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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.
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 using the sparse matrix converter
- Multiphase power and DC power transmission
- SVPWM inverter harmonic elimination
- Electric cars Regenerative braking efficiency improvement
- UPS systems issues in power quality
- Techno-environmental feasibility assessment of a standalone photovoltaic system
- Electric Scooter Simulation model
- Load-leveling economical analysis using EV
- Energy minimization algorithm for an electric car with many motors
- Minimization of Switching loss in the grid-connected system
- Economic analysis and a battery’s life analysis with the supercapacitor
- Protection System for an induction motor
- A high-efficiency PLC boiler control system
- SMART cities and IoT
- Electric scooter Performance analysis using different motors
- Semantics, knowledge management, and data acquisition using IoT
- Technologies of Network virtualization
- IoT home networks
- Electrical Appliance Control with Android
- The cost-benefit analysis of energy projects on grid-scale: A case study
- Detection of the arcing fault in the electrical systems
- Induction motor map development for efficiency
- A sensitivity analysis for the parameters vehicle design
- Research on electrical loads in the public and residential buildings
- Comparative Analysis and Calculation Methods of the Losses in the electrical energy in low-voltage devices
- Hybrid charging stations powered with solar energy
- IoT smart energy meter
- Wind-power generation using a synchronous generator with permanent magnet
- Off-grid rural areas applications using a switched reluctance machine
- Analysis and design of a magnetless multiphase dc-field machine to generate wind power
- Smart home electric energy management
- A techno-economic viability assessment of a decoupled energy storage
- A techno-economic optimization and modeling of storage-based PV power generation systems
- A technical model for the lithium-ion storage for biogas and PV energy system
- An analysis of transparent power grids
- Battery life and efficiency of regenerative braking
- Economic and life analysis of a battery with the supercapacitor
- EV home charging using the load-leveling algorithm
- In-Vivo Imaging of the cancer cells using the Fluorescent Microscopy
- Use of Dynamic Instrumentation for analyzing WhatsApp security
- Smart grid architecture design
- Use of PID controller for IM torque control
- Design of a hybrid power system
- Use of FIXCOM for designing a 3-level inverter
- Harvesting solar energy from a solar-powered satellite
- Use of microcontroller for battery discharging and charging of hybrid energy system
- Analysis and modeling of electrical gripper’s DC motor actuator
- Use of a brushless DC motor for Zeta converter’s power quality improvement
- Use of a three-phase Inverter based on Thyristor for simulation and control of a DC motor
- Use of PI Controller for designing a PLC speed control DC motor
- Use of PID controller for speed control of a DC motor: a comparative study
- Front-End ASICs power management circuits
- Off-Grid renewable energy’s remote monitoring system
- Non- Renewable and Renewable Energy Resources comparative analysis
- Development of Green Building for harvesting renewable energy
- Low carbon achievement: a case study
- Use of PSO for load dispatch in case of renewable uncertainties
- The hot climate and Vertical axis wind turbine relationship and consequence
- Use of fuzzy control for efficient electrical energy management
- Degradation in the performance of PV panel performance and shading effect: a case study
- Solar angles simulation to maximize solar thermal collectors efficiency
- Use of Node MCU for active solar tracking
- Different techniques for DC networks with low voltage
- Waste Management Approach based on information
- Grid-Connected Solar PV System with decoupled control
- Electric vehicle life analysis
- Use of ADVISOR for minimizing EV energy consumption
- Field data examination of energy consumption for an electric scooter
- Use of an electric car for peak load shaving
- Effect of the temperature on PV energy conversion
- Digital Signal process control system for motors
- Use of EMTDC/ PSCAD for evaluation of harmonic analysis and filter design
- Load flow analysis of integrated DC/ AC power system using newton-raphson method
- Auto-Irrigation System development using solar power
- DC motor speed control unit design
- Protection System design for under-voltage
- Protection System design for over-voltage
