requires less number of dc sources; switches and driver circuits as compared to other topologies. The proposed topology has been simulated for 31- level asymmetric configuration in MATLAB/SIMULINK environment to verify the proper operation of proposed topology. Harmonic analysis was also performed for 31-level inverter which showed significant reduction in the total harmonic distortion (THD) for phase voltage and current waveforms. The proposed topology is suitable for low voltage applications such as standalone photovoltaic (PV) systems and hybrid electric vehicles (HEVs).
A Simplified Space Vector Pulse-Width Modulation Scheme for Three-Phase Casca...Asoka Technologies
This document presents a simplified space vector pulse-width modulation (SVPWM) scheme for three-phase cascaded H-bridge inverters. It treats each unit as a three-level inverter and uses three-level SVPWM to modulate each unit individually. Duty cycles from sector 1 are mapped to obtain duty cycles for other sectors. This simplifies the process compared to conventional multilevel SVPWM. Simulation and experimental results validate the presented SVPWM scheme, which provides a higher effective switching frequency while maintaining the same DC-link voltage utilization as conventional SVPWM, with significantly reduced FPGA resource utilization.
A New Family of Step-up Hybrid Switched- Capacitor Integrated Multilevel Inve...Asoka Technologies
In the low voltage based renewable systems like PV and Fuel cell applications, the step-up of the output voltage to drive the loads is essential. For this, the integration of switched-capacitor (SC) units with the dc-ac converters will have the potential advantages like improved efficiency, optimal switching devices, small size of passive elements (L and C) as compared with traditional two-stage conversion system (dc/dc converter and dc/ac converter). This paper focuses on a new family of step-up multilevel inverter topologies with switched capacitor integration with dual input voltage sources. With the flexibility of 2 dc sources and switching capacitor circuits, four different topologies have been suggested in this paper with features of high voltage gain, reduced component count, reduced voltage stress and self-voltage balancing of the capacitor while achieving a higher number of levels. A detailed analysis of proposed multilevel inverters has been analyzed with the symmetrical and asymmetrical mode of operations and the associated gain, the number of levels, and other performance indices are presented. An in-depth study of all the topologies has been accomplished in this paper with several comparative studies in terms of components count, voltage gain and cost. The effectiveness and practicability of the suggested topology with 13 level output voltage has been explained by the experimental results obtained from a scale down prototype.
A multi cell 21-level hybrid multilevel inverter synthesizes a reduced number...Asoka Technologies
A multi-cell hybrid 21-Level multilevel inverter is proposed in this paper. The proposed topology includes two-unit; an H-bridge is cascaded with a modified K-type unit to generate an output voltage waveform with 21 levels based only on two unequal DC suppliers. The proposed topology's advantage lies in the fine and clear output voltage waveforms with high output efficiency. Meanwhile, the high number of output voltage waveform levels generates a low level of distortion and reduces the level of an electromagnetic interface (EMI). Moreover, it reduces the voltage stress on the switching devices and gives it a long lifetime. Also, the reduction in the number of components has a noticeable role in saving size and cost. Regarding the capacitors charging, the proposed topology presents an online method for charging and balancing the capacitor's voltage without any auxiliary circuits. The proposed topology can upgrade to a high number of output steps through the cascading connection. Undoubtedly this cascading will increase the power level to medium and high levels and reduce the harmonics content to a neglectable rate. The proposed system has been tested through the simulation results, and an experimental prototype based on the controller dSPACE (DS-1103) hardware unit used to support the simulation results.
A generalized multilevel inverter topology with reduction of total standing v...Asoka Technologies
This paper presents a new multilevel inverter topology with reduced active switches and total standing voltage. The proposed topology can generate a high number of voltage levels in the symmetric configuration. This topology intuitively generates positive and negative cycles without an additional H-bridge unit, which considerably reduces the total standing voltage of the inverter. A cascaded structure is developed from the proposed topology to create higher voltage levels. To show the novelty of the proposed topology, a thorough comparison between the available and the proposed topologies in terms of the number of switches, standing voltages, and dc-sources is presented. Furthermore, the power loss analysis is carried out for various load values. The feasibility of the proposed nine-level inverter is verified with simulation and experimental results.
Power Quality Improvement in Solar Fed Cascaded Multilevel Inverter with Outp...Asoka Technologies
This document discusses a project to improve power quality in a solar photovoltaic energy conversion system using a cascaded 15-level inverter. Proportional Integral, Artificial Neural Network, and Fuzzy Logic controllers are investigated to eliminate harmonics. Simulations were performed in MATLAB/Simulink and hardware was demonstrated for a 3kWp photovoltaic plant coupled to a multilevel inverter. The fuzzy logic controller provided the best results for voltage regulation and power quality improvement. Experimental results validated the effectiveness of the proposed system for grid interaction while improving power quality.
Residential Community Load Management based on Optimal Design of Standalone H...Asoka Technologies
This document presents a study on designing a standalone hybrid renewable energy system (HRES) for a residential community in Pakistan using PV, wind, diesel, and battery. Nine system configurations were analyzed using HOMER software to determine the optimal and most economical design. HOMER results showed a PV-wind-battery system with 13.4 kW PV, 4 kW wind, and 20 battery units was optimal, with a net present cost of $28,620 and cost of energy of $0.311/kWh. MATLAB/Simulink modeling validated this design could maintain voltages and safe battery SOC while meeting load, even with generation and demand fluctuations. The HRES design and control strategy presented provides a tool for planning
Reliability evaluation of MPPT based interleaved boost converter for PV systemAsoka Technologies
The demand for power supply and depletion of the conventional energy sources are increasing drastically. So to overcome this problem, the best alternative power generation for conventional fossil fuel is Photovoltaic solar cell based system because of its advantage of pollution free and its availability in abundance with free of cost. In the MPPT based PV system the converters are the most sensitive part. Therefore to provide uninterrupted power supply without compromising the quality of power, reliability evaluation of interleaved boost converter becomes necessary. MATLAB/Simulink is used for the simulation studies and to determine the power losses of various components of the converter which is used in calculating the failure rates and reliability of the interleaved boost converter. Reliability studies of IBC have not been studied much. However there exists few literature in which reliability expression has been developed using Markov technique which is a more complex method as compare to Reliability Block Diagram (RBD). Therefore this paper proposes reliability modeling and reliability evaluation of Interleaved boost converter in MPPT based photo-voltaic system by using simple RBD method.
Power Quality Improvement of Grid-Connected Photovoltaic Systems Using Trans-...Asoka Technologies
Voltage-source inverter has been used widely in traditional photovoltaic systems which have limitations. To overcome, Z-source inverter has been introduced. In spite of all the features introduced in Z-source inverter, its configuration has been improved over the years, like trans-Z-source inverter which has added advantages compared to traditional inverters, namely buck–boost feature, lesser passive elements, and higher voltage boost gain. In this paper, photovoltaic arrays are connected to the grid via the trans-Z-source inverter with the aim of improving its power quality. Moreover, the shoot through duty ratio is kept constant in the switching control method to add features like lower voltage stress (higher reliability), lower total harmonic distortion (lower maintenance cost), and higher voltage boost ratio. To evaluate the precision of the proposed system, the photovoltaic system is simulated on a standard grid and under partial shading condition which brings about voltage sag, and hence, a dynamic voltage restorer is used to mitigate voltage sag. Simulation results are presented to verify the validation of the proposed photovoltaic system in terms of voltage and current THD reducing 78.2% and 19.7%, respectively.
Power optimisation scheme of induction motor using FLC for electric vehicleAsoka Technologies
In electric vehicles (EVs) and hybrid EVs, energy efficiency is essential where the energy storage is limited. Adding to its high stability and low cost, the induction motor efficiency improves with loss minimisation. Also, it can consume more power than the actual need to perform its working when it is operating in less than full load condition. This study proposes a control strategy based on the fuzzy logic control (FLC) for EV applications. FLC controller can improve the starting current amplitude and saves more power. Through the MATLAB/SIMULINK software package, the performance of this control was verified through simulation. As compared with the conventional proportional integral derivative controller, the simulation schemes show good, high-performance results in time-domain response and rapid rejection of system-affected disturbance. Therefore, the core losses of the induction motor are greatly reduced, and in this way improves the efficiency of the driving system. Finally, the suggested control system is validated by the experimental results obtained in the authors’ laboratory, which are in good agreement with the simulation results.
