hot research topics in electrical engineering

Interesting
Scholarships
UGC-CARE Journals

1. Power Systems and Renewable Energy

1.1 smart grids and micro-grids.

a. Distributed control strategies for micro-grid management.

b. Blockchain applications for secure energy transactions in smart grids.

c. Resilience and robustness enhancement in smart grid systems against cyber threats.

d. Integration of renewable energy sources in micro-grids.

e. AI-based predictive maintenance for smart grid components.

1.2 Energy Harvesting and Storage

a. Next-gen battery technologies for energy storage systems.

b. Wireless power transfer and energy harvesting for IoT devices.

c. Super-capacitors and their applications in renewable energy storage.

d. Materials research for efficient energy conversion and storage.

e. Energy-efficient architectures for IoT devices powered by energy harvesting.

1.3 Electric Vehicles and Transportation

a. Charging infrastructure optimization for electric vehicles.

b. Vehicle-to-grid (V2G) technology and bidirectional power flow.

c. Lightweight materials and design for electric vehicle batteries.

d. Autonomous electric vehicle technology and its integration into smart cities.

e. Energy-efficient route planning algorithms for electric vehicles.

2. Communications and Networking

2.1 5g and beyond.

a. AI-driven optimization for 5G network deployment.

b. mmWave communication technologies and their implications.

c. Quantum communication for secure and high-speed data transfer.

d. 6G technology and its potential applications.

e. Edge computing and its role in 5G networks.

2.2 IoT and Wireless Sensor Networks

a. Energy-efficient protocols for IoT devices.

b. AI-enabled edge computing for IoT applications.

c. Security and privacy in IoT data transmission.

d. Integration of AI with IoT for intelligent decision-making.

e. Communication challenges in massive IoT deployment.

2.3 Satellite and Space Communications

a. Low Earth Orbit (LEO) satellite constellations for global connectivity.

b. Inter-satellite communication for improved space exploration.

c. Secure communication protocols for space-based systems.

d. Quantum communication for secure space-based networks.

e. Space debris mitigation and communication systems.

3. Control Systems and Robotics

3.1 autonomous systems.

a. AI-driven control for autonomous vehicles and drones.

b. Swarm robotics and their applications in various industries.

c. Human-robot collaboration in industrial settings.

d. Autonomous navigation systems for underwater vehicles.

e. Control strategies for multi-agent systems.

3.2 Biomedical and Healthcare Robotics

a. Robotics in surgical procedures and rehabilitation.

b. Wearable robotics for physical assistance and rehabilitation.

c. Robotic prosthetics and exoskeletons for enhanced mobility.

d. Telemedicine and remote healthcare using robotic systems.

e. Ethics and regulations in medical robotics.

3.3 Machine Learning and Control

a. Reinforcement learning for control system optimization.

b. Neural network-based adaptive control systems.

c. Explainable AI in control systems for better decision-making.

d. Control strategies for complex systems using deep learning.

e. Control system resilience against adversarial attacks.

4. Electronics and Nanotechnology

4.1 nano-electronics and quantum computing.

a. Quantum-resistant cryptography for future computing systems.

b. Development of reliable qubits for quantum computers.

c. Quantum error correction and fault-tolerant quantum computing.

d. Nano-scale transistors and their applications.

e. Hybrid quantum-classical computing architectures.

4.2 Flexible and Wearable Electronics

a. Stretchable electronics for wearable applications.

b. Smart textiles and their integration with electronic components.

c. Biocompatible electronics for healthcare monitoring.

d. Energy harvesting in wearable devices.

e. Novel materials for flexible electronic devices.

4.3 Neuromorphic Engineering and Brain-Computer Interfaces

a. Neuromorphic computing for AI and cognitive systems.

b. Brain-inspired computing architectures and algorithms.

c. Non-invasive brain-computer interfaces for diverse applications.

d. Ethics and privacy in brain-computer interface technology.

e. Neuroprosthetics and their integration with neural interfaces.

5. Signal Processing and Machine Learning

5.1 sparse signal processing.

a. Compressive sensing for efficient data acquisition.

b. Sparse signal reconstruction algorithms.

c. Sparse representations in machine learning.

d. Deep learning for sparse signal recovery.

e. Applications of sparse signal processing in various domains.

5.2 Explainable AI and Interpretability

a. Interpretable machine learning models for critical applications.

b. Explainable deep learning for decision-making.

c. Model-agnostic interpretability techniques.

d. Human-centric AI and its interpretability.

e. Visual and intuitive explanations in machine learning models.

5.3 Adversarial Machine Learning and Security

a. Robust deep learning models against adversarial attacks.

b. Adversarial machine learning in cybersecurity.

c. Detecting and mitigating adversarial attacks in AI systems.

d. Secure and private machine learning protocols.

e. Ethical considerations in adversarial machine learning.

As technology continues to redefine boundaries and explore new horizons, these research topics in Electrical Engineering stand at the forefront, ready to shape the future of our world. The amalgamation of these fields showcases the diversity and depth of possibilities waiting to be unlocked by the curious minds and diligent efforts of researchers and engineers in the years to come.

Advanced sensors
AI Applications
AI in robotics
Autonomous vehicles
Brain-machine interfaces
Cognitive radio
Electric vehicles
Electrical engineering research
Electroceuticals
Electromagnetic compatibility
Electronic design automation
Electronics advancements
Emerging research topics
Energy efficiency
Energy forecasting
Energy storage
Grid stability
Health technology
HVAC systems
IoT devices
Microgrid technology
Molecular electronics
Nanoelectronics
Power systems
quantum computing
Quantum cryptography
Quantum internet
Remote Sensing
renewable energy
Smart buildings
Smart grids
Smart grids cybersecurity
Speech and audio processing
sustainable manufacturing
Terahertz electronics
VLSI design
Wearable technology
Wireless protocols

Mail Subscription

iLovePhD is a research education website to know updated research-related information. It helps researchers to find top journals for publishing research articles and get an easy manual for research tools. The main aim of this website is to help Ph.D. scholars who are working in various domains to get more valuable ideas to carry out their research. Learn the current groundbreaking research activities around the world, love the process of getting a Ph.D.

Google News

Artificial intelligence

hot research topics in electrical engineering

Network Sites:
Technical Articles
Market Insights

Or sign in with
iHeartRadio

5 Electrical Engineering Research Projects Making Their Mark in 2024

Join our engineering community sign-in with:, from 3d processors to self-powered sensors, these academic research projects show how "the next big thing" in electronics may emerge from labs worldwide..

Many of the most influential hardware companies can trace their origins back to a university lab. Even RISC-V, the open-source ISA taking the hardware world by storm, had its humble beginnings at the University of California, Berkeley, in 2010. Only a few months into 2024, several projects from universities worldwide—from MIT in Boston to Shibaura Institute of Technology in Japan, have caught our attention. Here's our editor's pick of five electrical engineering research projects to keep an eye on.

MIT: Magnetic Energy Harvesting Sensor

MIT researchers have developed a self-powered, battery-free sensor that harvests magnetic energy from its surroundings. This sensor, designed for difficult-to-access areas like ship engines, can monitor power consumption and operations over extended periods without the need for battery replacement or special wiring.

System diagram of the self-powered sensor. Image used courtesy of IEEE

It operates by leveraging the ambient magnetic fields generated around electrical wires, enabling it to clip onto a wire and autonomously harvest energy. This energy is then used to monitor the temperature of the motor it is attached to. The researchers believe this innovation could lead to networks of maintenance-free sensors for various applications, significantly reducing installation and maintenance costs and potentially transforming the landscape of sensor deployment in industrial settings, manufacturing plants, and beyond.

Caltech: Tying Knots Inside Lasers

Caltech's recently published its latest research on mode-locked lasers, lasers that emit light in steady pulses instead of in one continuous beam. The team effectively created a "knot" within the laser pulses , enhancing their resilience to imperfections and environmental disturbances.

“Tying to knot” with lasers. Image used courtesy of Caltech

Such topological temporal mode-locking could significantly improve the stability and performance of frequency combs—crucial tools in modern communication, sensing, and computing applications. By ensuring that these laser pulses can withstand external shocks without losing coherence, the research opens new avenues for developing advanced sensing technologies and more reliable communication systems.

University of Florida: 3D Processors for Wireless Comms

The University of Florida's electrical engineering department has developed a three-dimensional processor it claims may "transform the landscape of wireless communication." The researchers aim to address the inherent limitations of traditional planar processors by embracing the third dimension, leading to unprecedented compactness and efficiency in data transmission.

A 3D filter created from connecting ferroelectric-gate fin resonators with different frequencies. Image used courtesy of the University of Florida

These 3D nanomechanical resonators, fabricated using CMOS technology, integrate different frequencies on one monolithic chip. The team calls this device a new type of spectral processor, taking a new approach to multi-band, frequency-agile radio chipsets to meet the surging demands for seamless connectivity and real-time data exchange. The potential applications are wide-ranging, from smart city infrastructures to remote healthcare services and immersive augmented reality experiences.

Shibaura Institute of Technology: Enhancing Electrical Fire Safety

At the Shibaura Institute of Technology, researchers have made a significant breakthrough in electrical fire safety by developing a method for detecting arc faults in low-voltage AC systems. Arc faults, one the leading causes of electrical fires, occur when two conductors electrically discharge because of poor contact, causing sparks as hot as 1,000°C.

The researchers observed that when a copper oxide bridge burns at high temperatures, an arc fault occurs, turning the bridge into an insulator and creating a loop in the conducting path. In a theoretical simulation of this phenomenon, the team saw a unique current waveform, termed the "current shoulder," appear in arc faults with copper contacts.

No arc-fault state vs. arc-fault state under various types of loads. Image used courtesy of SIT

A current transformer can detect this current shoulder when the voltage disparities between arc-fault and non-arc-fault states offset changes in the transformer's magnetic flux. This discovery improves the accuracy of arc-fault detection and may subsequently reduce the risk of electrical fires in residential and commercial buildings.

National University of Singapore: Record Solar Cell Efficiency

The National University of Singapore has achieved a milestone in solar cell technology by developing triple-junction tandem solar cells with a world-record efficiency of 27.1%. This feat was accomplished by integrating a novel pseudohalide, cyanate, into perovskite solar cells—a move that not only stabilized the perovskite structure but also significantly reduced energy loss.

The NUS triple-junction solar cell. Image used courtesy of NUS

The success of these cyanate-integrated perovskite solar cells in achieving higher voltages and maintaining stability under continuous operation marks a significant step forward in the quest for more efficient and sustainable energy solutions.

Electronics Research Marches On

Have you heard of or participated in any recent research moving the needle in electrical engineering? How might the project affect specific industries? Tell us about it in the comments below.

Learn More About:

Solar Cells
energy harvesting
national university of singapore
University of Florida
Shibaura Institute of Technology

Securing Machine Learning Models Against Copying

In Partnership with NXP Semiconductors

Learn About Load-Pull Systems: Passive and Active Tuners

by Dr. Steve Arar

Introduction to the Inductively-Loaded Class A Power Amplifier

Earthquake in Taiwan—Our Hearts Go Out to Those Impacted

by All About Circuits

Putting Labels to the Test

Welcome Back

Don't have an AAC account? Create one now .

Forgot your password? Click here .