- Silicon robot based on solar power
- 3-phase grid-connected PV systems simulation and design
- Analysis of brushless servo motors
- Grid-connected PV systems multilevel inverter simulation
- MIMO transformer models
- Fault detection in 3 phase transmission lines
- An optimization technique for flexible load scheduling
- Design of remote terminal unit for secure control of power
- Use of the artificial neural network for 3-phase fault detection
- Design of electrical substation earthing system
- Microgrid integration in the power transmission lines
- Induction motor temperature and material selection
- Open-loop simulation for an optimal vehicle simulation and design
- Use of STATCOM for improving the transient stability of a power grid
- Peak load management using Vehicle to Grid system
- Image sensing for a closed-loop traffic control system
- Arduino based smart home automation system
- 3 phase induction motor controlled by SVPWM in an electric vehicle
- Increasing the efficiency of a superconducting transformer
- An analysis of (SCADA) System in Power Stations
Research topics for electrical engineering can be exciting yet challenging to find at the same time as they require a lot of time for thorough research and writing. Moreover, the topic and the desired approach can a lot of time to be finalized. Keeping this hassle in view, we have compiled a list of the top 100 electrical engineering research paper topics in a single article to save your time. We will also keep updating the list to include some more latest and fresh research topics related to electrical engineering.
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Power Systems Research Topics Ideas for MS/PhD
List of power systems research topics ideas for ms/phd thesis.
1. Introduction and literature review of power system challenges and issues 2. Power system inertia estimation: Review of methods and the impacts of converter-interfaced generations 3. Artificial intelligence models in power system analysis 4. Power system protection 5. Technical barriers for harnessing the green hydrogen: A power system perspective 6. Evolutionary game analysis on behavior strategies of multiple stakeholders in maritime shore power system 7. Optimal analysis of a hybrid renewable power system for a remote island 8. Evaluation and optimization of off-grid and on-grid photovoltaic power system for typical household electrification 9. Comprehensive performance evaluation and demands’ sensitivity analysis of different optimum sizing strategies for a combined cooling, heating, and power system 10. Comprehensive weight method based on game theory for identify critical transmission lines in power system
11. Integrated standalone hybrid solar PV, fuel cell and diesel generator power system for battery or super capacitor storage systems in Khor fakkan, United Arab Emirates 12. Power system stability in the transition to a low carbon grid: A techno-economic perspective on challenges and opportunities 13. Multi-objective jellyfish search optimizer for efficient power system operation based on multi-dimensional OPF framework 14. Power system hybrid dynamic economic emission dispatch with wind energy based on improved sailfish algorithm 15. Voltage stability analysis of power system 16. Coordinated automatic generation control of interconnected power system with imitation guided exploration multi-agent deep reinforcement learning 17. Load frequency control based on the bees algorithm for the great britain power system 18. Multi-level interactive unit commitment of regional power system 19. Maiden application of fuzzy-2DOFTID controller in unified voltage-frequency control of power system 20. Networkâconstrained rail transportation and power system scheduling with mobile battery energy storage under a multiâobjective twoâstage stochastic programming
21. Fuel-cell sharing for a distributed hybrid power system 22. A sustainable energy distribution configuration for microgrids integrated to the national grid using back-to-back converters in a renewable power system 23. An optimization-based strategy for solving optimal power flow problems in a power system integrated with stochastic solar and wind power energy 24. Impact of fossil-free decentralized heating on northern European renewable energy deployment and the power system 25. Investigation and damping of electromechanical oscillations for grid integrated micro grid by a novel coordinated governor-fractional power system stabilizer 26. Improving the Accuracy of the State Estimation Algorithm in the Power System Based on the Location of PMUs and Voltage Angle Relationships 27. The near-optimal feasible space of a renewable power system model 28. Multi-objective optimization of a combined cooling, heating, and power system with subcooled compressed air energy storage considering off-design characteristics 29. Near-Optimal PI Controllers of STATCOM for Efficient Hybrid Renewable Power System 30. ‘Cooperative game’inspired approach for multi-area power system security management taking advantage of grid flexibilities