Power Flow Control of Interconnected AC-DC Microgrids in Grid-Connected Hybri...Asoka Technologies
This paper introduces a new approach for power flow control of interconnected AC-DC microgrids in grid-connected hybrid microgrids based on implementing a modified unified interphase power controller (UIPC). A typical grid-connected hybrid microgrid including one AC microgrid and one DC microgrid is considered as studied system. Instead of using the parallel-connected power converters, these microgrids are interconnected using a modified UIPC. As the first contribution of this paper, the conventional structure of UIPC, which uses three power converters in each phase, is modified so that a reduced number of power converters is implemented for power exchange control between AC-DC microgrids. The modified structure includes one power converter in each phase, named as line power converter (LPC), and a power converter which regulates the DC bus voltage, named as bus power converter (BPC) here. The AC microgrid is connected to the main grid through the LPCs which their DC buses are linked and can operate in capacitance mode (CM) or inductance mode (IM). A fuzzy logic controller is used in the control structure of the LPCs. The fuzzy inference system is optimized based on H∞ filtering method to reduce the errors in membership functions design. Through the BPC, the DC voltage of LPCs is supplied by the DC microgrid. However, since the DC microgrid voltage is provided here by a PV system, the DC link voltage of the LPCs is fluctuating. Thus, as the second contribution, to stabilize the DC link fluctuations, a new nonlinear disturbance observer based robust multiple-surface sliding mode control (NDO-MS-SMC) strategy is presented for DC side control of the BPC. The simulation results confirm the effectiveness of the proposed power flow control strategy of the improved UIPC for hybrid microgrids.
Power flow control of hybrid micro grids using modified uipcAsoka Technologies
Neuro Fuzzy Inference System (ANFIS) controlled modified Unified Inter-Phase Power Controller (UIPC). For study, a classic hybrid micro-grid connected to grid comprising of a AC micro-grid and a DC micro-grid is taken into account. These micro-grids are interconnected employing a modified UIPC, rather than using the power converters connected in parallel. As the first input of this paper is the standard structure of UIPC, which used three power converters in every phase. It was then modified such as number of power converters is used less and implemented for the control of the exchange of power between AC-DC microgrids. In every phase there is one power electronic converter in the improved structure. It is called as Line Power Converter (LPC). Also there is Bus Power Converter (BPC) to regulate the voltage of the DC bus. The Line Power Converters links the AC micro-grid to the main grid. The DC buses are also linked with them. It can be operated in Inductance Mode (IM) as well as Capacitance Mode (CM). The control structure of LPCs has an Adaptive Fuzzy Logic Controller in it. For hybrid micro-grids, the capability of the suggested power flow control strategy is confirmed by the MATLAB simulation results.
Multifunctional grid tied pv system using modified klms controlAsoka Technologies
This paper deals with the modified kernel least mean square (KLMS) control strategy in double-stage, solar photovoltaic (PV) grid tied system to enhance the power quality at common coupling point (CCP). This proposed control algorithm has less oscillations, fast convergence, fast dynamic response and good steady state performance. A control strategy is used to extract the fundamental active current component of load and generates reference grid current for a DC-AC converter. The proposed modified KLMS control mitigates multiple power quality concerns such as harmonics reduction, unity power factor and load balancing. The dynamic performance of proposed system is confirmed into the MATLAB\Simulink environment. Test results on hardware implementation are presented at varying solar irradiation levels and load unbalancing. Test results are found satisfactory and total harmonic distortion (THD) of the grid currents are observed well within the IEEE-519 standard.
Modelling and voltage control of the solar wind hybrid micro-grid with optimi...Asoka Technologies
Electricity generation from the wind and solar photovoltaic (PV) systems are highly dependent upon weather conditions. Their intermittent nature leads to fluctuations in their output. Therefore, the need for rapid compensation for energy transmission and distribution systems is increasingly important. Static Synchronous Compensator (STATCOM) can be adopted for reactive power compensation and for decreasing the voltage fluctuation caused by the system and renewable energy sources. This study presents modelling of a Solar PV-Wind Hybrid Micro-grid and the increase of the stable operating limit of the system in case of the incorporation of STATCOM is examined. The major contribution of this paper is the optimization of gain parameters of four PI controllers in STATCOM control circuit based on genetic algorithms (GA) and Bacteria Foraging Algorithm (BFA) and therefore obtaining better responses and voltage stability in terms of nonlinear nature of solar-wind hybrid micro-grid. The Simulink models of the system architecture include a wind turbine model, a solar PV power system model and a STATCOM. It is certified that the voltage fluctuation at the end of the bus bar is reduced by 8% using conventional PI controller, by 10% for GA-based PI controller, and by 15% for BFA based PI controller under variable load. The results obtained by GA and BFA-based optimization of PI controllers are compared with that of the conventional controller and better results attained.
Irradiance-adaptive PV Module Integrated Converter for High Efficiency and Po...Asoka Technologies
The strive for efficient and cost-effective photovoltaic systems motivated the power electronic design developed here. The work resulted in a DC-DC converter for module integration and distributed maximum power point tracking (MPPT) with a novel adaptive control scheme. The latter is essential for the combined features of high energy efficiency and high power quality over a wide range of operating conditions. The switching frequency is optimally modulated as a function of solar irradiance for power conversion efficiency maximization. With the rise of irradiance, the frequency is reduced to reach the conversion efficiency target. A search algorithm is developed to determine the optimal switching frequency step. Reducing the switching frequency may, however, compromise MPPT efficiency. Furthermore, it leads to increased ripple content. Therefore, to achieve a uniform high power quality at all conditions, interleaved converter cells are adaptively activated. The overall cost is kept low by selecting components that allow for implementing the functions at low cost. Simulation results show the high value of the module integrated converter for DC standalone and microgrid applications. A 400 W prototype was implemented at 0.14 Euro/W. Testing showed efficiencies above 95% taking into account all losses from power conversion, MPPT, and measurement and control circuitry.
Intelligent Power Sharing of DC Isolated Microgrid Based on Fuzzy Sliding Mod...Asoka Technologies
The document describes a novel droop control strategy for accurate power sharing in an isolated DC microgrid considering uncertainties and disturbances. It proposes using a sliding mode controller based on a Takagi-Sugeno fuzzy model to represent the nonlinear droop characteristics. The control strategy compensates for uncertainties and disturbances to achieve accurate proportional load power sharing without communication. The method is verified through PSIM/Matlab simulation to regulate load changes and ensure system stability in the DC microgrid.
Implementation of solar pv battery and diesel generator based electric vehic...Asoka Technologies
In this paper, a solar PV (Photovoltaic) array, a battery energy storage (BES), a diesel generator (DG) set and grid based EV charging station (CS) is utilized to provide the incessant charging in islanded, grid connected and DG set connected modes. The charging station is primarily designed to use the solar photovoltaic PV array and a BES to charge the electric vehicle (EV) battery. However, in case of exhausted storage battery and unavailable solar PV array generation, the charging station intelligently takes power from the grid or DG (Diesel Generator) set. However, the power from DG set is drawn in a manner that, it always operates at 80-85% loading to achieve maximum fuel efficiency under all loading conditions. Moreover, in coordination with the storage battery, the charging station regulates the generator voltage and frequency without a mechanical speed governor. It also ensures that the power drawn from the grid or the DG set is at unity power factor (UPF) even at nonlinear loading. Moreover, the PCC (Point of Common Coupling) voltage is synchronized to the grid/ generator voltage to obtain the ceaseless charging. The charging station also performs the vehicle to grid active/reactive power transfer, vehicle to home and vehicle to vehicle power transfer for increasing the operational efficiency of the charging station. The operation of the charging station is experimentally validated using the prototype developed in the laboratory.