Who’s Teaching What
Subject Updates
MEng program
Opportunities
Minor in Computer Science
Resources for Current Students
Program objectives and accreditation
Graduate program requirements
Admission process
Degree programs
Graduate research
EECS Graduate Funding
Resources for current students
Student profiles
Instructors
DEI data and documents
Recruitment and outreach
Community and resources
Get involved / self-education
Rising Stars in EECS
Graduate Application Assistance Program (GAAP)
MIT Summer Research Program (MSRP)
Sloan-MIT University Center for Exemplary Mentoring (UCEM)
Electrical Engineering
Computer Science
Artificial Intelligence + Decision-making

AI and Society

Ai for healthcare and life sciences, artificial intelligence and machine learning, biological and medical devices and systems, communications systems.

Computational Biology

Computational Fabrication and Manufacturing

Computer architecture, educational technology, electronic, magnetic, optical and quantum materials and devices, graphics and vision, human-computer interaction, information science and systems, integrated circuits and systems, nanoscale materials, devices, and systems, natural language and speech processing, optics + photonics, optimization and game theory, programming languages and software engineering, quantum computing, communication, and sensing, security and cryptography, signal processing, systems and networking, systems theory, control, and autonomy, theory of computation.

Departmental History
Departmental Organization
Visiting Committee
Explore all research areas

EECS’ research covers a wide variety of topics in electrical engineering , computer science , and artificial intelligence and decision-making .

The future of our society is interwoven with the future of data-driven thinking—most prominently, artificial intelligence is set to reshape every aspect of our lives. Research in this area studies the interface between AI-driven systems and human actors, exploring both the impact of data-driven decision-making on human behavior and experience, and how AI technologies can be used to improve access to opportunities. This research combines a variety of areas including AI, machine learning, economics, social psychology, and law.

Our goal is to develop AI technologies that will change the landscape of healthcare. This includes early diagnostics, drug discovery, care personalization and management. Building on MIT’s pioneering history in artificial intelligence and life sciences, we are working on algorithms suitable for modeling biological and clinical data across a range of modalities including imaging, text and genomics.

Our research covers a wide range of topics of this fast-evolving field, advancing how machines learn, predict, and control, while also making them secure, robust and trustworthy. Research covers both the theory and applications of ML. This broad area studies ML theory (algorithms, optimization, …), statistical learning (inference, graphical models, causal analysis, …), deep learning, reinforcement learning, symbolic reasoning ML systems, as well as diverse hardware implementations of ML.

We develop the technology and systems that will transform the future of biology and healthcare. Specific areas include biomedical sensors and electronics, nano- and micro-technologies, imaging, and computational modeling of disease.

We develop the next generation of wired and wireless communications systems, from new physical principles (e.g., light, terahertz waves) to coding and information theory, and everything in between.

We bring some of the most powerful tools in computation to bear on design problems, including modeling, simulation, processing and fabrication.

We design the next generation of computer systems. Working at the intersection of hardware and software, our research studies how to best implement computation in the physical world. We design processors that are faster, more efficient, easier to program, and secure. Our research covers systems of all scales, from tiny Internet-of-Things devices with ultra-low-power consumption to high-performance servers and datacenters that power planet-scale online services. We design both general-purpose processors and accelerators that are specialized to particular application domains, like machine learning and storage. We also design Electronic Design Automation (EDA) tools to facilitate the development of such systems.

Educational technology combines both hardware and software to enact global change, making education accessible in unprecedented ways to new audiences. We develop the technology that makes better understanding possible.

Our research spans a wide range of materials that form the next generation of devices, and includes groundbreaking research on graphene & 2D materials, quantum computing, MEMS & NEMS, and new substrates for computation.

Our research focuses on solving challenges related to the transduction, transmission, and control of energy and energy systems. We develop new materials for energy storage, devices and power electronics for harvesting, generation and processing of energy, and control of large-scale energy systems.

The shared mission of Visual Computing is to connect images and computation, spanning topics such as image and video generation and analysis, photography, human perception, touch, applied geometry, and more.

The focus of our research in Human-Computer Interaction (HCI) is inventing new systems and technology that lie at the interface between people and computation, and understanding their design, implementation, and societal impact.

This broad research theme covered activities across all aspects of systems that process information, and the underlying science and mathematics, and includes communications, networking & information theory; numerical and computational simulation and prototyping; signal processing and inference; medical imaging; data science, statistics and inference.

Our field deals with the design and creation of sophisticated circuits and systems for applications ranging from computation to sensing.

Our research focuses on the creation of materials and devices at the nano scale to create novel systems across a wide variety of application areas.

Our research encompasses all aspects of speech and language processing—ranging from the design of fundamental machine learning methods to the design of advanced applications that can extract information from documents, translate between languages, and execute instructions in real-world environments.

Our work focuses on materials, devices, and systems for optical and photonic applications, with applications in communications and sensing, femtosecond optics, laser technologies, photonic bandgap fibers and devices, laser medicine and medical imaging, and millimeter-wave and terahertz devices.

Research in this area focuses on developing efficient and scalable algorithms for solving large scale optimization problems in engineering, data science and machine learning. Our work also studies optimal decision making in networked settings, including communication networks, energy systems and social networks. The multi-agent nature of many of these systems also has led to several research activities that rely on game-theoretic approaches.

We develop new approaches to programming, whether that takes the form of programming languages, tools, or methodologies to improve many aspects of applications and systems infrastructure.

Our work focuses on developing the next substrate of computing, communication and sensing. We work all the way from new materials to superconducting devices to quantum computers to theory.

Our research focuses on robotic hardware and algorithms, from sensing to control to perception to manipulation.

Our research is focused on making future computer systems more secure. We bring together a broad spectrum of cross-cutting techniques for security, from theoretical cryptography and programming-language ideas, to low-level hardware and operating-systems security, to overall system designs and empirical bug-finding. We apply these techniques to a wide range of application domains, such as blockchains, cloud systems, Internet privacy, machine learning, and IoT devices, reflecting the growing importance of security in many contexts.

Signal processing focuses on algorithms and hardware for analyzing, modifying and synthesizing signals and data, across a wide variety of application domains. As a technology it plays a key role in virtually every aspect of modern life including for example entertainment, communications, travel, health, defense and finance.

From distributed systems and databases to wireless, the research conducted by the systems and networking group aims to improve the performance, robustness, and ease of management of networks and computing systems.

Our theoretical research includes quantification of fundamental capabilities and limitations of feedback systems, inference and control over networks, and development of practical methods and algorithms for decision making under uncertainty.

Theory of Computation (TOC) studies the fundamental strengths and limits of computation, how these strengths and limits interact with computer science and mathematics, and how they manifest themselves in society, biology, and the physical world.

Frontiers in Materials
Polymeric and Composite Materials
Research Topics

Advanced Technologies for Electrical Engineering

Total Downloads

Total Views and Downloads

About this Research Topic

Energy crisis and environmental pollution are two major themes currently faced by human society. The construction of a strong smart grid with super/ultra-high voltage network as the backbone and clean energy transmission as the leading shows a more important strategic role than ever since. However, the rapid ...

Keywords : Dielectric Polymer Materials, Insulation Materials, Conductive Materials, Magnetic Materials, Energy Storage Materials, Polymer Solar Cells, Superhydrophobic and Slippery Materials

Important Note : All contributions to this Research Topic must be within the scope of the section and journal to which they are submitted, as defined in their mission statements. Frontiers reserves the right to guide an out-of-scope manuscript to a more suitable section or journal at any stage of peer review.

Topic Editors

Topic coordinators, recent articles, submission deadlines.

Submission closed.

Participating Journals

Total views.

Demographics

No records found

total views article views downloads topic views

Top countries

Top referring sites, about frontiers research topics.

With their unique mixes of varied contributions from Original Research to Review Articles, Research Topics unify the most influential researchers, the latest key findings and historical advances in a hot research area! Find out more on how to host your own Frontiers Research Topic or contribute to one as an author.

Research Topics in Electrical Engineering

Electrical engineering is the branch of engineering which handles the designing, maintenance, and control of power electronic & power system devices . As well as they apply the electricity/power in that devices. Electrical engineering is often called EEE. They consider the effective power supplies of electrical devices and perform testing tasks to ensure electrical protection .

“This article is dedicated to the enthusiasts who are dynamically surfing for the research topics in electrical engineering”

By using the power electronics techniques electrical engineering offers consistent power systems. This is also aimed at optics, electrical mechanisms, and physics so on. This article is completely focused on giving the exact details on the research topics in electrical engineering to the students. At the end of this article, you would find the indispensable specifics and you will enjoy this article to be sure.

This article is going to beat your expectations as this is treasured with interesting facts. In addition, we wanted to begin this article with our familiar skillsets for your valuable considerations . Our technical team is framed with world-class engineers who can handle the entire aspects of technology. Now let’s begin this article with our experts’ skills in EEE.

Top 10 Interesting Research Topics in Electrical Engineering

Our Experts Skills in EEE

Perform Various Electronic Devices Preservation & Handling
Processed with Multiple Data Acquisition & Investigation
Worked in various Electrical Schematics Environments
Understanding of Linear Algebra Theories & Analytics
Able to design new and customize Electrical Circuit Design/Models

The above mentioned are some of the skillsets of our technical team. Apart from this, our technical crew is well versed in the other areas of electrical engineering technology too. To be honest, we are providing every practical explanation with graphical illustrations which results in the students’ great compassion. We are being trusted by students from all over the world. Envisaging the innovations and applying them to the technologies are our major objectives and we are successfully yielding the same in every approach to research topics in electrical engineering .

In the following passage, we can move on to the core aspects of the article’s theme. Guys don’t squeeze your heads about the next section. We are mounting to the significant electrical components of electrical engineering with their short descriptions for the ease of your understanding. Are you ready to know about that? Come let’s have the next section!!!

Important Electrical Components

Deals with unenclosed electrodes
It ties with the power loads between 2 nodes
It is used to isolate the circuits in the form of high / medium voltages
It resets the fuse when power over supplied in the switches
It is a component in which humidity is measured
It is a thermal electrical component
It is an electromagneticelectrical component
Functions with the electro-mechanisms
Rotation rate determines the centrifugal sensing forces
Sensing angles / tilts of the switch devices
Motion limits sensing switch mechanisms
Snap action sensingswitch mechanisms
Switches operated by foots/ends
Configuration setting internal array of switches
Range of push button / key buttons
Passes and outbreaks the current flows
It uses the light dependent resistors
Humidity is evaluated by hygrometer
It uses the gauss meters & magnetometer
Thermal cutoff is the switch which is dealing (opened/closed) with the temperatures
Bolometers measures the radiations of power exploitations
Thermistor is the resistor which works according to the NTC/PTC ups & downs
Thermopile / Thermocouple creates a relational voltage to the delta humidity
Resistance temperature detector deal with the wire temperature variations
Accelerometers identifies the electrical gravity & acceleration
Strain gauge identifies the winding, enlarging & enfolding aspects
Gas / Liquid flow is identified by the flow meters
Electrical vibrations are sensed by motion sensors
Gravity based directions are recognized by inclinometers
Linear situations are detected by linear variable differential transformer
Rate of rotation & proportional angles are recognized by rotary encoders
Piezoelectric sound tones are created by audio buzzers
Complete audio of the electronic devices are produced by loudspeakers

The above listed are the various components that are involved in electrical engineering in real-time . Consequently, we listed all the essential electrical components to the lay-mans or the beginners in these fields. We hope that it will abundantly help them. In a matter of fact, our articles are being published in the top IEEE journals respective to electrical engineering project topics . Now you can give a weightage to our contents. This is possible by inputting the unique power electronics project ideas & concepts in it starting with research topics in electrical engineering .