31. Exergo-economic assessment and sensitivity analysis of a solar-driven combined cooling, heating and power system with organic Rankine cycle and absorption heat ⊠32. Equilibrium optimizerâtuned cascade fractionalâorder 3DOFâPID controller in load frequency control of power system having renewable energy resource integrated 33. Analytical model of power system hardening planning for long-term risk reduction 34. An Optimal Control of Integrated Hybrid Power System with FACTS Devices Using Student PsychologyâBased Optimization Algorithm 35. Robust delay-dependent load frequency control of wind power system based on a novel reconstructed model 36. Power system harmonics 37. Increasing Turkey’s power system flexibility for grid integration of 50% renewable energy share 38. Preliminary propulsion and power system design of a tandem-wing long-range eVTOL aircraft 39. Efficient creation of datasets for data-driven power system applications 40. MVO algorithm based LFC design of a six-area hybrid diverse power system integrating IPFC and RFB
41. Optimal performance of a combined heat-power system with a proton exchange membrane fuel cell using a developed marine predators algorithm 42. A modified moth flame optimisation technique tuned adaptive fuzzy logic PID controller for frequency regulation of an autonomous power system 43. A techno-economic viability analysis of the two-axis tracking grid-connected photovoltaic power system for 25 selected coastal mediterranean cities 44. Decentralized data-enabled predictive control for power system oscillation damping 45. Optimal Design of Biomass Combined Heat and Power System Using Fuzzy Multi-Objective Optimisation: Considering System Flexibility, Reliability, and Cost 46. Design Methodology and Parametric Design Study of the On-Board Electrical Power System for Hybrid Electric Aircraft Propulsion 47. A novel sine augmented scaled sine cosine algorithm for frequency control issues of a hybrid distributed two-area power system 48. Sunflower optimization based fractional order fuzzy PID controller for frequency regulation of solar-wind integrated power system with hydrogen aqua equalizer-fuel ⊠49. Optimal scheduling for power system peak load regulation considering short-time startup and shutdown operations of thermal power unit 50. Voltage and frequency control of windâdiesel power system through adaptive sliding mode control of superconducting magnetic energy storage
51. Impedance-Based Stability Analysis Methods for DC Distribution Power System With Multivoltage Levels 52. Uncertainty Evaluation Algorithm in Power System Dynamic Analysis with Correlated Renewable Energy Sources 53. Which ship-integrated power system enterprises are more competitive from the perspective of patent? 54. Deep Feedback Learning Based Predictive Control for Power System Undervoltage Load Shedding 55. Conventional and advanced exergy analyses of a vehicular proton exchange membrane fuel cell power system 56. Advanced teaching method for learning power system operation based on load flow simulations 57. A novel application of ALO-based fractional order fuzzy PID controller for AGC of power system with diverse sources of generation 58. A review of the smart grid concept for electrical power system 59. Dynamic powerâfrequency control in a hybrid wind-PV plant interlinked with AC power system 60. Application of SVC and STATCOM for wind integrated power system
61. Mass optimization of the radiation shadow shield for space nuclear power system 62. Power system operation with power electronic inverterâdominated microgrids 63. Comparative study of four MPPT for a wind power system 64. An empirical approach to frequency droop characterization from utilityâscale photovoltaic plants operation in a power system 65. Bioâinspired hybrid BFOAâPSO algorithmâbased reactive power controller in a standalone windâdiesel power system 66. A Small Hybrid Power System of Photovoltaic Cell and Sodium Borohydride Hydrolysis-Based Fuel Cell 67. A hybrid MFOâGHNN tuned selfâadaptive FOPID controller for ALFC of renewable energy integrated hybrid power system 68. Nonlinear Model Predictive Control of an Autonomous Power System Based on Hydrocarbon Reforming and High Temperature Fuel Cell 69. A new congestion cost allocation method in a deregulated power system using weighting of contractual preferences and geographical location of users 70. Optimized Power System Voltage Measurements Considering Power System Harmonic Effects