বাংলাদেশের অর্থনৈতিক সমীক্ষা ২০২৪ [Bangladesh Economic Review 2024 Bangla.pdf] কম্পিউটার , ট্যাব ও স্মার্ট ফোন ভার্সন সহ সম্পূর্ণ বাংলা ই-বুক বা pdf বই " সুচিপত্র ...বুকমার্ক মেনু 🔖 ও হাইপার লিংক মেনু 📝👆 যুক্ত ..
আমাদের সবার জন্য খুব খুব গুরুত্বপূর্ণ একটি বই ..বিসিএস, ব্যাংক, ইউনিভার্সিটি ভর্তি ও যে কোন প্রতিযোগিতা মূলক পরীক্ষার জন্য এর খুব ইম্পরট্যান্ট একটি বিষয় ...তাছাড়া বাংলাদেশের সাম্প্রতিক যে কোন ডাটা বা তথ্য এই বইতে পাবেন ...
তাই একজন নাগরিক হিসাবে এই তথ্য গুলো আপনার জানা প্রয়োজন ...।
বিসিএস ও ব্যাংক এর লিখিত পরীক্ষা ...+এছাড়া মাধ্যমিক ও উচ্চমাধ্যমিকের স্টুডেন্টদের জন্য অনেক কাজে আসবে ...
Reimagining Your Library Space: How to Increase the Vibes in Your Library No ...Diana Rendina
Librarians are leading the way in creating future-ready citizens – now we need to update our spaces to match. In this session, attendees will get inspiration for transforming their library spaces. You’ll learn how to survey students and patrons, create a focus group, and use design thinking to brainstorm ideas for your space. We’ll discuss budget friendly ways to change your space as well as how to find funding. No matter where you’re at, you’ll find ideas for reimagining your space in this session.
ISO/IEC 27001, ISO/IEC 42001, and GDPR: Best Practices for Implementation and...PECB
Denis is a dynamic and results-driven Chief Information Officer (CIO) with a distinguished career spanning information systems analysis and technical project management. With a proven track record of spearheading the design and delivery of cutting-edge Information Management solutions, he has consistently elevated business operations, streamlined reporting functions, and maximized process efficiency.
Certified as an ISO/IEC 27001: Information Security Management Systems (ISMS) Lead Implementer, Data Protection Officer, and Cyber Risks Analyst, Denis brings a heightened focus on data security, privacy, and cyber resilience to every endeavor.
His expertise extends across a diverse spectrum of reporting, database, and web development applications, underpinned by an exceptional grasp of data storage and virtualization technologies. His proficiency in application testing, database administration, and data cleansing ensures seamless execution of complex projects.
What sets Denis apart is his comprehensive understanding of Business and Systems Analysis technologies, honed through involvement in all phases of the Software Development Lifecycle (SDLC). From meticulous requirements gathering to precise analysis, innovative design, rigorous development, thorough testing, and successful implementation, he has consistently delivered exceptional results.
Throughout his career, he has taken on multifaceted roles, from leading technical project management teams to owning solutions that drive operational excellence. His conscientious and proactive approach is unwavering, whether he is working independently or collaboratively within a team. His ability to connect with colleagues on a personal level underscores his commitment to fostering a harmonious and productive workplace environment.
Date: May 29, 2024
Tags: Information Security, ISO/IEC 27001, ISO/IEC 42001, Artificial Intelligence, GDPR
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Training: ISO/IEC 27001 Information Security Management System - EN | PECB
ISO/IEC 42001 Artificial Intelligence Management System - EN | PECB
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Walmart Business+ and Spark Good for Nonprofits.pdfTechSoup
"Learn about all the ways Walmart supports nonprofit organizations.
You will hear from Liz Willett, the Head of Nonprofits, and hear about what Walmart is doing to help nonprofits, including Walmart Business and Spark Good. Walmart Business+ is a new offer for nonprofits that offers discounts and also streamlines nonprofits order and expense tracking, saving time and money.
The webinar may also give some examples on how nonprofits can best leverage Walmart Business+.
The event will cover the following::
Walmart Business + (https://business.walmart.com/plus) is a new shopping experience for nonprofits, schools, and local business customers that connects an exclusive online shopping experience to stores. Benefits include free delivery and shipping, a 'Spend Analytics” feature, special discounts, deals and tax-exempt shopping.
Special TechSoup offer for a free 180 days membership, and up to $150 in discounts on eligible orders.
Spark Good (walmart.com/sparkgood) is a charitable platform that enables nonprofits to receive donations directly from customers and associates.
Answers about how you can do more with Walmart!"
How to Add Chatter in the odoo 17 ERP ModuleCeline George
In Odoo, the chatter is like a chat tool that helps you work together on records. You can leave notes and track things, making it easier to talk with your team and partners. Inside chatter, all communication history, activity, and changes will be displayed.
Strategies for Effective Upskilling is a presentation by Chinwendu Peace in a Your Skill Boost Masterclass organisation by the Excellence Foundation for South Sudan on 08th and 09th June 2024 from 1 PM to 3 PM on each day.
Chapter wise All Notes of First year Basic Civil Engineering.pptxDenish Jangid
Chapter wise All Notes of First year Basic Civil Engineering
Syllabus
Chapter-1
Introduction to objective, scope and outcome the subject
Chapter 2
Introduction: Scope and Specialization of Civil Engineering, Role of civil Engineer in Society, Impact of infrastructural development on economy of country.
Chapter 3
Surveying: Object Principles & Types of Surveying; Site Plans, Plans & Maps; Scales & Unit of different Measurements.
Linear Measurements: Instruments used. Linear Measurement by Tape, Ranging out Survey Lines and overcoming Obstructions; Measurements on sloping ground; Tape corrections, conventional symbols. Angular Measurements: Instruments used; Introduction to Compass Surveying, Bearings and Longitude & Latitude of a Line, Introduction to total station.
Levelling: Instrument used Object of levelling, Methods of levelling in brief, and Contour maps.
Chapter 4
Buildings: Selection of site for Buildings, Layout of Building Plan, Types of buildings, Plinth area, carpet area, floor space index, Introduction to building byelaws, concept of sun light & ventilation. Components of Buildings & their functions, Basic concept of R.C.C., Introduction to types of foundation
Chapter 5
Transportation: Introduction to Transportation Engineering; Traffic and Road Safety: Types and Characteristics of Various Modes of Transportation; Various Road Traffic Signs, Causes of Accidents and Road Safety Measures.
Chapter 6
Environmental Engineering: Environmental Pollution, Environmental Acts and Regulations, Functional Concepts of Ecology, Basics of Species, Biodiversity, Ecosystem, Hydrological Cycle; Chemical Cycles: Carbon, Nitrogen & Phosphorus; Energy Flow in Ecosystems.
Water Pollution: Water Quality standards, Introduction to Treatment & Disposal of Waste Water. Reuse and Saving of Water, Rain Water Harvesting. Solid Waste Management: Classification of Solid Waste, Collection, Transportation and Disposal of Solid. Recycling of Solid Waste: Energy Recovery, Sanitary Landfill, On-Site Sanitation. Air & Noise Pollution: Primary and Secondary air pollutants, Harmful effects of Air Pollution, Control of Air Pollution. . Noise Pollution Harmful Effects of noise pollution, control of noise pollution, Global warming & Climate Change, Ozone depletion, Greenhouse effect
Text Books:
1. Palancharmy, Basic Civil Engineering, McGraw Hill publishers.
2. Satheesh Gopi, Basic Civil Engineering, Pearson Publishers.
3. Ketki Rangwala Dalal, Essentials of Civil Engineering, Charotar Publishing House.
4. BCP, Surveying volume 1
How to Manage Your Lost Opportunities in Odoo 17 CRMCeline George
Odoo 17 CRM allows us to track why we lose sales opportunities with "Lost Reasons." This helps analyze our sales process and identify areas for improvement. Here's how to configure lost reasons in Odoo 17 CRM
it describes the bony anatomy including the femoral head , acetabulum, labrum . also discusses the capsule , ligaments . muscle that act on the hip joint and the range of motion are outlined. factors affecting hip joint stability and weight transmission through the joint are summarized.