As this article is refined through various levels of internal checks we thought that giving the current elements of the EEE here would be nice. Yes, my dear readers, our technical crew is also listed the current elements of the EEE for the ease of your understanding . Come let’s try to understand them.

What are the Current Elements in EEE?

These elements measures the electric signals with high speed
Probe loading is used to measure the circuit diagrams with higher frequency
Probe input capability results in high frequency
It is used to measure the immobile probes which cannot reaches the circuit
Instances of CP are huge buss bars, unusual shapes & closed break controls
It allows to read power ingestion of the electrical devices like oscilloscopes & DMMs
Radio waves are receiving and responding to the frequencies in a given range
Transmits the radio signals & determines the frequency fluctuation rates
The power flow is floated in the surface of the circuits & never goes in-depth
It produces the various kinds of electric waves & acts as a testing tool
Triangular, sine & square are the sorts of waveforms
These shapes are exposed while diagnosing the electrical processes
It is used to test the electrical circuits voltage
At the end it is tied with dual twisted cables & neon bulbs
It identifies the flow of the power supply in every cables/wires
Effective voltage tester is compatible with the 500 volts (V)
Laboratories voltages are measured by the DVMs
It represents the voltages in the forms of LCD/LED

The foregoing passage has conveyed to you the various essential elements of the EEE . Handling these elements needs some practice. You can handle these elements with our experts’ guidance in the determined areas. In fact, we are having 100+ energetic developers in our concern & they can help you throughout your researchers and projects of every technology.

Techniques used for Electrical Engineering

Gradient-based Techniques
Conjugate Gradient Techniques
Sequential Quadratic Programming Techniques
Intellectual Optimization Techniques
PSO, Ant Colony, Immune & EDA Techniques
DEA & GA Evolutionary Techniques
Multi-Objective Optimization Techniques
Sequential Minimal Optimization Techniques
Convex Optimization Techniques
Co-ordinate Descent Techniques
Stochastic Optimization Techniques
Gibbs Sampling & Swarm Techniques
Tabu & Genetic / Annealing Techniques
Metropolis-Hastings Techniques
Dropout & Back-propagation Techniques
Eigenvalue Decomposition Techniques

The itemized above are the latest techniques used for EEE researches and projects in general. For your information, these techniques will be applied in the EEE concepts which need effective & incredible results. If you do want any assistance in these areas you could reach our technical team experts to sort out your uncertainties .

In this regard, our researchers of the concern are wanted to highlight the major research areas in EEE for ease of your understanding. We are habitually conducting researches in the areas of EEE hence we wished to transfer our knowledge in these areas too. Are you interested to know about them? Come on guys lets we move on to the next section.

Major Research Areas in EEE

AI & Signal Processing
High Voltage Engineering
P ower Electronics
Power Systems

The aforementioned are the 4 major areas involved in electrical & electronic engineering . So far we have learned the EEE concepts ranging from basic to advance . Certainly, we hope that you would have understood the things explained as of now.

As this article is titled with the research topics in electrical engineering we are going to envelop the next section with the latest research topics in EEE with their descriptions. Are you getting interested to know about that too? Let’s try to understand the same with clear points.

Latest Research Topics in EEE

Remnant/fossil & petroleum fuels are stimulating the RES
In addition, power supply from these are inadequate inherent
Copper & core damages diminishes the electrical devices efficiency
Power supply variations determines the copper losses
Core losses are determined according to the persistent power supplies
Less hysteresis materials can be used to minimize the core losses
These are capable of acquiring massive electrical data than meter readers
It is used to predict & analyze the power consumption by several techniques
Pre-programing of power load supply & demand helps to avoid the grid failures
UHVDC is also known as high voltage DC
It is widely used to reduce the power losses during transmitted in far distances
It attains the transmission proficiency 99 out of 100%

These are some of the latest research topics in electrical engineering . These areas need research initiations to overcome the shortcomings arouse in them. For example, switch regulators and circuit breakers are complex to design. Along with these, solar cells of renewable energy resources are needed to be experimented with to enrich their performance.

This is only a sample for your valid references apart from this we are plenteously having the research topics in electrical engineering which is unique in nature.

In addition to these areas, it is also important to have knowledge in the areas of the latest trends in electrical and electronics engineering . The latest trends are tending the futuristic characteristics in it. Yes, guys, we know that you are also storming the trends of the EEE so that we are going to itemize you the same for your superior indulgent. Are you ready to know them? Here we go!!!

Top 10 Research Topics in Electrical Engineering Domain

Latest Trends in EEE

Improved Performance of Power Electronic Devices
Innovative Solar Energy based Power Cells
Integration of Micro / Smart Grids with RES
Positioning of Renewable Energy Systems

The above listed are the latest trends that makes the EEE much more innovative. Here RES stands for Renewable Energy Sources . For instance, solar energy power cells are the effective systems and help to produce the power units with cost effective.

So far we have come up with the areas of research topics in electrical engineering with crystal clear facts. We hope that you are relishing this article as this is conveyed to you all the necessary details. We are delighted with our contributions by transferred our piece of knowledge here. We are hoping for your further explorations in these areas of technology. Let’s make execute your ideas in the form of researches.

Stay educated! Stay experimented! Stay exposed!!!

Information

Author Services

Initiatives

You are accessing a machine-readable page. In order to be human-readable, please install an RSS reader.

All articles published by MDPI are made immediately available worldwide under an open access license. No special permission is required to reuse all or part of the article published by MDPI, including figures and tables. For articles published under an open access Creative Common CC BY license, any part of the article may be reused without permission provided that the original article is clearly cited. For more information, please refer to https://www.mdpi.com/openaccess .

Feature papers represent the most advanced research with significant potential for high impact in the field. A Feature Paper should be a substantial original Article that involves several techniques or approaches, provides an outlook for future research directions and describes possible research applications.

Feature papers are submitted upon individual invitation or recommendation by the scientific editors and must receive positive feedback from the reviewers.

Editor’s Choice articles are based on recommendations by the scientific editors of MDPI journals from around the world. Editors select a small number of articles recently published in the journal that they believe will be particularly interesting to readers, or important in the respective research area. The aim is to provide a snapshot of some of the most exciting work published in the various research areas of the journal.

Original Submission Date Received: .

Active Journals
Find a Journal
Proceedings Series
For Authors
For Reviewers
For Editors
For Librarians
For Publishers
For Societies
For Conference Organizers
Open Access Policy
Institutional Open Access Program
Special Issues Guidelines
Editorial Process
Research and Publication Ethics
Article Processing Charges
Testimonials
Preprints.org
SciProfiles
Encyclopedia

Journal Menu

Energies Home
Aims & Scope
Editorial Board
Reviewer Board
Topical Advisory Panel
Instructions for Authors
Special Issues
Sections & Collections
Article Processing Charge
Indexing & Archiving
Editor’s Choice Articles
Most Cited & Viewed
Journal Statistics
Journal History
Journal Awards
Society Collaborations
Conferences
Editorial Office

Journal Browser

arrow_forward_ios Forthcoming issue arrow_forward_ios Current issue
Vol. 17 (2024)
Vol. 16 (2023)
Vol. 15 (2022)
Vol. 14 (2021)
Vol. 13 (2020)
Vol. 12 (2019)
Vol. 11 (2018)
Vol. 10 (2017)
Vol. 9 (2016)
Vol. 8 (2015)
Vol. 7 (2014)
Vol. 6 (2013)
Vol. 5 (2012)
Vol. 4 (2011)
Vol. 3 (2010)
Vol. 2 (2009)
Vol. 1 (2008)

Find support for a specific problem in the support section of our website.

Please let us know what you think of our products and services.

Visit our dedicated information section to learn more about MDPI.

Volume II: Challenges and Research Trends of Electrical Engineering and Power Electronics

Print Special Issue Flyer

Special Issue Editors

Special issue information.

Published Papers

A special issue of Energies (ISSN 1996-1073). This special issue belongs to the section " F: Electrical Engineering ".

Deadline for manuscript submissions: closed (2 January 2023) | Viewed by 15466

Share This Special Issue

Dear Colleagues,

The special issue "Volume II: Challenges and Research Trends of Electrical Engineering and Power Electronics" will be devoted to current challenges in power generation and distribution.

With the growing role of information and communication technologies, electromobility and the struggle for an ever decreasing environmental impact of civilisation, the need to optimise energy generation and distribution processes and to meet challenges such as distributed generation and rapid changes in demand arises. These requirements generate the need for special research in the direction of automation of management of the widely understood power system. The special issue is intended to address these requirements. The main, but not the only, focus will be on applications of advanced signal and data processing (computer simulation, surrogate models, machine learning, artificial intelligence and computer science in general) to meet today's challenges of clean, high quality energy. I especially invite papers related to automatic diagnostics in power generation and conversion, special applications of electricity, optimal energy storage, distributed generation, smart grids, renewable and small sources (including small hydro, biomass, biogas, solar, wind and geothermal power) and their integration into the power system, energy harvesting and power quality.

Prof. Dr. Jacek Starzynski Dr. Bogdan Dziadak Dr. Adam Jóśko Guest Editors

Manuscripts should be submitted online at www.mdpi.com by registering and logging in to this website . Once you are registered, click here to go to the submission form . Manuscripts can be submitted until the deadline. All submissions that pass pre-check are peer-reviewed. Accepted papers will be published continuously in the journal (as soon as accepted) and will be listed together on the special issue website. Research articles, review articles as well as short communications are invited. For planned papers, a title and short abstract (about 100 words) can be sent to the Editorial Office for announcement on this website.

Submitted manuscripts should not have been published previously, nor be under consideration for publication elsewhere (except conference proceedings papers). All manuscripts are thoroughly refereed through a single-blind peer-review process. A guide for authors and other relevant information for submission of manuscripts is available on the Instructions for Authors page. Energies is an international peer-reviewed open access semimonthly journal published by MDPI.

Please visit the Instructions for Authors page before submitting a manuscript. The Article Processing Charge (APC) for publication in this open access journal is 2600 CHF (Swiss Francs). Submitted papers should be well formatted and use good English. Authors may use MDPI's English editing service prior to publication or during author revisions.

energy quality
smart grids
smart sensors
machine learning for automated control and diagnostics
renewable sources

Published Papers (7 papers)

Jump to: Review

Jump to: Research

Further Information

Mdpi initiatives, follow mdpi.

Subscribe to receive issue release notifications and newsletters from MDPI journals

Premium Membership ♕

Learn from experienced engineers and study specialized technical articles, guides & courses. Save 50% on courses with the Enterprise Plan.

Researches and Projects

Research papers.

EEP’s section Researched and Projects encourages every research scholar, professors, faculty members and research students to publish their research papers on EEP.

EEP’s goal is to promote scientific research in electrical engineering in general, power substation, transformers, HVAC, maintenance of electrical equipment, industry automation, power electronics, low through medium to high voltage, renewable energy (solar, wind, hydro, geothermal), etc..


1	The Four Layers of Smart Grid Security
2	Planning application of equipments in hydro power projects
3	Leakage and ground currents: Measurement techniques
4	The applicability of lighting elimination, devices to substations and power lines
5	Active current, Reactive current, Kirchhoff’s laws and Tellegen’s theorem Shared by Mr. Shailesh Kumar
6	Micro Hydro Project: an option for development of Rural Areas Shared by Mr. Pravesh Kafle
7	The Use of Attack Trees in Assessing Vulnerabilities in SCADA Systems
8	Capacitor Bank Switching with Vacuum Circuit Breakers by Schneider Electric
9	Light fixture with color temperature of the light dependent on the solar time Shared by Mr. Andrzej Andrew Pelczar
10	Parallel Path Magnetic Technology for High Efficiency Power Generators and Motor Drives
11	Electrical Conductance and Insulation
12	High altitude considerations for electrical power systems and components
12	Selecting the right PV voltage
13	The Role of Infrared Testing at Data Centers

Premium Membership

29 comments.