71. Power System Characteristics 72. Fault Tolerant Control Method of Power System of Tram Based on PLC. 73. Priority Lists for Power System Investments: Locating Phasor Measurement Units 74. The concept of vulnerability and resilience in electric power systems 75. A review of different optimisation techniques for solving single and multi-objective optimisation problem in power system and mostly unit commitment problem 76. Modeling Inverters with Grid Support Functions for Power System Dynamics Studies 77. Performance of wide-area power system stabilizers during major system upsets: investigation and proposal of solutions 78. Review of Proactive Operational Measures for the Distribution Power System Resilience Enhancement Against Hurricane Events. 79. Chaos Elimination in Power System Using Synergetic Control Theory 80. Role of Hydrogen in a Low-Carbon Electric Power System: A Case Study
a. Study of Assessing the Stability of Rwanda’s Power System from Big Data Based on Power Generation 81. A simplified virtual power system lab for distance learning and ABET accredited education systems 82. Review of risk analysis methods for failure scenario in power system under typhoon disasters 83. Preliminary Study on Forced Oscillation of Power System with Quadratic Nonlinearity 84. A novel power system operation simulation method considering multi-state models of coal-fired power unit: a case study of coal-fired power transformation in a certain ⊠85. Comprehensive Analysis and Visualization Method of Online and Offline Operation Modes of Power System 86. Impact of the Power System Stabilizer on Transient Stability of the Power System 87. Research on Data Intelligent Retrieval Method Oriented to Unified Business Center of Power System 88. Technologies and economics of electric energy storages in power systems: Review and perspective 89. How to Use LDA Model to Analyze Patent Information? Taking Ships Integrated Power System as an Example
90. Satin Bowerbird optimization algorithm for the Application of Optimal power flow of power system with FACTS devices 91. Applications of Big Data and Internet of Things in Power System 92. Power system planning methods and experiences in the energy transition framework 93. Study of Interconnections in Vietnam Power System with Asynchronous Back to Back HVDC Links 94. A Convolution Neural Network Method for Power System Oscillation Type Identification 95. DE-Assisted LFC of Three-Area Six-Source Interconnected Power System with Wind Model and Fuel Cell Under Restructured Environment 96. Optimization for Short-Term Operation of Hybrid Hydro-PV Power System Based on NSGA-II 97. Deep learning for short-term voltage stability assessment of power systems 98. Transient Stability-Based Security State Classification of Power System Networks Using Kohonen’s Neural Network 99. Renewable Energy-Based Load Frequency Stabilization of Interconnected Power Systems Using Quasi-Oppositional Dragonfly Algorithm
100. Nonlinear Model Predictive Control of an Autonomous Power System Based on Hydrocarbon Reforming and High Temperature Fuel Cell. Energies 2021, 14, 1371 101. Primary frequency control techniques for large-scale PV-integrated power systems: A review 102. Optimal Operation of a Power System with Cross-border Electricity Trading Considering Demand Response Program: A Case Study of Afghanistan 103. Combined solar power and storage as cost-competitive and grid-compatible supply for China’s future carbon-neutral electricity system 104. Design Optimization Analysis Based On Demand Side Management of a Stand-alone Hybrid Power System Using Genetic Algorithm for Remote Rural Electrification 105. Enhance Power Quality of Grid Connected Wind and Solar Power System with ANFIS Control Scheme 106. Observer-based event triggering Hâ LFC for multi-area power systems under DoS attacks 107. Diagnosis performance assessment of the secondary protection for a 68âbus power system 108. Results of a 200 hours lifetime test of a 7 kW HybridâPower fuel cell system on electric forklifts 109. Optimization of power-to-heat flexibility for residential buildings in response to day-ahead electricity price