How to Setup Warehouse & Location in Odoo 17 InventoryCeline George
In this slide, we'll explore how to set up warehouses and locations in Odoo 17 Inventory. This will help us manage our stock effectively, track inventory levels, and streamline warehouse operations.
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2015 latest IEEE electrical project list for BTech, Mtech, Phd
1. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
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ACADEMIC MATLAB SIMULATION 2013/14/15 PROJECTS FOR
ELECTRICAL AND ELECTRONICs ENGINEERING[EEE]
POWER ELECTRONICs AND DRIVES[PED]
POWER SYSTEMS[PS]….
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2. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
1 AT14-01
A Modified Three-Phase Four-Wire UPQC
Topology With Reduced DC-Link Voltage
Rating
2013-14 IEEE
2 AT14-02
FPGA-Based Predictive Sliding Mode Controller
of a Three-Phase Inverter 2013-14 IEEE
3 AT14-03
Pulsewidth Modulation of Z-Source Inverters
With Minimum Inductor Current Ripple 2014-15 IEEE
4 AT14-04
Improving the Dynamics of Virtual-Flux-Based
Control of Three-Phase Active Rectifiers 2014-15 IEEE
5 AT14-05
Sensorless Induction Motor Drive Using Indirect
Vector Controller and Sliding-Mode Observer for
Electric Vehicles
2013-14 IEEE
6 AT14-06
Back-Propagation Control Algorithm for Power
Quality Improvement Using DSTATCOM 2014-15 IEEE
7 AT14-07
A Zero-Voltage Switching Three-Phase Inverter 2014-15 IEEE
8 AT14-08
Control of Reduced-Rating Dynamic Voltage
Restorer With a Battery Energy Storage System 2014-15 IEEE
9 AT14-09
A Combination of Shunt Hybrid Power Filter
and Thyristor-Controlled Reactor for Power
Quality
2014-15 IEEE
3. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
10 AT14-10
A Transformerless Grid-Connected Photovoltaic
System Based on the Coupled Inductor Single-
Stage Boost Three-Phase Inverter
2014-15 IEEE
11 AT14-11
LCL Filter Design and Performance Analysis for
Grid-Interconnected Systems 2014-15 IEEE
12 AT14-12
An Inductively Active Filtering Method for
Power-Quality Improvement of Distribution
Networks With Nonlinear Loads
2013-14 IEEE
13 AT14-13
A Bidirectional-Switch-Based Wide-Input Range
High-Efficiency Isolated Resonant Converter for
Photovoltaic Applications
2014-15 IEEE
14 AT14-14
Analysis and Implementation of an Improved
Flyback Inverter for Photovoltaic AC Module
Applications
2014-15 IEEE
15 AT14-15
Speed Sensorless Vector Controlled Induction
Motor Drive Using Single Current Sensor 2013-14 IEEE
16 AT14-16
A Novel Design and Optimization Method of an
LCL Filter for a Shunt Active Power Filter 2014-15 IEEE
17 AT14-17
An Active Harmonic Filter Based on One-Cycle
Control 2014-15 IEEE
4. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
18 AT14-18
A Nine-Level Grid-Connected Converter
Topology for Single-Phase Transformerless PV
Systems
2014-15 IEEE
19 AT14-19
Modeling and Design of Voltage Support Control
Schemes for Three-Phase Inverters Operating
Under Unbalanced Grid Conditions
2014-15 IEEE
20 AT14-20
Cascaded Two-Level Inverter-Based Multilevel
STATCOM for High-Power Applications 2014-15 IEEE
21 AT14-21
A Voltage-Controlled DSTATCOM
for Power-Quality Improvement 2014-15 IEEE
22 AT14-22
Solar PV and Battery Storage Integration using
a New Configuration of a Three-Level NPC
Inverter With Advanced Control Strategy
2014-15 IEEE
23 AT14-23
A Current Control MPPT Method in High Power
Solar Energy Conversion System 2014-15 IEEE
24 AT14-24
A Novel Five-Level Inverter for Solar System 2014-15 IEEE
25 AT14-25
A Single-Stage Three-Phase Grid-Connected
Photo-Voltaic System With Fractional Order
MPPT
2014-15 IEEE
5. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
26 AT14-26
Design and Implementation of Sliding Mode and
PI Controllers based Control for Three Phase
Shunt Active Power Filter
2014-15 IEEE
27 AT14-27
Implementation of Adaptive Filter in Distribution
Static Compensator 2014-15 IEEE
28 AT14-28
A Comparison of Soft-Switched DC-to-DC
Converters for Electrolyzer Application 2014-15 IEEE
29 AT14-29
Adaptive fuzzy controller based MPPT for
photovoltaic systems 2014-15 IEEE
30 AT14-30
Design of Fuzzy Logic Based Maximum Power
Point Tracking Controller for Solar Array for
Cloudy Weather Conditions
2014-15 IEEE
31 AT14-31
Dynamic Behavior of DFIG Wind Turbine Under
Grid Fault Conditions 2014-15 IEEE
32 AT14-32
Fuzzy-Logic-Controller-Based SEPIC Converter
for Maximum Power Point Tracking 2014-15 IEEE
33 AT14-33
Performance Improvement of Direct Power
Control of PWM Rectifier With Simple
Calculation
2013-14 IEEE
6. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
34 AT14-34
FLC-Based DTC Scheme to Improve the
Dynamic Performance of an IM Drive 2012-13 IEEE
35 AT14-35
Single Phase Grid-Connected Photovoltaic
Inverter for Residential Application with
Maximum Power Point Tracking
2013-14 IEEE
36 AT14-36
Improved Active Power Filter Performance
for Renewable Power Generation Systems 2014-15 IEEE
37 AT14-37
Micro Wind Power Generator with Battery
Energy Storage for Critical Load 2012-13 IEEE
7. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
1 AT01
An Integrated Boost Resonant Converter for
Photovoltaic Applications
2013-14 IEEE
2 AT02
Bridgeless SEPIC Converter With a Ripple-Free
Input Current
2013-14 IEEE
3 AT03
An Advanced Power Electronics Interface for
Electric Vehicles Applications
2013-14 IEEE
4 AT04
A High-Efficiency Solar Array Simulator
Implemented by an LLC Resonant DC–DC
Converter
2013-14 IEEE
5 AT05
A Novel Reduced Switching Loss Bidirectional
AC/DC Converter PWM Strategy with Feed-
Forward Control for Grid-Tied Micro Grid
Systems
2013-14 IEEE
6 AT06
Coordinated Control and Energy Management of
Distributed Generation Inverters in a Microgrid
2013-14 IEEE
7 AT07
A New ZVS DC/DC Converter With Three
APWM Circuits
2013-14 IEEE
8 AT08
Analysis and Implementation of a Single Stage
Flyback PV-Micro Inverter with Soft Switching
2013-14 IEEE
9 AT09
A Bridgeless Boost Rectifier for Low-Voltage
Energy Harvesting Applications
2013-14 IEEE
8. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
10 AT10
A 1.65 W Fully Integrated 90 nm Bulk CMOS
Capacitive DC–DC Converter With Intrinsic
Charge Recycling
2013-14 IEEE
11 AT11
A Comparison of Soft-Switched DC-to-DC
Converters for Electrolyzer Application
2013-14 IEEE
12 AT12
Control Strategy for Power Flow Management in
a PV System Supplying DC Loads
2013-14 IEEE
13 AT13
A High Step-Up Three-Port DC–DC Converter
for Stand-Alone PV/Battery Power Systems
2013-14 IEEE
14 AT14
Decoupling Capacitor Selection in DCM Flyback
PV Micro-inverters Considering Harmonic
Distortion
2013-14 IEEE
15 AT15
Design and Performance of a Bidirectional
Isolated DC–DC Converter for a Battery Energy
Storage System
2013-14 IEEE
16 AT16
Double-port Interface for Small Scale Renewable
Sources Integration
2013-14 IEEE
17 AT17