Hello sir, I am an Electrical Engineer in a Construction Firm. Would you give me a best topic for a research paper in connection to my nature of work.

Thank you very much

i am the student of electrical engineering and my specialization is in power here is my final year please can you give me an idea of final year project in power . i need a project idea with reserch papers

i run a master degree course in electrical electronics (power option) i need a project topic on transmission lines and its protection schemes

dear sir i am working on auto cad electrical and now i want to write a paper using this software is there any one who could send me some data or topics guide for this research thanks in advance. [email protected]

Sir ,plz provide me research paper on any new topic

sir i am a final year student of electrical engineering tell about authntic project mean latest.

good day sir, been trying to come up with a suitable topic for my thesis, pursuing my Msc in electrical power systems, i am hoping to work on electrical power stability (transient). please i need all information i can get from you sir with a suitable topic, thanks

Hello sir , I m a final year student of electrical engineering. plz suggest me the latest innovative project topics.

this website is really worth for me, Everyday i got a mail with a new thing. sir i’m doing master of engineering, and i research a project regarding renewable source something new and innovative.so kind me send something related to my subject. i will be very glad and thankful to EEP..

Sir Kindly send me the Ph.D thesis and IEEE articles,if any,related to the Phasor Measurement Units(PMUs) to my mail id. Thank you.

I want to research in power system protection Kindly suggest me.

Hello sir; I’m an electrical enginner, and I want to do a PhD in renewable energy, and I am looking for some hot topics today. Can you please suggest some of them?

Hi , Im looking for project fo protection of transformer

I want to do research in ELECTRICAL or electronic .I m doing b tech in ELECTRICAL.sir tell me about the areas .

Hello sir , I m a final year student of electrical engineering. plz suggest me the latest innovative project topics. Plz sir I want to do something innovative. my email id is [email protected]

Hi! I’m electrical engineering student in DHVTSU, Bacolor, Pampanga, PH. I’m in 4th level and in need a topic related on industrial automation and system evaluation for our ResearchA. If you have some ideas kindly email me. Thank you in advance! More energy and More Power EEP!

we have done our final year project on Transient stability analysis of a 30 bus system and want to publish it. kindly guide. thanks

I am a final year student and I am also interested in doing a project Transient stability analysis of a Power system. I am requesting for your report to aid me do mine. Kindly assist.

hi i am amjad iqbal student of 1st year MSC … i want to publish paper… is there any one who can guide me how to publish paper?… as i am in 1st semester i don’t have any idea about research pls help me i will be always thank full to all of you email me [email protected]

your website is really helpfull.plz put some projects for students also………… we have learnt from it a lot…………

hello everyone, i m alakesan doing my master of engineering at Anna university, chennai, india. i m on my final year. As per curriculum i have to do project. i m interested in mechanical loads that are acting on electrical equipment. i have finished my literature survey. i planned to do “seismic and static analysis on gis- circuit breaker and its support structures, since it is vulnerable to mechanical loads. But i m struggling with dimensions of circuit breakers. So i request you guys, kindly give some guidance to do model the circuit breaker. my mail id is ; [email protected] – thanking you

There aren’t enough words to express how useful EEP has been to me, my students and my teaching profession. Please keep on with the good work. In the same vane, I would want to request you supply me with materials on Teacher’s Guide pertaining to Power Systems Analysis, Power Systems Control, Protection, Planning, Operations and Economic Despatch with worked examples or their theory and examples versions.

You may please forward it to my email address: [email protected] . This will undoubtedly enhance my teaching and the students’ learning prospects.

Thank you very much to all the EEP group once again.

I am looking for research graduate position in Power System Stability, Network, Control and Optimization. Have more than 7 years of experience in Power System and good technical back ground. Email : [email protected]

Hi,I’m looking for a project or research about methods for reducing looses in electrical transmission lines. if you have please send it to my email; [email protected]

Did you get any?

Thanks so much to EEP, please information on design construction of automatic water pumping machine, it circuit wiring/diagram. Mail: [email protected]

Thanks for your Valuable information through EEP

SIR PLEASE I AM REQUESTED TIO YOU PLEASE UPLOD MORE DETAIL BOOKS PAPERS IN ELECTRICAL MACHINES HIGH VOLTAGE ,CONTROL SYSTEM , UTILIZATION OF ELECTRICAL POWER,COMPUTER ADDED DESIGN AND POWER SYSTEM ANALYSIS .PLEASE SEND ME ON MY EMAIL [email protected] , thank you sir

THANK YOU SO MUCH SIR IT SO USEFUL IN ELECTRICAL ENGINEERING AGAIN THANK YOU

Tell us what you're thinking. We care about your opinion! Please keep in mind that comments are moderated and rel="nofollow" is in use. So, please do not use a spammy keyword or a domain as your name, or it will be deleted. Let's have a professional and meaningful conversation instead. Thanks for dropping by!

Your real name *

Email address *

Learn How to Design Power Systems

Subscribe to weekly newsletter.

100+ Electrical Engineering Research Topics Examples

Electrical engineering comprises the comprehension of electricity and how it works. The main task of electrical engineers is to improve the distribution of energy to different electrical devices. Electrical engineers utilize their skills and knowledge to solve different technical issues. Electrical engineers’ tasks are working with the airline navigation system, GPS, systems for power generation, and transmissions like the wind farmhouses and similar projects. Working on different energies also comes in the domain of electrical engineers such as hydro-energy, turbine, fuel cell, gas, geothermal energy, solar energy, and wind energy. Electrical engineers use various passive components such as inductors, capacitors, and resistors, and so on while working on electrical devices and systems.

Students need to get different ideas for the research in electrical engineering on the latest ideas during the academic career of engineering. If you have been looking for an article that includes interesting research paper topics for electrical engineering students at a single site, you have come to the right place.

Electrical Engineering

Search form.

Future Students
Current Students
Accreditation
Senior Design
Scholarships and Funds
Marketable Skills
Study Abroad
M.S. Program
Ph.D. Program
Research Overview
Research Labs
Research Equipment
Stay Connected
Update Your Info
Order Transcript
Mission and Vision
Department History
Board of Advisors

Electrical Engineering Research

Faculty members and students at the department of Electrical Engineering work together to conduct research across many areas in the field of electrical engineering as well as related fields such as computer science and engineering. These research areas can be divided into three groups.

Communications, Signal Processing and Networking

This group focuses on design and development of advanced communication techniques to provide efficient and robust information transmission over wired and wireless networks.

This group has an extensive collaborative research program with the Computer Science and Engineering Department. Working in concert with academia and industry partners, the group is dedicated to research on:

information and communication theory
source and channel coding
wireless communication and networking

Both undergraduate and graduate levels courses are offered by the faculty members in this group.

The Applied Electromagnetics Laboratory focuses on the domain of applied electromagnetics with applications ranging from developing biomedical devices to designing antennas for various wireless systems. Research topics include:

Microwave ablation and monitoring
Self-interference cancellation techniques for in-band full-duplex communications
Adaptive phased-array antennas for beam-steering applications
Reconfigurable multi-beam antennas for millimeter-wave communications

The Applied Optics Lab aims at:

Optical system (imaging and non-imaging) design and modeling, tolerance analysis, and system optimization to improve design for manufacturability.
Design and fabrication of electro-optic polymer integrated circuits for chemical/biological sensors and optical current sensors (OCS) for smart grid electric distribution system.

The Communications and Signal Processing Laboratory (CSPL) focuses on design and development of advanced communication techniques to provide efficient and robust information transmission over wired and wireless networks. Working in concert with academia and industry partners, CSPL is dedicated to research in coding and information theory; aerial communication and networks; drone system design and applications, especially in emergency response; and wireless sensor networks.

The Embedded Sensing & Processing Systems (ESPS) Laboratory focuses on research in the areas of statistical signal processing, machine learning, real-time embedded systems, and wireless sensor networks with applications in wireless localization and tracking, environmental monitoring, cyber-physical systems, Internet of Things, and artificial intelligence. The overarching goal of our research is to solve real-life system-level challenges through theoretical research in signal processing and machine learning, networking protocol design and analysis, and practical system developments with hardware and software implementations.

The Information Theory and Applications Laboratory focuses on the application of information theory to communications, networking, privacy, security and storage. Current research interests include private information retrieval, index coding, optimality of treating interference as noise, topological interference management, and interference alignment.

The Optimization, Signal Processing, and Control Algorithm Research Lab (O.S.C.A.R.) focuses on fundamental algorithm development at the forefront of machine learning seeking efficient and accurate solutions based in traditional optimization, signal processing and control theory techniques. Current research topics include:

Classification and Identification
Image Compression
Image Super Resolution
PCA Applications
STEM Outreach

Systems and Control

This group investigates state of the art research problems in robotics, power systems, and cooperative decentralized systems.

Faculty and students work on autonomous systems including wireless sensor networks, robotic systems, airborne networks, and networks of unattended air vehicles.

Research applications include disaster recovery, search-and-rescue operations conducted by teams of people, surveillance of ground-based targets by fleets of unmanned aerial vehicles and exploration of planetary surfaces by swarms of robots.

The Autonomous Systems Laboratory focuses on information assurance, decision making and video communications aspects in autonomous systems, such as unmanned aerial vehicles (UAVs). This laboratory consists of infrastructure and simulation tools necessary to develop protocols for autonomous systems and to analyze their performance. The laboratory has several UAVs that are being used to develop and test decentralized decision-making and task-scheduling algorithms. The laboratory's infrastructure includes computing and networking equipment suitable for simulating civilian and military applications.

The Control Systems Laboratory focuses on the advancement of control theory and technology with applications to intelligent and autonomous systems. Current research topics include control systems with time delay, unmanned aerial vehicles, deep reinforcement learning based control, and active magnetic bearings.

The Environmental and Ecological Engineering Laboratory integrates environmental modeling, real-time monitoring, and renewable power systems for applications to sustainability. Research topics include food-energy-water nexus, sustainable brackish water desalination systems, land-use change, landscape dynamics, and forest ecology, coupled human-natural systems, watershed and reservoir management, wireless sensor networks and environmental observatories, and global climate change.

The Power Electronics and Renewable Energy (PERE) Laboratory focuses on developing effective power electronics technologies to improve the generation, conversion, and control of electrical energy in smart cities and sustainable energy applications. Research topics include wide-bandgap semiconductor applications, renewable energy conversion technologies, smart grids, distributed energy systems, and electric vehicle grid integration.

RF and Circuit Design

Faculty and students of this group are working on a wide variety of fundamental and applied problems in circuits and systems as well as their applications in communications, networking, geolocation, and vision processing.

This group offers many courses in RF/microwave/millimeter-wave circuit and antenna design at both undergraduate and graduate levels.

Designed circuit components will be implemented either on the board-level or on the chip-level.