110. Impact of renewable generation on probabilistic dynamic security assessment of a power transmission system 111. Prospects of power generation from the deep fractured geothermal reservoir using a novel vertical well system in the Yangbajing geothermal field, China 112. A residential community-level virtual power plant to balance variable renewable power generation in Sweden 113. Evaluation of hierarchical controls to manage power, energy and daily operation of remote off-grid power systems 114. ⊠Multivalent Diagnoses Developed by a Diagnostic Program with an Artificial Neural Network for Devices in the Electric Hybrid Power Supply System âHouse on Waterâ 115. Technical features of the computing and geo-information system for research of prospective interstate power grid expansion 116. Two stage unit commitment considering multiple correlations of wind power forecast errors 117. Blockchain-based securing of data exchange in a power transmission system considering congestion management and social welfare 118. An Optimization Technique for Voltage Regulation in Electrical Power Systems 119. Availability importance measures of components in smart electric power grid systems
120. Electromagnetic Transients on Power Plant Connection Caused by Lightning Event 121. ⊠incorporating battery energy storage system, minimum variable contribution of demand response, and variable load damping coefficient in isolated power ⊠122. Comparatives Studies in Molten Salt Reactor FUJI-U3 with Various Power 123. Future of electrical aircraft energy power systems: An architecture review 124. Fluid power troubleshooting 125. Cascading Failures Assessment in Renewable Integrated Power Grids Under Multiple Faults Contingencies 126. COVID-19-induced low power demand and market forces starkly reduce CO 2 emissions 127. Technology revolution in the inspection of power transmission lines-A literature review 128. Reactive power control of photovoltaic power generation systems by a wideâarea control system for improving transient stability in power systems 129. Techno-economic and environmental assessment of the coordinated operation of regional grid-connected energy hubs considering high penetration of wind power 130. A hybrid grey wolf optimisation and pattern search algorithm for automatic generation control of multi-area interconnected power systems 131. ICA based Multi Converter Strategy for Improving Power Quality in Multi-Feeder System with Renewable Source Integration 132. A Self Monitoring and Analyzing System for Solar Power Station using IoT and Data Mining Algorithms 133. Analysis of Emergency Operation Modes of Micro Power Systems with Small Hydroelectric Power Plants 134. Improving the voltage quality and power transfer capability of transmission system using facts controller 135. Particle swarm optimization in image processing of power flow learning distribution 136. A Modified TeachingâLearning-Based Optimization for Dynamic Economic Load Dispatch Considering Both Wind Power and Load Demand Uncertainties With ⊠137. An ensemble model for wide-area measurement-based transient stability assessment in power systems 138. An adaptative control strategy for interfacing converter of hybrid microgrid based on improved virtual synchronous generator 139. Quantum computing based hybrid deep learning for fault diagnosis in electrical power systems
140. Performance enhancement and multi-objective optimization of a double-flash binary geothermal power plant 141. Optimal reactive power dispatch using an improved slime mould algorithm 142. Applications of Metaheuristics in Power Electronics 143. A Dynamic State Estimator Based Tolerance Control Method Against Cyberattack and Erroneous Measured Data for Power Systems 144. Establishment of Low Voltage Ride-Through Curves and Stability Analysis with High Photovoltaic Penetration in Power Systems 145. A systematic review of the costs and impacts of integrating variable renewables into power grids 146. A wind power accommodation capability assessment method for multi-energy microgrids 147. Analyzing the effects of economic development on the transition to cleaner production of China’s energy system under uncertainty 148. Enhancing fault detection function in wind farmâintegrated power network using Teaching LearningâBased Optimization technique 149. Economic analysis and optimization of a renewable energy based power supply system with different energy storages for a remote island