High Reliability and Efficiency Single-Phase
Transformerless Inverter for Grid-Connected
Photovoltaic Systems
2013-14 IEEE
18 AT18
Multilevel SVPWM With DC-Link Capacitor
Voltage Balancing Control for Diode-Clamped
Multilevel Converter Based STATCOM
2013-14 IEEE
9. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
19 AT19
High Voltage-Boosting Converters Based on
Bootstrap Capacitors and Boost Inductors
2013-14 IEEE
20 AT20
High-Efficiency Single-Input Multiple-Output DC–
DC Converter
2013-14 IEEE
21 AT21
Nonlinear Current Control for Power Electronic
Converters: IC Design Aspects and Implementation
2013-14 IEEE
22 AT22
Improved Trans-Z-Source Inverter With Continuous
Input Current and Boost Inversion Capability
2013-14 IEEE
23 AT23 Integrated Full-Bridge-Forward DC–DC Converter
for a Residential Microgrid Application
2013-14 IEEE
24 AT24
Modular Multilevel Inverter with New Modulation
Method and Its Application to Photovoltaic Grid-
Connected Generator
2013-14 IEEE
25 AT25
Microfabricated V-Groove Power Inductors Using
Multilayer Co–Zr–O Thin Films for Very-High-
Frequency DC–DC Converters
2013-14 IEEE
26 AT26 Reconfigurable Solar Converter: A Single-Stage
Power Conversion PV-Battery System
2013-14 IEEE
27 AT27
Integration and Operation of a Single-Phase
Bidirectional Inverter With Two Buck/Boost
MPPTs for DC-Distribution Applications
2013-14 IEEE
10. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
28 AT28 Module-Level DC/DC Conversion for Photovoltaic
Systems: The Delta-Conversion Concept
2013-14 IEEE
29 AT29
High Boost Ratio Hybrid Transformer DC–DC
Converter for Photovoltaic Module Applications
2013-14 IEEE
30 AT30
Performance Investigation of Isolated Wind–Diesel
Hybrid Power Systems With WECS Having PMIG
2013-14 IEEE
31 AT31
High-Efficiency Digital-Controlled Interleaved
Power Converter for High-Power PEM Fuel-Cell
Applications
2013-14 IEEE
32 AT32
Pulsewidth-Modulated Dual - Half- Controlled
Converter
2013-14 IEEE
33 AT33
PWM Plus Phase Angle Shift (PPAS) Control
Scheme for Combined Multiport DC/DC Converters
2013-14 IEEE
34 AT34
Mitigation of Lower Order Harmonics in a Grid-
Connected Single-Phase PV Inverter
2013-14 IEEE
35 AT35
Soft-Switching DC/DC Converter With a Full ZVS
Range and Reduced Output Filter for High-Voltage
Applications
2013-14 IEEE
36 AT36
Space-Vector PWM Control Synthesis for an H-
Bridge Drive in Electric Vehicles
2013-14 IEEE
11. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
37 AT37
StatCom Control at Wind Farms With Fixed-Speed
Induction Generators Under Asymmetrical Grid
Faults
2013-14 IEEE
38 AT38
A High-Efficiency Wide-Input-Voltage Range
Switched Capacitor Point-of-Load DC–DC
Converter
2013-14 IEEE
39 AT39
Simulation Analysis of SVPWM Inverter Fed
Induction Motor Drives
2013-14 IJETEE
40 AT40
Research on Three-phase Voltage Type PWM
Rectifier System Based on SVPWM Control
2013-14 MAXWELL
41 AT41 A ZVS Grid-Connected Three-Phase Inverter 2012-13 IEEE
42 AT42
Dynamic Modeling of Microgrid for Grid Connected
and Intentional Islanding Operation
2012-13 IEEE
43 AT43
High-Step-Up and High-Efficiency Fuel-Cell Power-
Generation System With Active-Clamp
Flyback–Forward Converter
2012-13 IEEE
44 AT44
Direct Power Control of Series Converter of Unified
Power-Flow Controller With Three-Level
Neutral Point Clamped Converter
2012-13 IEEE
45 AT45
Analysis Of Discrete & Space Vector Pwm
Controlled Hybrid Active Filters For Power Quality
Enhancement
2012-13 IJAET
12. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
46 AT46
Matlab -based Simulation & Analysis of Three-level
SPWM Inverter
2012-13 IJSCE
47 AT47
Design and Simulation of three phase Inverter for
grid connected Photovoltic systems
2012-13 NCNTE
48 AT48
Comparison of Controllers for Power Quality
Improvement Employing Shunt Active Filter
2012-13 ICCEET
49 AT49
Comparison of Control Algorithms for Shunt
Active Filter for Harmonic Mitigation
2012-13 IJERT
50 AT50
Comparison of Controllers for Power Quality
Improvement Employing Shunt Active Filter
2012-13 ICCEET
51 AT51
Compensation Of Sags And Swells Voltage Using
Dynamic Voltage Restorer (Dvr) During Single Line
To Ground And Tree-Phase Faults
2012-13 IJTPE
52 AT52
Simulation and Analysis of Zero Voltage Switching
PWM Full Bridge Converter 2012-13 IJERT
53 AT53
Direct Torque Control Based on Space Vector
Modulation with Adaptive Stator Flux Observer for
Induction Motors
2012-13 IJERA
54 AT54
Diode Clamped Three Level Inverter Using
Sinusoidal PWM
2012-13 ICCSNT
13. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
55 AT55
Direct Active and Reactive Power Regulation of
Grid-Connected DC/AC Converters Using Sliding
Mode Control Approach
2011-12 IEEE
56 AT56
Control for Grid-Connected and Intentional
Islanding Operations of Distributed Power
Generation
2011-12 IEEE
57 AT57
Power System Stability Enhancement Using Static
Synchronous Series Compensator (SSSC)
2011-12 IEEE
58 AT58
Power Quality and Power Interruption Enhancement
by Universal Power Quality
Conditioning System with Storage Device
2011-12 AJBAS
59 AT59
Z-Source Inverter With A New Space Vector Pwm
Algorithm For High Voltage Gain
2011-12 ARPN
60 AT60 Wind Farm to Weak-Grid Connection using UPQC
Custom Power Device
2010-11 IEEE
61 AT61
Enhancement of Power Quality in Distribution
System Using D-STATCOM
2010-11 IEEE
62 AT62
A STATCOM-Control Scheme for Grid Connected
Wind Energy System for Power Quality
Improvement
2010-11 IEEE
63 AT63
Single-Phase to Three-Phase Drive System Using
Two Parallel Single-Phase Rectifiers
2010-11 IEEE
14. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
64 AT64
Simulation a Shunt Active Power Filter using
MATLAB/Simulink
2010-11 IEEE
65 AT65
Single-Phase to Three-Phase Drive System Using
Two Parallel Single-Phase Rectifiers
2010-11 IEEE
66 AT66
A Single-Phase Z-Source Buck–Boost Matrix
Converter
2010-11 IEEE
67 AT67 Space Vectors Modulation for Nine-Switch
Converters
2010-11 IEEE
68 AT68
Design of a Hybrid PID Plus Fuzzy Controller for
Speed Control of Induction Motors
2010-11 IEEE
69 AT69
Novel Direct Torque Control Based on Space
Vector Modulation With Adaptive Stator Flux
Observer for Induction Motors
2010-11 IEEE
70 AT70
High-Efficiency Voltage Regulator for Rural
Networks 2010-11 IEEE
71 AT71
A Non-Insulated Step-Up/Down DC-DC Converter
with Wide Range Conversion
2010-11 ACTA
72 AT72
STATCOM for Improved Dynamic Performance of
Wind Farms in Power Grid
2010-11 MEPCON
73 AT73
Control Strategy for Three Phase Voltage Source
PWM Rectifier based on the SVM 2010-11 EFEEA
15. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
74 AT74
Simulation And Comparison Of Spwm And
Svpwm Control For Three Phase Inverter
2010-11 ARPN
75 AT75
Natural Harmonic Elimination of Square-Wave
Inverter for Medium-Voltage Application
2009-10 IEEE
76 AT76
Multiconverter Unified Power-Quality Conditioning