The Analog/Mixed-Signal Design and Simulation Lab focuses on design and simulation of analog/mixed-signal AMS) integrated circuits (ICs) for multimedia and IoT security applications. Research topics include:

Surrogate modeling (metamodeling) of complex IC functional design units
Hardware/software co-design of secure multimedia digital systems
High-level behavioral simulation of AMS ICs
Hardware design of Physically Unclonable Functions (PUFs)
Embedded system design for the IoT
Emerging Technology and VLSI Research Lab Faculty: Edgard Munoz-Coreas

The Nanoscale Materials and Devices Lab (NMDL) focuses on emerging devices from low-dimensionality solid-state materials. Research topics include but are not limited to:

Low-power nanoelectronic devices and circuits
Photodetectors and optoelectronic devices
Flexible and printed electronics
Physical sensors and sensor arrays
Synthesis of semiconducting selenides and sulphides
Nanofabrication

The Reconfigurable Computing Laboratory provides infrastructure for electronic design automation, including several workstations with the latest Electronic Design Automation (EDA) software, enabling design and simulation of a range of electronic chip designs. Students have access to EDA software including Cadence, Synopsys, and Xilinx design tool suites. The laboratory supports high quality research activities related to digital design, reconfigurable computing, FPGAs, ASICs, VLSI design, electronic design automation, SoC design, portable computing, and wearable computing.

Communications and Signal Processing Laboratory
Embedded Sensing & Processing Systems Laboratory
Information Theory and Applications Laboratory
Autonomous Systems Laboratory
Cyber-Physical Energy Systems Laboratory
Networked Intelligent Control Systems Laboratory
Computer Aided Design (CAD) Laboratory
Integrated Biomedical Circuits and Systems Laboratory (iBioCASL)

Research Home

Laboratories, research faculty, research for students, facilities and equipment use.

UNT's Electrical Engineering labs offer a wide variety of research opportunities and experiences for all of our students.

Institutional labs can be used by any student, with or without faculty supervision, for any projects. As the name suggests, these often double as classrooms.

Research labs are under the direct supervision of a faculty member and usually dedicated to a single research area. They often contain specialized equipment appropriate for study of the research area.

Finding your Research Niche

Both graduate and undergraduate students can work with the three faculty research groups mentioned at the beginning of this page.

Faculty research areas give students the chance to work closely with professors and other students in a variety of projects centered around important engineering subjects.

If you're interested in participating in research in the Electrical Engineering department, it's as easy as knocking on a faculty member's door and asking what opportunities are available.

Graduate Programs
Undergraduate Programs
Schedule a tour

Strategic Research Areas

Research Groups, Centers and Labs
Undergraduate Research Opportunities
Executive Leadership
Administrative Staff
Faculty Awards and Honors
Resources and Groups for ECE Women
ECE Advisory Council
ECE Connections
Giving Opportunities
Ways to Give
Academic Support
Financial Support
Mental Health Resources
Experience and Employment
Undergraduate Services
Graduate Services and Activities

Research in Electrical and Computer Engineering covers an extremely broad range of topics. Whether in computer architecture, energy and power systems or in nanotechnology devices, the research conducted in ECE is at the cutting edge of technological and scientific developments.

Computer Engineering

Computer engineering concerns itself with the understanding and design of hardware needed to carry out computation, as well as the hardware-software interface. It is sometimes said that computer engineering is the nexus that connects electrical engineering and computer science. Research and teaching areas with a significant computer engineering component include digital logic and VLSI design, computer architecture and organization, embedded systems and Internet of things, virtualization and operating systems, code generation and optimization, computer networks and data centers, electronic design automation, or robotics.

Related Research Areas

Artificial Intelligence
Complex Systems, Network Science and Computation
Computer Architecture
Computer Systems
Data Mining
Energy and the Environment
Rapid Prototyping

Robotics and Autonomy

Scientific Computing
Sensors and Actuators
Signal and Image Processing
Statistics and Machine Learning

Robotics at Cornell spans various subareas, including perception, control, learning, planning, and human-robot interaction. We work with a variety of robots such as aerial robots, home and office assistant robots, autonomous cars, humanoids, evolutionary robots, legged robots, snake robots and more. The Collective Embodied Intelligence Lab works to design and coordination of large robot collectives able to achieve complex behaviors beyond the reach of single robot systems, and corresponding studies on how social insects do so in nature. Major research topics include swarm intelligence, embodied intelligence, autonomous construction, bio-cyber physical systems, human-swarm interaction, and soft robots.

Visit the the Cornell Engineering Robotics Website for more.

Integrated Circuits
Power Electronics
Robotics and Autonomy
Systems and Networking

Information, Networks, and Decision Systems

This research area focuses on the advancement of research and education in the information, learning, network, and decision sciences. Our research is at the frontier of a wide range of fields and applications, including machine learning and signal processing, optimization and control theory, information theory and coding, power systems and electricity markets, network science, and game theory. The work encompasses theory and practice, with the overarching objective of developing the mathematical underpinnings and tools needed to address some of the most pressing challenges facing society today in energy and climate change, transportation, social networks, and human health. In particular, the Foundations of Information, Networks, and Decision Systems (FIND) group comprises a vibrant community of faculty, postdocs, and students dedicated to developing the mathematical underpinnings and tools needed to address the aforementioned challenges in a principled and theory-guided manner.

Biotechnology
Computational Science and Engineering
Energy Systems
Image Analysis
Information Theory and Communications
Optimization
Remote Sensing

Physical Electronics, Devices, and Plasma Science

Work in this area applies the physics of electromagnetism, quantum mechanics, and the solid state to implement devices and systems for applications including energy, quantum technologies, sensing, communication, and computation. Our efforts span theory and development of new electronic and optical devices and materials, micro-electromechanical systems, acoustic and optical sensing and imaging, quantum control of individual atoms near absolute zero temperature, and experiments on high-energy plasmas at temperatures close to those at the center of the sun. At Cornell ECE, we work on diverse topics aimed at transforming the way we view the world. Our interdisciplinary research reveals fundamental similarities across problems and prompts new research into some of the most exciting and cutting-edge developments in the field.

Advanced Materials Processing
Astrophysics, Fusion and Plasma Physics
High Energy Density, Plasma Physics and Electromagnetics
Materials Synthesis and Processing
Microfluidics and Microsystems
Nanotechnology
Photonics and Optoelectronics
Semiconductor Physics and Devices
Solid State, Electronics, Optoelectronics and MEMs

Circuits and Electronic Systems

Integrated circuits are ubiquitous and integral to everyday devices, from cellular phones and home appliances to automobiles and satellites. Healthcare, communications, consumer electronics, high-performance scientific computing, and many other fields are creating tremendous new opportunities for innovation in circuits and electronic systems at every level. Research in this area spans topics including analog and mixed signal circuits, RF transceivers, low power interfaces, power electronics and wireless power transfer, and many others.

Micro Nano Systems
Optical Physics and Quantum Information Science

Bio-Electrical Engineering

Biological and Biomedical Electrical Engineering (B2E2) consists of both applied and fundamental work to understand the complexity of biological systems at different scales, e.g., from a single neuronal or cancer cell, all the way to the brain or malignant tumor. B2E2 aims to develop new hardware and computational tools to identify, characterize, and treat diseases. In the physical domain, electrical engineering approaches to integrated microsystems lead to new biological and medical sensors. These sensors consist of state-of-the-art ultrasonic, RF, optical, MRI, CT, electrical impedance transducers.

The integration of sensors, electronics are used to develop implantable and wearable devices, with decreasing size, weight, and power and increased functionality. B2E2 microsystems can help create interfaces for sensing and actuation to help understand the physiological and pathological mechanisms of diseases, and enable advanced robotic interfaces in medicine. Medical devices can generate vast amounts of data, which require both real-time and post-acquisition processing. B2E2 faculty, sometimes in collaboration with medical researchers, develop advanced computational tools to learn from and exploit data and apply artificial intelligence approaches to impact medical practice by improving: early disease detection, disease diagnosis, response to therapy assessment, and guided surgical procedures.

Biomedical Imaging and Instrumentation
Complex Systems, Network Science and Technology
Computer-Aided Diagnosis
Nanobio Applications
Neuroscience

Hardware That Protects Against Software Attacks

ECE's Ed Suh and Zhiru Zhang and CS's Andrew C. Myers aim to develop both hardware architecture and design tools to provide comprehensive and provable security assurance for future computing systems against software-level attacks that exploit seven common vulnerability classes.

Image credit Beatrice Jin

Re-architecting Next-Gen Computing Systems

Disaggregated architectures have the potential to increase resource capacity by 10 to 100 times server-centric architectures.

Re-imagining Computer System Memories

Interdisciplinary team will provide new insights and an entirely new paradigm for the semiconductor industry in the emerging era of big data.

Engineers to hack 50-year-old computing problem with new center

Cornell engineers are part of a national effort to reinvent computing by developing new solutions to the “von Neumann bottleneck,” a feature-turned-problem that is almost as old as the modern computer itself.

Professors Dave Hammer and Bruce Kusse looking at the COBRA machine

The Laboratory of Plasma Studies: Uncovering mysteries of high energy density plasma physics

In the basement of Grumman Hall, an x-ray pulse produced by a hot, dense plasma – an ionized gas – lasting only fractions of a microsecond both begins and ends an experiment. Hidden within that fraction of time lies a piece of a puzzle—data that graduate students and staff scientists at the Laboratory of Plasma Studies (LPS) will use to better understand the mysterious physics behind inertial confinement fusion.

Sophia Rocco working on the COBRA machine

Sophia Rocco: Hoping to make the world a better place through a potential renewable energy source

When she was looking at graduate schools, physics major Sophia Rocco thought she would be in a materials science program bridging her interests in electricity and magnetism and novel materials for solar cells. Chancing upon the School of Electrical and Computer Engineering at Cornell, she discovered the Laboratory of Plasma Studies (LPS).

The Laboratory of Plasma Studies with the COBRA machine in the foreground and students in the background

Finding the Ultimate Energy Source: Cornell’s Lab of Plasma Studies

Plasma is one of the four fundamental states of matter, but it does not exist freely on the Earth’s surface. It must be artificially generated by heating or subjecting a neutral gas to a strong electromagnetic field. Located in the basement of Grumman Hall are two large pulse-power generators that create plasma by delivering extremely high currents to ordinary matter for short periods. These generators are part of the Lab of Plasma Studies at Cornell University.

Photo credit: Dave Burbank

A schematic, left, of a gallium oxide vertical power field-effect transistor, and a scanning electron microscope image, right, of the transistor, showing a 330-nanometer-wide by 795-nanometer-long channel.

Vertical gallium oxide transistor high in power, efficiency

The research group led by Grace Xing and Debdeep Jena presented research on a new gallium oxide field-effect transistor at a conference at the Massachusetts Institute of Technology May 29-June 1.

Molnar, Jena and Xing join national consortium to develop future cellular infrastructure

Three Cornell faculty will be part of the newly established $27.5 million ComSenTer, a center for converged terahertz communications and sensing.

Faculty members associated with Cornell NeuroNex

Data on the Brain

The NSF has found a willing partner at Cornell University in this quest to create technologies that will allow researchers to image the brain and the nervous system.

[email protected]
+91-97 91 62 64 69

PhD in Electrical Engineering Topics

In general, electrical engineering is denoted as the engineering discipline that is concentrated on the design, application, and study of systems, devices, and equipment that are functional through electromagnetism, electronics, and electricity. In this article, we deliberate the significance of a PhD in electrical engineering topics using the experience of our research professionals. Firstly, we start with the substantial research field based on electrical engineering along with its specifications.