150. A hybrid SATS algorithm-based optimal power flow for security enhancement using SSSC 151. Prediction-based analysis on power consumption gap under long-term emergency: A case in China under COVID-19 152. Dynamic virtual power plant: A new concept for grid integration of renewable energy sources 153. Energy Storage Investment and Operation in Efficient Electric Power Systems 154. Comprehensive Design of DC Shipboard Power Systems for Pure Electric Propulsion Ship Based on Battery Energy Storage System 155. Physics-informed neural networks for minimising worst-case violations in dc optimal power flow 156. A review on fractional order (FO) controllers’ optimization for load frequency stabilization in power networks 157. Resilience analysis and cascading failure modeling of power systems under extreme temperatures 158. CascadeâIλDÎŒN controller design for AGC of thermal and hydroâthermal power systems integrated with renewable energy sources 159. Hospital-oriented quad-generation (HOQG)âA combined cooling, heating, power and gas (CCHPG) system
160. Energy, exergy, economy and environmental (4E) analysis and optimization of single, dual and triple configurations of the power systems: Rankine Cycle/Kalina Cycle ⊠161. Deriving pack rules for hydroâphotovoltaic hybrid power systems considering diminishing marginal benefit of energy 162. Safe Reinforcement Learning for Emergency Load Shedding of Power Systems 163. Electric power systems 164. Solving optimal power flow problem with stochastic windâsolarâsmall hydro power using barnacles mating optimizer 165. An efficient control strategy of shunt active power filter for asymmetrical load condition using time domain approach 166. Analysis of various options for balancing power systems’ peak load 167. An open-source extendable model and corrective measure assessment of the 2021 texas power outage 168. Optimal supply chains and power sector benefits of green hydrogen 169. Improving the Efficacy of the Nigerian Electric Power Transmission Network Using Static Synchronous Compensator (STACOM)
170. Optimal Placement of PMUs for Kerala and Tamil Nadu State Level Regional Indian Power Grid 171. Sharing hydropower flexibility in interconnected power systems: A case study for the China Southern power grid 172. Full energy sector transition towards 100% renewable energy supply: Integrating power, heat, transport and industry sectors including desalination 173. Multi-objective optimal power flow problems based on slime mould algorithm 174. System simulation and exergetic analysis of solid oxide fuel cell power generation system with cascade configuration 175. The importance of temporal resolution in modeling deep decarbonization of the electric power sector 176. MULTI-OBJECTIVE OPTIMAL REACTIVE POWER DISPATCH CONSIDERING THE INTEGRATION OF PROBABILISTIC WIND AND SOLAR POWER 177. Knowledge implementation and transfer with an adaptive learning network for real-time power management of the plug-in hybrid vehicle 178. Solar power satellites research in China 179. Frequency stabilization of solar thermal-photovoltaic hybrid renewable power generation using energy storage devices
i. Design and Comparison of Auxiliary Resonance controllers for Mitigating Modal Resonance of Power Systems Integrated with Wind Generation ii. A Computational Intelligence Approach for Power Quality Monitoring iii. Cascading Failure A nalysis of Cyber Physical Power Systems Considering Routing Strategy iv. Demand Side Management by PV Integration to Micro-grid Power Distribution System: A Review and Case Study Analysis v. Use of a hybrid windâsolarâdieselâbattery energy system to power buildings in remote areas: a case study vi. Challenges and opportunities of inertia estimation and forecasting in low-inertia power systems vii. Generation Scheduling of Hydro-dominated Provincial Power Grid: Problems and Solutions viii. A review of machine learning applications in IoT-integrated modern power systems ix. Use of hydrogen as a seasonal energy storage system to manage renewable power deployment in Spain by 2030 x. Assessment of utilization of combined heat and power systems to provide grid flexibility alongside variable renewable energy systems
180. The role of the power sector in net-zero energy systems 181. A new approach to determine maintenance periods of the most critical hydroelectric power plant equipment 182. Application of HighâPerformance Computing in Synchrophasor Data Management and Analysis for Power Grids 183. Wide-area monitoring and anomaly analysis based on synchrophasor measurement 184. Marine predators algorithm for load frequency control of modern interconnected power systems including renewable energy sources and energy storage units 185. Comparative study on the thermodynamic and economic performance of novel absorption power cycles driven by the waste heat from a supercritical CO2 cycle 186. Adaptive constraint differential evolution for optimal power flow 187. Optimization of location and size of distributed generations for maximizing their capacity and minimizing power loss of distribution system based on cuckoo search ⊠188. Solar power-to-gas application to an island energy system 189. Fault Detection in Power Transmission System Using Reverse Biorthogonal Wavelet