System: MC-UPQC 2009-10 IEEE
77 AT77
Improved Z-Source Inverter With Reduced Z-
Source Capacitor Voltage Stress and Soft-Start
Capability
2009-10 IEEE
78 AT78
Multilevel Multiphase Space Vector PWM
Algorithm With Switching State Redundancy
2009-10 IEEE
79 AT79
Single-Stage Flyback Power-Factor-Correction
Front-End for HB LED Application
2009-10 IEEE
80 AT80
Modeling and Simulating for Transient Stability
Analysis of Power System using Dynamic Phasor
2009-10 ICISE
81 AT81
Study on Speed Sensorless SVM-DTC System of
PMSM
2009-10 ICEMI
82 AT82
Soft Computing Techniques for the Control of an
Active Power Filter
2009-10 IEEE
16. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
83 AT83
A Versatile Control Scheme for a Dynamic Voltage
Restorer for Power-Quality Improvement
2009-10 IEEE
84 AT84
Bidirectional Switch Commutation for a Matrix
Converter Supplying a Series Resonant Load
2009-10 IEEE
85 AT85
Improving the Dynamic Performance of Wind
Farms With STATCOM
2009-10 IEEE
86 AT86
A Modular Fuel Cell, Modular DC–DC Converter
Concept for High Performance and Enhanced
Reliability
2009-10 IEEE
87 AT87
A Three-Level Full-Bridge Zero-Voltage Zero-
Current Switching Converter With a Simplified
Switching Scheme
2009-10 IEEE
88 AT88
A Non-Insulated Step-Up/Down DC-DC Converter
with Wide Range Conversion
2009-10 IEEE
89 AT89
A Novel Three-Phase Three-Leg AC/AC Converter
Using Nine IGBTs
2009-10 IEEE
90 AT90
Fuzzy Load Controller for Wind Energy
Conversion System
2009-10 NCSCT
91 AT91
Study on Speed Sensorless SVM-DTC System of
PMSM
2009-10 ICEMI
17. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
92 AT92
Direct Torque Control of Induction Motors with
Fuzzy Minimization Torque Ripple
2009-10 WCECS
93 AT93
PMSM Speed Sensorless Direct Torque Control
Based on EKF
2009-10 ICIEA
94 AT94
A Novel Zero-Voltage-Switching PWM Full Bridge
Converter 2008-09 IEEE
95 AT95
System Simulation of 3-phase PWM Rectifier Based
on Novel Voltage Space Vector
2008-09 IEEE
96 AT96
Simulation of Three Phase Voltage based PWM
Rectifier Based on the Space Vector Modulation
2008-09 IEEE
97 AT97
Fundamental Frequency Modulated Multilevel
Inverter for Three-Phase Stand-Alone
Photovoltaic Application
2008-09 IEEE
98 AT98
Synthesis of Multilevel Converters Based on
Singleand / or Three-Phase Converter Building
Blocks
2008-09 IEEE
99 AT99
Synthesis of Multilevel Converters Based on
Singleand/ or Three-Phase Converter Building
Blocks
2008-09 IEEE
100 AT100
Quasi Current Mode Control for the Phase-Shifted
BSeries Resonant Converter
2008-09 IEEE
18. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
101 AT101
Control for Grid-Connected and Intentional Islanding
Operations of Distributed Power Generation
2008-09 IETE
102 AT102
Simulink Model of Direct Torque Control of
Induction Machine 2008-09 IEEE
103 AT103
Elimination of Harmonics in a Five-Level Diode-
Clamped Multilevel Inverter Using Fundamental
Modulation
2007-08 IEEE
104 AT104 Current-Fed Dual-Bridge DC–DC Converter 2007-08 IEEE
105 AT105
A Novel Nine-Switch Inverter for Independent
Control of Two Three-phase Loads
2007-08 IEEE
106 AT106
Enhancement of Voltage Quality in Isolated Power
Systems
2007-08 IEEE
107 AT107
An Improved Power-Quality 30-Pulse AC–DC for
Varying Loads
2007-08 IEEE
108 AT108 Current-Fed Dual-Bridge DC–DC Converter 2007-08 IEEE
109 AT109
Analysis and Design Considerations of Zero-Voltage
and Zero-Current-Switching (ZVZCS) Full-Bridge
PWM Converters
110 AT110
Wind Farm to Weak-Grid Connection using UPQC
Custom Power Device
19. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
111 AT111 A Novel Control Method for Shunt Active Power
Filters Using SVPWM
2004-05 IAS
112 AT112
Modeling And Simulation For Voltage Sags/Swells
Mitigation Using Dynamic Voltage Restorer (Dvr)
2005-09 JATIT
113 AT113 Matrix Converters: A Technology Review 2002-03 IEEE
114 AT114
Simulation Analysis of SVPWM Inverter Fed
Induction Motor Drives
2013-14 IJETEE
115 AT115
A Three-Phase Three-Leg AC/AC Converter
Using Nine Igbts
116 AT116
Simulation And Experimental Based Four Switch
Three Phase Inverter Fed Induction Motor Drive 2013-14 WJMS
117 AT117
Performance Of A 4- Switch, 3-Phase Inverter
Fed Induction Motor (IM) Drive System
2013-14 IJAREEIE
118 AT118
Simulink/Modelsim Co-Simulation And Fpga
Realization Of Spwm Controller For Three Phase
Multilevel Inverter
2013-14 IJESS
119 AT119
A Sinusoidal Pwm Scheme For Neutral Point
Clamped Five Level Inverter
2013-14 IEEJ
120 AT120
Performance Improvement of Active Power Filter
under Distorted and Unbalanced Grid Voltage
Conditions
2013-14 EIE
20. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
121 AT121
Analysis of Cascaded Five Level Multilevel
InverterUsingHybrid PulseWidth Modulation
2013-14 IJETAE
122 AT122
Comparative Study on New COPWM Techniques
for Three Phase Cascaded Z-Source Inverter
2013-14 IJERT
123 AT123
Total Harmonic Distortion Analysis and Comparison
of Diode Clamped Multilevel Z-Source Inverter
2013-14 IJMER
124 AT124
Simulation of Inverter Fed Five Phase Induction
Motor
2013-14 IJSR
125 AT125
Simulation of Fuzzy Logic Based Shunt Hybrid
Active Filter for Power Quality Improvement
2013-14 IJISA
126 AT126
Fuzzy Based Hysteresis Current Controlled Shunt
Active Power Filter for Power Conditioning
2013-14 IJMER
127 AT127
Power Quality Enhancement Using Hybrid Active
Filter
2013-14 IJESIT
128 AT128
Three Phase to Three Phase Direct Matrix Converter
using SPWM Technique
2013-14 IJSCE
129 AT129
Comparative Study of Multicarrier PWM
Techniques for Seven Level Cascaded Z-Source
Inverter
2013-14 IJCA
130 AT130
Performance Investigation of Multi-phase VSI with
Simple PWM Switching Techniques 2013-14 IJE
21. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
131 AT131
A Novel Three-Phase Three-Leg AC/AC Converter
Using Nine IGBTS
2013-14 IJMER
132 AT132
Overview of Single Phase Matrix Converter
Application
2013-14
133 AT133
Performance Evaluation of Multicarrier SPWM
Strategies for Three Phase Z - source Seven Level
Diode Clamped Inverter
2013-14 IJETT
134 AT134
High-Gain Switched-Inductor Switched-Capacitor
Step-Up DC-DC Converter
2013-14 IMECS
135 AT135
Sinusoidal and Space Vector Pulse Width
Modulation for Inverter 2013-14 IJETT
136 AT136
Simulation Of A Space Vector Pwm Controller For A
Three-Level Voltage-Fed Inverter Motor Drive
2013-14 IJATCSE
137 AT137
Three Level Inverter To Improve Performance Of
Induction Motor Drives Using MATLAB
2013-14 IJAEST
138 AT138
Three Phase To Three Phase Direct Matrix Converter
Using SPWM Technique
2013-14 IJSCE
139 AT139
Performance Analysis of Three Phase PWM
Voltage Source Inverter Fed Three Phase
Induction Motor Drive
2013-14
140 AT140
Simulation & Performance Analysis of Two Level
AC-DC-AC Converter with IM
2013-14 IJSCE
22. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
141 AT141
Switched Inductor Z-Source Matrix Converter