Research Areas in Electrical Engineering

RFID systems
Medical electronics
Antennas and EM modeling
Radar and sonar
Uncooled and coherent wavelength division multiplex technology
Advanced liquid crystal devices
Photonic generation of THz signals
Wireless over fiber devices and systems
Ultrafast photonic devices
Connected electronic and photonic systems
Resistive switching
Laser processing
Diamond electronics
Quantum nanoelectronics
Optical materials and electronic devices
Information security and retrieval
Sensor networks
IP networks
Wireless communications
Telecommunication networks and services
High-speeded optical systems
Optical packet networks
Dense WDM optically routed networks
Large-scale optical networks
Optoelectronic devices and systems

Our research experts are skillful to provide the best research project in electrical engineering systems. Since, they are well-versed in mathematical logic, numerical analysis, time and space analysis, information about latest phd in electrical engineering topics, the tools, and the usage of algorithms and protocols. For instance, if you have selected your area as electrical engineering , at that time you can select your research topic from the following research fields in electrical engineering.

Recent PhD in Electrical Engineering Topics

Research Fields in Electrical Engineering

Electrical materials science
Mechatronics
Renewable energies
Electrochemistry
Nanotechnology
Microwave engineering
Electromagnetics and waves
Power Electronics
Spanning a huge number of specializations
Hardware engineering
Instrumentation and electronics
Signal processing
Radio frequency engineering
Telecommunication engineering
Power engineering
Computer engineering

Above mentioned are the notable research fields in contemporary research based on electrical engineering. The research scholars should select their PhD in electrical engineering topics from the latest research fields. For more research references based on electrical engineering, the research scholars can reach us. Below, we have highlighted the algorithms that are used to implement the research project.

Algorithms in Electrical Engineering

Bayesian learning
Reinforcement learning
Combining multiple learners
Hidden Markov models
Neural networks
Dimensionality reduction
Bayesian decision theory

These are the emerging subjects in electrical engineering that are gaining widespread significance in the research platform. We must aware of the current trends and developments in the research area before presenting the research phd in electrical engineering topics. There are also some expectations from reviewers that you must be sure to satisfy. We have discussed the substantial algorithms that are used in electrical engineering research projects.

Current Trends in Electrical Engineering

Battery charging and discharging control of a hybrid energy system using a microcontroller
TMTDYN: A Matlab package for modeling and control of hybrid rigid continuum robots based on discretized lumped system and reduced order models
Establishment of a smart living environment control system
Renewable energy in sustainable electricity and economic development
Energy models for renewable energy utilization and to replace fossil fuels
A new framework for the advancement of power management strategies in hybrid electric vehicles
Robust power management via learning and game design
Particle swarm optimization for microgrid power management and load scheduling
High voltage driver with a switch capacitor cell and a current sensing resistor for implementing functions of zero voltage switching and overcurrent
A modified Y Source DC/DC converter with high voltage gains and low switch stresses
High voltage gain interleaved boost converter with Anfis-based Mppt controller for fuel cell-based applications
An improved SCADA framework for integrated renewable substations-based microgrid central control systems
Linear LAV-based state estimation integrating hybrid SCADA /PMU measurements
Towards highly efficient state estimation with SCADA measurements in distribution systems
Decentralized constrained optimal control of the multi-machine power system stability improvement
The reduction and power quality improvement in grid-connected PV system
Effect of intermittent power supply on the German power system
Design and implementation of an automated residential water heating system using sustainable energy and PLC techniques
Corporate eco-efficiency and financial performance: evidence from Guinness Nigeria PLC
A novel hybrid fuzzy logic controller-based RFLC for fault limiting in transmission networks and its dynamic analysis
Modified voltage control strategy for DC network with distributed energy storage using a fuzzy logic controller
A solar-powered reconfigurable inverter topology for AC/DC homes with fuzzy logic controller
Inverse kinematic analysis of 4 DOF pick and place arm robot manipulators using a fuzzy logic controller
In DFIG-based WECS connected to the grid using UPQC controlled by fractional order PID and Anfis controllers
Design of optimal PID controller for LFC and AVR in power system using PSO
Simulation 3 DOF RRR robotic manipulator under PID controller
Voltage controller of DC-DC buck-boost converter with proposed PID controller
Design, analysis, and application of a new disturbance rejection PID for uncertain systems
Forecasting methodologies of solar resources and PV power for smart grid energy management
The cooperative internet of things enabled smart grid
Optimal and autonomous incentive-based energy consumption scheduling algorithm for smart grid
Can active learning benefit the smart grid a perspective on overcoming the data scarcity
Smart grid in the context of industry 4.0 an overview of communications technologies and challenges
A survey on smart grid technologies and applications
Control and analysis of microgrid frequency droop with fuzzy-based WECS with EV
Formal requirements for microgrid using Kaos and reference architecture
Implementation of efficient energy generation of microgrid from solar power plant

We have added the above-mentioned as research trends to show and uplift your research skill level. To tell the truth, PhD in electrical engineering topics are an innovative trend set in recent days. There are lots of research topics that are coming up from the recently used applications and research techniques in the electrical engineering field . So, contact us for your requirements in research development. For your reference, our research experts have listed down the pioneering research topics in electrical engineering.

Research PhD in Electrical Engineering Topics

Photonics and optical communications
Sensing devices
Microelectronics and nanoscale engineering
Electronic engineering for agricultural applications
Communication, digital signal processing, and radio networks
Advanced material science and technology development
Resilient energy and multi-energy systems
Robotics systems, artificial intelligence, and automation
Low-costts virtual systems and effective trains
Top speed motors and their topologies
High power virtual systems (HPVPS)
Diagnosing green growth in India
Motor design for aerospace fault tolerant
Designing compressor motors and advanced propulsion science
Renewable energy and hybrid electric aerospace
Drives and controls
DFIG Machines: improving energy efficiencies
Wind turbine generators: 3D temperature mapping
Cost functions for efficient electric vehicle drive systems
Electric vehicles and health monitoring of power semiconductor modules
Switched reluctance motors
Extra functionality devices: advanced technology modeling
Challenges of autonomous power systems
Distributed generation systems: loss detection of grid events via pattern identification
Electric vehicle motors and gearbox
Soft magnetic composites
Smart grid monitoring
Computer-aided design for electrical engineering
Energy networks and their mathematical foundations
Electrical motors and their redesigning
Power electronics tools and equipment
Computation research in new technologies and materials
Studying behavior thru computational modeling
Piezoelectric and ferroelectrics
Using photovoltaic, graphene, and silicon carbide
Atomic layer interface engineering
Design choice in the direct drive of wheel motors
Series connected supercapacitor and li-ion capacitor cells for the active voltage equalization
PM machines with high power and speed

Along with that, our research professionals have enlisted the notable research phd in electrical engineering topics its implementation process in the following.

Project Topics in Electrical Engineering

Solar panel is deployed to charge the battery and the operational amplifiers are utilized to monitor the voltage along with the LED to monitor the condition of the battery
It is the integrated control of lighting appliances and heating, ventilation, and air conditioning (HVAC). In addition, Arduino is deployed to regulate home appliances through remote
It is used to implement the circuits with the mechanical loads in the average speed
It is deployed to enhance the power factor through the set of capacitors that are connected parallel to switch the capacitors and that is functional as per the value of power factor
It is used to switch the room light when a person gets in and switch it off when he leaves the room. Consequently, it displays on the LCD about the person’s entry

The research scholars will be overwhelmed to know that still there are lots and many more phd in electrical engineering topics being developed now and then depending on the real-time requirements. In addition, we have enlisted the list of simulation tools used in the research implementation.

Simulation Tools in Electrical Engineering

The laboratory virtual instrument engineering workbench is abbreviated as LabVIEW and it is the engineering software system. It is deployed to access the data insights and hardware
Personal simulation program with integrated circuit emphasis is abbreviated as PSPICE. It is used for the simulation and authentication process of the mixed signal and analog circuits
It is deployed to implement the graphical simulation along with the specific toolboxes for the electric transients, transmission line, and switches for power supply, simulating and analyzing the renewable energy sources
Solar advisor model in Simulink
Wind turbine model in Simulink
Its toolboxes offer various functions such as curve fitting, system identification, control system design, linear algebra, linear system implementation, optimization, etc.

The following is about the questions along with their appropriate answers and these are the questions that are frequently asked by research scholars to develop their research skills in electrical engineering. In addition, our research experts have answered these questions through their years of experience in this field.

Questions based on Electrical Engineering Research

What are the different types of power electronics.

AC to AC converters
DC to AC converters
DC to DC converters
AC to DC converters

Which project is best for electrical engineering?

PLC and SCADA-based traffic control system
Photovoltaic solar power generation with maximum power point tracking
Zigbee based solar powered forest fire detection and control system
GSM-based substation monitoring and control system
Android-based electrical appliance control

What are the current research topics in renewable energy?

Think tank platform for the renewable energy industry
Membrane-enhanced reforming technology
Bio-oil production from biomass pyrolysis technology
Lignocellulose hydrolysis technology
Design and construction of biodiesel production plant

Our research professionals are providing the finest research assistance for research students based on electrical and electronics engineering and electrical and communication engineering. While guiding the PhD scholars, we used to follow and provide the following processes.

Preparation of research topic and proposal
Paper preparation and publication support
Annexure II
Demonstration for the proposed research
Provision of synopsis
Thesis will be written along with the support of research scholars

The research projects based on electrical engineering are rendering online guidance to make research projects , pile up the assignments, implementation process, homework help, paper publication, thesis writing, phd in electrical engineering topics and much more. We have well-experienced subject-specific experts, developers, and so on who are contented to help the research scholars at all times. You can connect with us to aid more and our 24/7 customer care support is ready to offer assistance always. So, ping us to acquire the finest knowledge.

Opening Hours

Mon-Sat 09.00 am – 6.30 pm
Lunch Time 12.30 pm – 01.30 pm
Break Time 04.00 pm – 04.30 pm
18 years service excellence
40+ country reach
36+ university mou
194+ college mou
6000+ happy customers
100+ employees
240+ writers
60+ developers
45+ researchers
540+ Journal tieup

Payment Options

Our Clients

Social Links

Opening Time

Closing Time

We follow Indian time zone

Have any questions?
+91-9176966446
[email protected]

PhD Topic Selection
Problem Identification
Research Proposal
Pilot Study
PhD. Dissertation (Full)
Ph.D. Dissertation (Part)
Phd-Consultation
PhD Coursework Abstract Writing Help
Interim-Report
Synopsis Preparation
Power Point
References Collection
Conceptual Framework
Theoretical Framework
Annotated Bibliography
Theorem Development
Gap Identification
Research Design
Sample Size
Power Calculation
Qualitative Methodology
Quantitative Methodology
Primary Data Collection
Secondary Data Collection
Quantitative Statistics
Textual / Content Analysis
Biostatistics
Econometrics
Big Data Analytics
Software Programming
Computer Programming
Translation
Transcription
Plagiarism Correction
Formatting & Referencing
Manuscript Rewriting
Manuscript Copyediting
Manuscript Peer Reviewing
Manuscript Statistics
PhD Manuscript Formatting Referencing
Manuscript Plagiarism Correction
Manuscript Editorial Comment Help
Conference & Seminar Paper
Writing for a journal
Academic Statistics
Journal Manuscript Writing
Research Methodology
PhD Animation Services
Academic Law Writing
Business & Management
Engineering & Technology
Arts & Humanities
Economics & Finance Academic
Biological & Life Science
Medicine & Healthcare
Computer Science & Information
HIRE A RESEARCH ASSISTANT

Research topics in electronics and electrical engineering

Electronics and electrical engineering are the studies of harnessing electricity and the electromagnetic spectrum to enhance the lives of human beings. It is exciting and futuristic to think about significant technological advancements and electronic technology breakthroughs like smart grid systems, electronic vehicles, sustainable power consumption, wireless wearables, robotics, artificial intelligence (AI), AR (Augmented Reality), VR (Virtual Reality), and the Industrial Internet of Things (IIoT). Advanced developments in technology for electronics research and development contribute to the efficient use of energy for our daily needs. PhD Assistance may assist you in selecting the latest topic for study in electronics and electrical engineering.