190. Line failure localization of power networks part i: Non-cut outages 191. Sunsetting coal power in China 192. Decentralised stochastic disturbance observer-based optimal frequency control method for interconnected power systems with high renewable shares 193. Hydrogen-based systems for integration of renewable energy in power systems: Achievements and perspectives 194. Research on frequency modulation control of photovoltaic power generation system based on VSG 195. Research on Grid Expansion Planning and Reliability Balance under the Fusion of Energy Storage and Wind Power 196. Asynchronous Control for Discrete-Time Hidden Markov Jump Power Systems 197. Nonlinear disturbance observer based adaptive super twisting sliding mode load frequency control for nonlinear interconnected power network 198. A Review of Lithium-Ion Battery Models in Techno-economic Analyses of Power Systems 199. Probabilistic estimation model of power curve to enhance power output forecasting of wind generating resources
- Power Systems Topics of presentation
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MS in Electrical Engineering - Electric Power
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The electric power industry is presently experiencing what has been described as the most revolutionary (and exciting) set of technological changes since the days of Edison. Apart from environmental pressures that demand a revised portfolio of energy resources, utilities are anticipating the development of a so-called âsmart gridâ that promises new opportunities for efficient and reliable use of electric power. The skills that electric power engineers will require are changing accordingly.
The MS in Electrical Engineering (Electric Power) is a program option for students seeking careers in the electric power industry. The plan of study combines traditional topics in power generation, transmission, and distribution with cutting-edge topics such as the integration of renewable energy sources in the âsmart grid.â
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Visit our Ready to Apply page for more information
ELIGIBILITY CRITERIA
Applicants to the master's of science programs in Electrical Engineering - Electric Power are required to have a bachelorâs degree or be in the process of completing a bachelor's degree. Degrees in any engineering or engineering-related disciplines are frequently represented among our program applicants, including but not limited to the following:
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Applicants without a Bachelorâs degree in the preferred majors listed above will only be considered with coursework and demonstrated proficiency in the acceptable courses listed below ( or equivalent ).Â
Applications are reviewed holistically; simply taking these courses does not guarantee admission.
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The following materials are required to be included with your online application:
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Download the  Cost of Attendance to see a summary of tuition and fees by semester. The document is a typical example and the number of courses, and time to complete the program, will vary by student.
What were the main reasons you chose to pursue this graduate program at USC? I chose the program for its strength in its electrical engineering program while being in the heart of Los Angeles.
What are some personal achievements or experiences youâd like to share? I was a former Apple engineer after my undergraduate before coming to pursue my graduate education at USC!
What do you like most about living in Los Angeles? Los Angeles has been one of the most diverse cities Iâve ever lived in. The combination of food, people, and atmosphere has really made it a treat to live in the area
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* Information is based on a voluntary survey and should not be interpreted as a comprehensive view of the 2022 graduating class.
This program is also available online to professional engineers through DEN@Viterbi. Because the DEN@Viterbi program provides a fully equivalent academic experience, the degree a USC engineering student earns is the same whether they are on-campus or online.
If you are interested in beginning classes as a DEN@Viterbi student next semester, explore the requirements and steps to enrolling as a Limited Status Student.