Operation and Analysis
2013-14 WASJ
142 AT142
Performance Evaluation of Multicarrier SPWM
Strategies for Three Phase Z - source Seven Level
Diode Clamped Inverter
2013-14 IJETT
143 AT143
Comparison of MLI and Z-Source Inverter for
Transformerless Operation of Single-Phase
Photovoltaic Systems
2010-11 TIJST
144 AT144
Novel Direct Torque Control Based on Space Vector
Modulation With Adaptive Stator Flux Observer for
Induction Motors
2010-11 IEEE
145 AT145
Performance Analysis of Multilevel Inverters
Using Variable Switching Frequency Carrier Based
PWM Techniques
2012-13 ICREPQ
146 AT146
Direct Torque Control Based on Space Vector
Modulation with Adaptive Stator Flux Observer for
Induction Motors
2012-13 IJERA
147 AT147
The Grid-connected Inverter of Simulation on Direct-
drive Wind Power System Based on MATLAB
2012-13 ICCIA
148 AT148
Z-Source Multilevel Inverter for Uninterruptible
Power Supply Application
2012-13 BIJPSIC
149 AT149
Simulation of Three-Phase Inverter Using Minimum
Number of Controlled Switches 2013-14 EIJ
23. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
150 AT150
Improvement of power quality by using active filter
based on vectorial power theory control strategy on
the MATLAB-Simulink platform
IOSR
151 AT151
Reduction of THD in Diode Clamped Multilevel
Inverter employing spwm technique
2013-14 IJSR
152 AT152
Applications of DSTATCOM Using MATLAB
/Simulation in Power System
IJEIR
153 AT153
Design and Simulation of DSTATCOM for Power
Quality Enhancement in Distribution Networks
under Various Fault Condition
2013-14 IJETAE
154 AT154 By Dynamic Voltage Restorerfor Power Quality
Improvement
2013-14 IJECS
155 AT155
Modeling And Simulation Of Dynamic Voltage
Restorer (Dvr) For Voltage Sags/Swells Mitigation
2013-14 IJARSE
156 AT156
Modelling and Simulation of Dynamic Voltage
Restorer for Power Quality Improvement 2013-14 IJSER
157 AT157 Fuzzy Based Hysteresis Current Controlled Shunt
Active Power Filter for Power Conditioning
2013-14 IJMER
158 AT158
Space Vector Modulation Controlled Hybrid Active
Power Filter for Power Conditioning
2013-14 IJETEE
159 AT159
Simulation of Multipulse Converter for Harmonic
Reduction using Controlled Rectifier
2013-14 IJSR
24. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
160 AT160
Simulation of Multipulse Converter for Harmonic
Reduction using Controlled Rectifier
2013-14 IJSR
161 AT161
A Novel Control of Two AC Loads using Nine
Switch Inverter
2012-13 ICCCE
162 AT162
Comparative Study between Different Control
Strategies for Shunt Active Power Filter
2013-14 PESA
163 AT163
Series Connected Forward Flyback Convertor For
High Step Up Power Conversion
2012-13 IJEAT
164 AT164
Analysis Of Discrete & Space Vector Pwm
Controlled Hybrid Active Filters For Power
Quality Enhancement
2012-13 IJAET
165 AT165
Mitigation Of Harmonics By Hysteresis Control
Technique Of VSI Based Statcom
2013-14 IJLTET
166 AT166
Application Of STATCOM To Increase Transient
Stability Of Wind Farm
2013-14 AJEPES
167 AT167
A Single-Phase Grid-Connected Fuel Cell System
Based on a Boost-Inverter
2013-14 IEEE
168 AT168
Adaptive Step Size With Adaptive-Perturbation-
Frequency Digital MPPT Controller for a
Single-Sensor Photovoltaic Solar System
2013-14 IEEE
25. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
169 AT169
An Energy-Efficient Motor Drive With Autonomous
Power Regenerative Control System Based on
Cascaded Multilevel Inverters and Segmented Energy
Storage
2013-14 IEEE
170 AT170
An Improved Three-Phase Variable-Band Hysteresis
Current Regulator
2013-14 IEEE
171 AT171
Design and Implementation of Energy Management
System With Fuzzy Control for DC Microgrid
Systems
2013-14 IEEE
172 AT172
Design, Analysis, and Implementation of Solar
Power Optimizer for DC Distribution System
2013-14 IEEE
173 AT173
Modeling and Simulation of All-Electric Ships With
Low-Voltage DC Hybrid Power Systems
2013-14 IEEE
174 AT174
Reactive Power Control of Permanent-Magnet
Synchronous Wind Generator With Matrix Converter
2013-14 IEEE
175 AT175
Improved Transformerless Inverter With Common-
Mode Leakage Current Elimination for a
Photovoltaic Grid-Connected Power System
2012-13 IEEE
176 AT176
A Carrier-Based PWM Strategy With the Offset
Voltage Injection for Single-Phase Three-Level
Neutral-Point-Clamped Converters
2013-14 IEEE
177 AT177
A ZVS-PWM Three-Phase Current-Fed Push–Pull
DC–DC Converter
2013-14 IEEE
26. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
178 AT178
Adaptive MPPT Applied to Variable-Speed
Microhydropower Plant
2013-14 IEEE
179 AT179
Analysis, Modeling, and Implementation of a
Multidevice Interleaved DC/DC Converter for Fuel
Cell Hybrid Electric Vehicles
2013-14 IEEE
180 AT180
Control Strategy for Power Flow Management in a
PV System Supplying DC Loads
2013-14 IEEE
181 AT181
Coordinated Control of Cascaded Current-Source
Converter Based Offshore Wind Farm
2013-14 IEEE
182 AT182
DC-Bus Design and Control for a Single-Phase
Grid-Connected Renewable Converter With a Small
Energy Storage Component
2013-14 IEEE
183 AT183
Digital-Controlled Single-Phase Transformer-Based
Inverter for Non-Linear Load Applications
2013-14 IEEE
184 AT184
Dual Transformerless Single-Stage Current Source
Inverter With Energy Management Control Strategy
2013-14 IEEE
185 AT185
FPGA-Based Predictive Sliding Mode Controller
of a Three-Phase Inverter
2013-14 IEEE
186 AT186
Half-Wave Cycloconverter-Based Photovoltaic
Microinverter Topology With Phase-Shift
Power Modulation
2013-14 IEEE
27. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
187 AT187
High-Performance Control of a DC–DC Z-Source
Converter Used for an Excitation Field Driver
2012-13 IEEE
188 AT188
Improved Transformerless Inverter With
Common-Mode Leakage Current Elimination for
a Photovoltaic Grid-Connected Power System
2012-13 IEEE
189 AT189
Reactive Power Control of Permanent-Magnet
Synchronous Wind Generator With Matrix Converter
2013-14 IEEE
190 AT190
Sensorless Control of CSC-Fed IPM Machine for
Zero- and Low-Speed Operations Using Pulsating
HFI Method
2013-14 IEEE
191 AT191
A Bridgeless Boost Rectifier for Low-Voltage
Energy Harvesting Applications
2013-14 IEEE
192 AT192
A Current Controller Design for Current Source
Inverter-Fed AC Machine Drive System
2013-14 IEEE
193 AT193
A Family of Three-Switch Three-State Single-Phase
Z-Source Inverters
2013-14 IEEE
194 AT194
A High Step-Down Transformerless Single-Stage
Single-Switch AC/DC Converter
2013-14 IEEE
195 AT195
A High-Performance SPWM Controller for Three-
Phase UPS Systems Operating Under Highly
Nonlinear Loads
2013-14 IEEE
28. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
196 AT196
A New DC Anti-Islanding Technique of Electrolytic
Capacitor-Less Photovoltaic Interface in DC
Distribution Systems
2013-14 IEEE
197 AT197
A Single-Phase Grid-Connected Fuel Cell System
Based on a Boost-Inverter