Here are some of the topic research topics in electronics and electrical engineering.

Electrical engineering topics include the following:

Study on the use of a modified PNN classifier with SMO optimization techniques for diagnosing the severity of skin cancer conditions
A study on battery integrated multiple input DC-DC boost converter
A study on the impact of Evaluation of compact fluorescent lights in a 50 Hz electrical network
A Systematic Evaluation of deep neural network-based dynamic modelling method for AC power electronic systems:
A Review of 2D van der Waals Devices Using Electronic Modulation of Semimetallic Electrode
A Study on frequency stability of hybrid industrial microgrids using optimal fractional sliding mode
Review on Latent Features of Neural Network Design for Power Electronic Systems Using Impedance Modelling
Understanding Effective Power Electronics Using Circuit Simulation
First-principles calculations of phosphorus-doped SnO2 transparent conducting oxide: Structural, electronic, and electrical properties
Adaptive position control of a brush-based DC motor
Implementation of an A-Source DC–DC Boost Combination Phase-Shifting Full-Bridge Converter for Electric Car Rapid Charging Applications
PM machines with high power and high speed.
Series connected super-capacitor and li-ion capacitor cells: active voltage equalisation.
Design choice in the direct drive in-wheel motors.
Reluctance Motors.
Nanoelectronics.
Atomic layer interface engineering.
Using photovoltaics, graphene, and silicon carbide.
Piezoelectrics and ferroelectrics.
Studying behaviour thru computational modelling.
Computation research in new technologies, materials.
Power electronics tools and equipment.
Electrical motors and their redesigning.
Energy networks and their mathematical foundations.
Computer-aided design for electrical engineering.
Smart grid monitoring.
Soft magnetic composites.
Electric vehicle motors and gearbox.
Distributed generation systems: loss detection of grid events via pattern identification.
Challenges of autonomous power systems.
Extra-functionality devices: advanced technology modelling.
Switched reluctance motors.
Electric vehicles and health monitoring of power semiconductor modules.
Cost Functions for Efficient Electrics Vehicle Drive Systems.
Wind Turbine Generators: 3D temperature mapping.
DFIG Machines: improving energy efficiencies.
Power electronics.
Drives and controls.
Power systems and energy storage.
Hybrid electric aerospace.
Renewable energy.
Advanced propulsion science.
Designing compressor motors.
Motor design for aerospace—fault tolerant.
Wind turbine energy technologies.
Diagnosing green growth in India.
HPVPS stages (high power virtual systems).
Top speed motors and their topologies.
Low cost effective trains.
Low-cost virtual systems.

Need Guidance on how the topic selection would be, check our topic selection examples !

Also, to get assistance on thesis topics in dissertation topics in microbiology, dissertation topics in English literature, interior design thesis topics, physiotherapy research topics, llm dissertation topics, sociology dissertation topics, criminal law dissertation topics, political science dissertation topics, dissertation topics in pediatrics, microbiology thesis topics, thesis topics in psychiatry, cardiology thesis topics, dissertation topics in education, dissertation topics for M.SC microbiology, dissertation topics in education, geography dissertation topics, interior design dissertation topics, pharmacology thesis topics, Avail our Ph.D topic selection support service today!

Need help with your Dissertation Service?

Take a look at topic selection service:

Click Here!

Quick Contact

Dissertation.

Our Dissertation Writing service can help with everything from full dissertations to individual chapters.

Literature Review

Referencing Tools

Harvard Referencing Tool
Vancouver Referencing Tool
APA Referencing Tool

Privacy Overview
Strictly Necessary Cookies
3rd Party Cookies

This website uses cookies so that we can provide you with the best user experience possible. Cookie information is stored in your browser and performs functions such as recognising you when you return to our website and helping our team to understand which sections of the website you find most interesting and useful.

Strictly Necessary Cookie should be enabled at all times so that we can save your preferences for cookie settings.

If you disable this cookie, we will not be able to save your preferences. This means that every time you visit this website you will need to enable or disable cookies again.

This website uses Google Analytics to collect anonymous information such as the number of visitors to the site, and the most popular pages.

Keeping this cookie enabled helps us to improve our website.

Please enable Strictly Necessary Cookies first so that we can save your preferences!

BSc/HND Project Topics
MSc/PhD Project Topics
Source Codes
Project Ideas

Masters Electrical Engineering Final Year Project Research Topics

Electrical Engineering Project Topic: Electrical engineering project topics and research materials are born out of the research ideas that come into bear during students’ practical seasons in school. Weather achieved through collective effort or individual effort, final year projects in electrical engineering are most of the time exhibited or constructed, just as the case may be. Electrical engineering project topics are driven to solve technical problems especially such that surround electrical hardware and software. Project topics of this course of study should yield to the research procedures stipulated by institutions. Moreso, project topics of electrical engineering should be subject to scrutiny by the project supervisor to ensure that the right research procedure for presenting undergraduate research is followed with caution.

Filters: Undergraduate (HND,BSc,BTech) Masters (MSc,MTech) PhD Thesis

Electrical Engineering Research Project Topics with a index have Instant Download

Quick project topic search.


S/N	Project Topic
Item Type & Format: \| 52 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 200 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 333 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 121 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 125 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 152 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 127 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 83 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 105 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 120 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 133 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 135 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 170 pages \| \| Chapter 1-5 \|

Cannot find your topic?.. Search for the Project Topic now. It saves time and it is easy

Download MASTERS Electrical Engineering Final Year Research Project Topics - Free Project Topics | Codemint and Research Materials. Get Complete Chapter 1-5 Project Materials and Research Topics for HND, BSc, MSc in Doc & PDF. Final Year Projects and Research Materials on CodeMint

Find Your Department Here

Thank you for visiting nature.com. You are using a browser version with limited support for CSS. To obtain the best experience, we recommend you use a more up to date browser (or turn off compatibility mode in Internet Explorer). In the meantime, to ensure continued support, we are displaying the site without styles and JavaScript.

View all journals
Explore content
About the journal
Publish with us
Sign up for alerts
Published: 17 June 2024

Time to talk with industry

Nature Reviews Electrical Engineering volume 1 , page 349 ( 2024 ) Cite this article

65 Accesses

Metrics details

Sharing of knowledge created by industry through appropriate publishing practices could help deep-tech companies improve their corporate image, stimulate creativity and lure top talent without putting their intellectual property at risk.

The concept of ‘priority’, which implies that the one announcing a new discovery receives the benefits of that discovery, underlies advances in scientific knowledge and serves as the basis of the reward system in academic research. In other words, once the result is reported, the author’s contribution must be acknowledged by the scientific community, especially by those who intend to build upon this discovery. Therefore, a claim of priority encourages scientific discoveries and hastens their disclosure, which takes place mainly through scientific publishing. Industrial researchers, on the other hand, do not adhere to the ‘publish or perish’ mindset and have a rather different perspective on the value added through publication, tending to stay vigilant in view of the risks associated with potential knowledge spillover.

To this end, patenting has been used by industry as a standard procedure for protecting intellectual property. However, filing a patent application considerably delays the publication process and thereby undermines the concept of priority. It is also worth noting that some companies actively discourage or even prohibit scientific publication. For example, deep-tech companies that are developing strategically important technologies, those that have the potential of an immediate and profound impact on society, such as chip manufacturers, have little interest in openly discussing their innovations. Instead, to announce the latest news on their products and engineering innovations behind the breakthroughs, companies opt for press releases and short conference papers and presentations, with a level of detail that leaves plenty of room for confidentiality. Yet it is the advances on the cutting edge of engineering research that are of the most interest and value to the scientific communities working on the relevant emerging technologies and, by association, to the scientific journals that are eager, but often unable, to publish these results.

Although there is no shortage of examples showing the clear value of scientific publishing for the firms that encourage these practices, understanding of the incentives that drive private R&D companies to ultimately engage in disclosure of scientific knowledge remains rather limited. The 1995 study by Hicks (D. Hicks, Ind. Corp. Chang. 4 , 401–424; 1995) is commonly viewed as the original systematic examination of the topic, in which the author presents several arguments in support of their decision to publish. First, building scientific credibility through publications is commonly used by the private sector to engage with academic researchers, with an eye to establishing collaborations and attracting and retaining talent. Moreover, publishing is often seen as highly rewarding for employees who seek to establish their scientific reputation and see a strong publication record as an asset for career progression.

Also, there is a clear correlation between the professional and educational background of company founders and the company’s attitude towards publishing. Generally, a company with more PhD-holding entrepreneurs at the executive level is likely to have a solid publication output and to have a positive outlook on scientific publishing. Among other factors that motivate the dissemination of industrial research are the exclusion of competitors from patent races and choosing patent–paper pairs as an effective disclosure strategy with a low risk of knowledge spillover. Moreover, firms that require access to scientific knowledge to ensure their innovation are, unsurprisingly, more open to adopting academic principles.

However, the establishment of collaborative ties with academic institutions is not a strong determinant. In electrical engineering, the attitude of private R&D companies towards publishing varies greatly and, from our outreach experience and some rather anecdotal evidence, the likelihood of engaging in publishing depends largely on their management’s views on the overall benefits of sharing research results through publication. According to Nature Index , for physical sciences, the universities with the highest research output publish ten times more articles than the most active corporate organizations. Indeed, only a few companies publish more than 100 papers every year, with the rest being far behind. The research output of the leading chip manufacturers, such as TSMC, Samsung and Intel, is vanishingly low and has not changed in the past 5 years. There can be many possible explanations for this observation. However, with no clear picture, it is our role as a publisher to initiate a much-needed discussion with the semiconductor industry and other industries about the barriers that separate industrial research and scientific publishing.

“We want to hear industry’s opinion on the perceived benefits and risks of publishing to identify the barriers that prevent the dissemination of industrial research in top scientific journals”

We want to hear industry’s opinion on the perceived benefits and risks of publishing to identify the barriers that prevent the dissemination of industrial research in top scientific journals and to understand how scientific publishers can support more publication of engineering research. We feel certain that deeper collaboration between industry and publishers will precipitate better understanding and mutual benefits of knowledge sharing.

Rights and permissions

Reprints and permissions

About this article

Cite this article.

Time to talk with industry. Nat Rev Electr Eng 1 , 349 (2024). https://doi.org/10.1038/s44287-024-00067-0

Download citation

Published : 17 June 2024

Issue Date : June 2024

DOI : https://doi.org/10.1038/s44287-024-00067-0

Share this article

Anyone you share the following link with will be able to read this content:

Sorry, a shareable link is not currently available for this article.