2013-14 IEEE
198 AT198
A Three-Level Converter With Reduced Filter Size
Using Two Transformers and Flying Capacitors
2013-14 IEEE
199 AT199
Adaptive Dead-Time Compensation for Grid-
Connected PWM Inverters of Single-Stage PV
Systems
2013-14 IEEE
200 AT200
Performance Analysis of Three-Phase Three-Leg
AC/AC Converter using SPWM and SVPWM
2013-14 IJESE
201 AT201
An Improved Buck PFC Converter With High
Power Factor
2013-14 IEEE
202 AT202
An Improved Soft-Switching Buck Converter With
Coupled Inductor
2013-14 IEEE
203 AT203
Analysis and Comparison of Medium Voltage High
Power DC/DC Converters for Offshore Wind Energy
Systems
2013-14 IEEE
204 AT204 Analysis and Design of a Push–Pull Quasi-Resonant
Boost Power Factor Corrector
2013-14 IEEE
29. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
205 AT205
Asymmetric Control of DC-Link Voltages for
Separate MPPTs in Three-Level Inverters
2013-14 IEEE
206 AT206
Bridgeless SEPIC Converter With a Ripple-Free
Input Current
2013-14 IEEE
207 AT207 Cascaded Multicell Trans-Z-Source Inverters 2013-14 IEEE
208 AT208
Control of Improved Full-Bridge Three-Level
DC/DC Converter for Wind Turbines in a DC Grid
2013-14 IEEE
209 AT209
DC-Voltage Fluctuation Elimination Through a DC-
Capacitor Current Control for DFIG Converters
Under Unbalanced Grid Voltage Conditions
2013-14 IEEE
210 AT210
Design and Implementation of Energy Management
System With Fuzzy Control for DC Microgrid
Systems
2013-14 IEEE
211 AT211
Design of High-Performance Stand-Alone and
Grid-Connected Inverter for Distributed Generation
Applications
2013-14 IEEE
212 AT212
Design, Analysis, and Implementation of Solar
Power Optimizer for DC Distribution System
2013-14 IEEE
213 AT213
Enhanced Control of a DFIG-Based Wind-Power
Generation System With Series Grid-Side Converter
Under Unbalanced Grid Voltage Conditions
2013-14 IEEE
30. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
214 AT214
Grid Interfacing of Multimegawatt Photovoltaic
Inverters
2013-14 IEEE
215 AT215
High Power Factor AC–DC LED Driver
With Film Capacitors
2013-14 IEEE
216 AT216
High-Efficiency Isolated Bidirectional AC–DC
Converter for a DC Distribution System
2013-14 IEEE
217 AT217
High-Efficiency Single-Input Multiple-Output
DC–DC Converter
2013-14 IEEE
218 AT218
Improved Sensorless Operation of a CSI-Based
Induction Motor Drive: Long Feeder Case
2013-14 IEEE
219 AT219
Integration and Operation of a Single-Phase
Bidirectional Inverter With Two Buck/Boost MPPTs
for DC-Distribution Applications
2013-14 IEEE
220 AT220
Modeling and Simulation of All-Electric Ships With
Low-Voltage DC Hybrid Power Systems
2013-14 IEEE
221 AT221
Multilevel DC-Link Inverter and Control Algorithm
to Overcome the PV Partial Shading
2013-14 IEEE
222 AT222
Nonlinear Behavior and Instability in a Three-Phase
Boost Rectifier Connected to a Nonideal Power Grid
With an Interacting Load
2013-14 IEEE
31. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
223 AT223
Perturbation On-Time (POT) Technique in Power
Factor Correction (PFC) Controller for Low Total
Harmonic Distortion and High Power Factor
2013-14 IEEE
224 AT224
Problems Incurred in a Vector-Controlled Single-
Phase Induction Motor, and a Proposal for a Vector-
Controlled Two-Phase Induction Motor as a
Replacement
2013-14 IEEE
225 AT225
Soft-Switching DC/DC Converter With a Full ZVS
Range and Reduced Output Filter for High-Voltage
Applications
2013-14 IEEE
226 AT226
Space-Vector-Modulated Three-Level Inverters
With a Single Z-Source Network
2013-14 IEEE
227 AT227
Synchronous-Reference-Frame-Based Control of
Switched Boost Inverter for Standalone DC
Nano grid Applications
2013-14 IEEE
228 AT228
Advanced Symmetrical Voltage Quadrupler
Rectifiers for High Step-Up and High Output-
Voltage Converters
2013-14 IEEE
229 AT229
An Advanced Current Control Strategy for
Three-Phase Shunt Active Power Filters
2013-14 IEEE
230 AT230
A Modular Fuel Cell, Modular DC–DC Converter
Concept for High Performance and Enhanced
Reliability
2009-10 IEEE
32. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
231 AT231
Cascaded Current–Voltage Control to Improve the
Power Quality for a Grid-Connected Inverter With a
Local Load
2013-14 IEEE
232 AT232
Reconfigurable Solar Converter: A Single-Stage
Power Conversion PV-Battery System
2013-14 IEEE
233 AT233
Wind Farm to Weak-Grid Connection using UPQC
Custom Power Device
2013-14 IEEE
234 AT234
Power Quality Improvement and Mitigation Case
Study Using Distributed Power Flow Controller
2012-13 IEEE
235 AT235
Fault Ride-Through of a DFIG Wind Turbine Using a
Dynamic Voltage Restorer During Symmetrical and
Asymmetrical Grid Faults
2011-12 IEEE
236 AT236
Direct Power Control of Series Converter of Unified
Power-Flow Controller With Three-Level Neutral
Point Clamped Converter
2012-13 IEEE
237 AT237
Multiconverter Unified Power-Quality Conditioning
System: MC-UPQC
2009-10 IEEE
238 AT238
A Novel Online Fuzzy Control Method of Static
VAR Compensation for an Effective Reactive Power
Control of Transmission Lines
2010-12 IEEE
33. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
239 AT239
Control of Parallel Multiple Converters for Direct-
Drive Permanent-Magnet Wind Power Generation
Systems
2012-13 IEEE
240 AT240
Dynamic Modeling and Simulation of Hybrid Power
Systems Based on Renewable Energy
2009-10 IEEE
241 AT241
Single-Stage Power-Factor-Correction Circuit with
Flyback Converter to Drive LEDs for Lighting
Applications
2010-11 IEEE
242 AT242
A 24-Pulse AC-DC Converter Employing a pulse
doubling technique for Vector-Controlled Induction
Motor Drives
2008-09 IETE
243 AT243
A Variable-Speed, Sensorless, Induction Motor Drive
Using DC Link Measurements
2009-10 IEEE
244 AT244
Modeling and Simulation of a Distribution
STATCOM (D-STATCOM) for Power Quality
Problems-Voltage Sag and Swell Based on
Sinusoidal Pulse Width Modulation (SPWM)
2012-13 IEEE
245 AT245
Seven-Level Shunt Active Power Filter for High-
Power Drive Systems
2009-10 IEEE
246 AT246
Integration and Operation of a Single-Phase
Bidirectional Inverter With Two Buck/Boost MPPTs
for DC-Distribution Applications
2013-14 IEEE
34. ELECTRICAL PROJECTS USING MATLAB/SIMULINK
asokatechnologies@gmail.com
S NO CODE PROJECT TITLE YEAR JOURNAL
247 AT247
A FACTS Device: Distributed Power-Flow
Controller (DPFC)
2010-11 IEEE
248 AT248
High Performance of Space Vector Modulation
Direct Torque Control SVM-DTC Based on
Amplitude Voltage and Stator Flux Angle
20013-12 RJASET
249 AT249 Electric Springs—A New Smart Grid Technology 2012-13 IEEE
250 AT250
Performance of the Speed Sensorless Induction
Motor Drive for Traction Application with MRAS
type Speed and Flux Estimator
2012-13 IEEE
251 AT251
Power-Management Strategies for a Grid-Connected
PV-FC Hybrid System
2010-11 IEEE
252 AT252
Voltage unbalance and harmonics compensation for
islanded microgrid inverters
2013-14 IET