Provided by the Springer Nature SharedIt content-sharing initiative

Quick links

Explore articles by subject
Guide to authors
Editorial policies

MyU : For Students, Faculty, and Staff

Hüsrev Cılasun, Alireza Khataei, and Siliang Zeng awarded doctoral dissertation fellowships

Maroon flag with "We are driven" hanging in a backdrop of trees in autumnal foliage

Doctoral candidates Hüsrev Cılasun, Alireza Khataei, and Siliang Zeng are recipients of the Graduate School’s 2024-2025 doctoral dissertation fellowship (DDF) award. The fellowship gives the University's most accomplished doctoral candidates an opportunity to devote full-time effort to an outstanding research project by providing time to finalize and write a dissertation during the fellowship year.

Portrait of Husrev Cilasun standing against a pale wall, in a striped shirt smiling into camera

Hüsrev Cılasun is conducting his doctoral research under the guidance of Professor Ulya Karpuzcu, and is exploring novel and unconventional ways of computing with spin, the angular momentum of physical particles. He is working on two distinct aspects of such computation. The first one deals with using actual magnetic spins to enable several orders of magnitude higher performance and energy efficiency than conventional computers, while preserving data privacy and fault tolerance for emerging big data problems in, for instance, genomics. The second aspect uses abstract models of spins to solve large scale combinatorial optimization problems which are present in numerous applications in our lives, ranging from robotics, airline scheduling, logistics (determining ideal routes for package delivery) to chip design (finding the best way to draw a chip layout). All of these problems are hard to solve and characterized by several constraints. Cılasun’s research goal is to explore the design space of spin-based computing systems to solve existing problems more efficiently using significantly less resources (including energy) and to solve new problems that no conventional system can due to physical resource limitations.

Alireza Khataei standing outdoors against a blue sky wearing a gray shirt smiling into camera

Alireza Khataei has been working on his research under the guidance of Professor Kia Bazargan. Khataei’s research is located at the intersection of innovative data encoding and highly optimized hardware to perform computations with limited hardware resources. The goal is to accelerate compute-intensive applications such as neural networks and image processing. His work stems from the recent explosion of machine learning applications and the growth in AI computation complexity. These developments are the result of advances in hardware speed and innovations in neural network models. However, both the training of the network as well processing the many millions of user prompts entail massive amounts of computation, which requires the support of hardware that can stand up to the challenge. Hardware accelerators are specially designed computation units inside processors that target specific types of computation and are particularly critical for handling the anticipated growth and complexity of neural networks. Khataei’s research targets hardware acceleration, developing innovative solutions to improve the costs associated with computation in terms of time and power.

Siliang Zeng outdoors in a white zip up sweatshirt, leaning down smiling into camera

Siliang Zeng ’s research is focused on aligning artificial intelligence (AI) systems with human preferences, context, social norms, and other values. Working under the guidance of Professor Mingyi Hong, Zeng’s work develops a comprehensive framework, including formulation, algorithms, and customization to and for specific applications. This will allow AI systems to effectively learn from humans for a wide range of tasks. He addresses critical challenges such as the effective integration of diverse human generated data to build an aligned system, enabling AI systems to continuously learn and adapt to changing contexts and norms, and transparency of AI systems so users can understand and trust them.

Learn more about our graduate programs

Know more about our research areas

Additional student and alumni news

Get the Reddit app

A place to ask questions, discuss topics and share projects related to Electrical Engineering.

Hot topics in EE right now

I am looking for a bachelor's thesis right now. What are the hottest topics in EE right now? Where would it be useful to do a thesis in? I am interested in signal processing, telecommunication and RF. Not so much in integrated circuits and power engineering.

IMAGES

100+ Recent & Hot Electrical Engineering Research Topics
50 Suggested Research Topics/ Titles for Electrical Engineering
100+ Electrical Engineering Research Topics
Top 10 Interesting Research Topics in Electrical Engineering Domain
Top 30+ PhD in Electrical Engineering Topics [Recently Updated]
PPT

VIDEO

Top 10 Electrical Seminar Topics 2023
Electrical Engineering useful tips 4 #generation #ksebsubengineer
Electrical seminar topics 2023
top electrical project ideas for engineering students
Research Topics in Business Management
SEMINAR TOPICS FOR ELECTRICAL ENGINEERING(PART 2)

COMMENTS

100+ Recent & Hot Electrical Engineering Research Topics
Topics include developing fast internet networks, smart Bluetooth devices, and GPS systems. Other topics focus on building tiny electronic chips inside computers and phones. Researchers also work on voice technologies, self-driving cars, drones, and more. In essence, electrical engineering researchers focus on a wide variety of subjects.
Top 75 Emerging Research Topics in Electrical Engineering
1.1 Smart Grids and Micro-grids. a. Distributed control strategies for micro-grid management. b. Blockchain applications for secure energy transactions in smart grids. c. Resilience and robustness enhancement in smart grid systems against cyber threats. d. Integration of renewable energy sources in micro-grids. e.
PDF Electrical Engineering Research Topics
Here is a list of 100+ hot and interesting electrical engineering research topics: Advanced Power Electronics for Renewable Energy Systems Smart Grid Technologies and Integration Energy Harvesting from Ambient Sources. Internet of Things (IoT) for Electrical Systems. Artificial Intelligence Applications in Power Systems.
Electrical and electronic engineering
Find the latest research and news on electrical and electronic engineering from Nature Portfolio, covering various topics and applications.
5 Electrical Engineering Research Projects Making Their Mark in 2024
March 08, 2024 by Jake Hertz. From 3D processors to self-powered sensors, these academic research projects show how "the next big thing" in electronics may emerge from labs worldwide. Many of the most influential hardware companies can trace their origins back to a university lab. Even RISC-V, the open-source ISA taking the hardware world by ...
Browse Articles
This Review discusses the state-of-the-art power electronics in electric vehicles based on Si, SiC and GaN from an industry perspective, with a particular focus on the module power densities ...
Electrical and electronic engineering
All-analog photoelectronic chip for high-speed vision tasks. An all-analog chip combining electronic and light computing achieves systemic energy efficiency of more than three orders of magnitude ...
Explore all research areas
Artificial Intelligence and Machine Learning. Our research covers a wide range of topics of this fast-evolving field, advancing how machines learn, predict, and control, while also making them secure, robust and trustworthy. Research covers both the theory and applications of ML. This broad area studies ML theory (algorithms, optimization ...
306723 PDFs
Explore the latest full-text research PDFs, articles, conference papers, preprints and more on ELECTRICAL ENGINEERING. Find methods information, sources, references or conduct a literature review ...
Advanced Technologies for Electrical Engineering
Energy crisis and environmental pollution are two major themes currently faced by human society. The construction of a strong smart grid with super/ultra-high voltage network as the backbone and clean energy transmission as the leading shows a more important strategic role than ever since. However, the rapid development of clean and renewable energy technologies represented by wind and solar ...
Electronics Letters: Vol 60, No 12
Electronics Letters is an interdisciplinary, rapid-communication journal covering the latest developments in all electronic and electrical engineering related fields. Electronics Letters: Vol 60, No 12
Top 10 Interesting Research Topics in Electrical Engineering Domain
Disconnector. It is used to isolate the circuits in the form of high / medium voltages. Circuit Breaker. It resets the fuse when power over supplied in the switches. Humidistat. It is a component in which humidity is measured. Thermostat. It is a thermal electrical component. Reed Switch.
100 New Research Topics in Electrical and Electronics Engineering
A presentation of 100 research topics in Electrical and Electronics Engineering, with a brief description of the topic. Discover the world's research 25+ million members
Volume II: Challenges and Research Trends of Electrical Engineering and
Institute of Theory of Electrical Engineering, Measurement and Information Systems, Faculty of Electrical Engineering, Warsaw University of Technology, 00-662 Warsaw, Poland Interests: electrical engineering; design engineering; sensors; wsn; energy harvesting Special Issues, Collections and Topics in MDPI journals
Researches and Projects (RaP)
EEP's section Researched and Projects encourages every research scholar, professors, faculty members and research students to publish their research papers on EEP. EEP's goal is to promote scientific research in electrical engineering in general, power substation, transformers, HVAC, maintenance of electrical equipment, industry automation ...
100+ Electrical Engineering Research Topics
Top Research Topics for Electrical Engineering Students. For your convenience, we have compiled here a list of the top 100 electrical engineering project ideas in 2021. Distance Locator for an underground cable fault. An analysis of battery energy storage (BES) systems financial incentive policies. Photovoltaic conversion efficiency improvement ...
Electrical and electronic engineering
Read the latest Research articles in Electrical and electronic engineering from Scientific Reports
Research
Facilities and Equipment Use. UNT's Electrical Engineering labs offer a wide variety of research opportunities and experiences for all of our students. Institutional labs can be used by any student, with or without faculty supervision, for any projects. As the name suggests, these often double as classrooms. Research labs are under the direct ...
Strategic Research Areas
Strategic Research Areas. Research in Electrical and Computer Engineering covers an extremely broad range of topics. Whether in computer architecture, energy and power systems or in nanotechnology devices, the research conducted in ECE is at the cutting edge of technological and scientific developments. Research. Strategic Research Areas.
Top 30+ PhD in Electrical Engineering Topics [Recently Updated]
In general, electrical engineering is denoted as the engineering discipline that is concentrated on the design, application, and study of systems, devices, and equipment that are functional through electromagnetism, electronics, and electricity. In this article, we deliberate the significance of a PhD in electrical engineering topics using the experience of our research professionals.
Research topics in electronics and electrical engineering
Piezoelectrics and ferroelectrics. Studying behaviour thru computational modelling. Computation research in new technologies, materials. Power electronics tools and equipment. Electrical motors and their redesigning. Energy networks and their mathematical foundations. Computer-aided design for electrical engineering. Smart grid monitoring.
New Research Topics for Electrical & Power Electronics Engineering
🎁 Let's become a patron on my content 🙂 ⬇️ https://www.patreon.com/eduguideaHi guys, In this video, I talked about New research topics for #Elect...
Electrical Engineering Final Year Research Project Topics
Electrical Engineering Project Topic: Electrical engineering project topics and research materials are born out of the research ideas that come into bear during students' practical seasons in school. Weather achieved through collective effort or individual effort, final year projects in electrical engineering are most of the time exhibited or constructed, just as the case may be.
Time to talk with industry
The 1995 study by Hicks (D. Hicks, Ind. Corp. Chang. 4, 401-424; 1995) is commonly viewed as the original systematic examination of the topic, in which the author presents several arguments in ...
Hüsrev Cılasun, Alireza Khataei, and Siliang Zeng awarded doctoral
Hüsrev Cılasun is conducting his doctoral research under the guidance of Professor Ulya Karpuzcu, and is exploring novel and unconventional ways of computing with spin, the angular momentum of physical particles. He is working on two distinct aspects of such computation. The first one deals with using actual magnetic spins to enable several orders of magnitude higher performance and energy ...
Hot topics in EE right now : r/ElectricalEngineering
Properly hyped. AI is becoming Open Source, easy to use, and highly funded. The amount of people doing masters and PhD's with an element of AI (CS, ECE, ME, CivE, business degrees, biology, medicine, etc) is significantly rising just by looking at the amount of academic research and private/industry research being done.
Welcome to Worship
Welcome to Worship | June 09, 2024 Creator God, we marvel in awe of the expansiveness of Your creation ~ Welcome to the Worship of God with First...


S/N	Project Topic
Item Type & Format: \| 52 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 200 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 333 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 121 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 125 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 152 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 127 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 83 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 105 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 120 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 133 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 135 pages \| \| Chapter 1-5 \|
Item Type & Format: \| 170 pages \| \| Chapter 1-5 \|

Top 75 Emerging Research Topics in Electrical Engineering