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Our research areas reflect the diversity of the electrical engineering profession and range from the very small, such as nanoscale electronic devices and their modeling, to the very large, such as the U.S. electric power grid and its control. Our faculty includes experts in many application areas, such as the design of flight control for aircraft and the implementation of neural interfaces for biomedical applications.
Graduate students are involved in all of our research activities and have access to state-of-the-art facilities, such as the electromagnetic anechoic chamber, the wireless communications lab and the integrated circuit fabrication cleanroom. Some programs offer students theoretical approaches for the design of communication systems, while others include the implementation of wireless communication devices, such as the circuits in cell phones.
These research efforts align with national and international efforts to address worldwide challenges in energy production and distribution, communications technology and information management, health care technology and delivery, sustainable development and economic growth and global security.
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Control systems.
The School of Electrical, Computer and Energy Engineering’s systems and controls program includes nine graduate courses in the areas of linear and nonlinear control systems, real-time and digital control systems, optimal control, distributed parameter systems, adaptive control and neural networks. In addition, the theoretical material taught in the upper-division undergraduate and graduate courses is enhanced through the use of computer and experimental projects.
Electric power and energy systems
The School of Electrical, Computer and Energy Engineering’s electric power and energy systems curriculum includes six upper-division undergraduate courses and 14 graduate courses in the area of power system analysis, power generation, transmission and distribution, power system dynamics and stability, energy conversion, electric machines, power electronics, high voltage engineering and nuclear power engineering.
Arizona State University is the lead higher education institution in the Power Systems Engineering Research Center (PSERC), an industrially and federally supported program of industry and university cooperation. Students are exposed to industrial projects, professional society meetings, laboratory experience and research partially supported by PSERC.
Electromagnetics, antennas and microwaves
The School of Electrical, Computer and Energy Engineering’s electromagnetics, antennas and microwave circuits curriculum includes senior-level undergraduate and graduate-level courses in the areas of electromagnetics, antennas, microwave and terahertz circuits and devices, fiber optics and lasers. Computers and associated software are incorporated in many of the upper-division undergraduate and graduate courses to enhance the theoretical material taught in the courses.
Faculty members in the electromagnetics group are involved in researching many areas of applied electromagnetics, including metamaterials; smart antennas; beamforming and scanning techniques; flexible antennas; miniature, wideband and reconfigurable antennas; tunable and reconfigurable microwave circuits; RF microelectromechanical systems; biomedical applications; metamaterials; and fast computational electromagnetic methods.
Electronic and mixed-signal circuit design
The School of Electrical, Computer and Energy Engineering’s electronic and mixed-signal circuit design curriculum includes five upper-division undergraduate courses and more than 10 graduate-level courses in the area.
With the support of the semiconductor industry and government agencies, these centers have established a state-of-the-art educational program in very large-scale integration (VLSI) design, modeling, mixed-signal and radio-frequency (RF) integrated circuits design.
Physical electronics and photonics
The School of Electrical, Computer and Energy Engineering’s physical electronics and photonics curriculum includes five upper-division undergraduate courses and 14 graduate courses in the areas of semiconductor devices and materials, characterization, photonic and photovoltaic devices, semiconductor processing and intelligent control, nanoelectronics, molecular electronics, transport and computational electronics, as well as occasional specialty courses.
The faculty in the physical electronics and photonics program are actively pursuing research in many areas of semiconductor materials and devices. They engage students in the MSE, MS and PhD programs. Research is typically supported by the National Science Foundation , the U.S. Department of Defense , the U.S. Department of Energy and private industry.
Signal processing and communications
The School of Electrical, Computer and Energy Engineering offers instruction in the related areas of signal processing and communications systems at the graduate level. Courses are also offered for beginning graduate students in the field to bridge any gaps that might exist between undergraduate course work and the 500-level offerings at ASU.
Students may choose from among several 500-level courses, ranging from offerings primarily intended for first-year students to special topic courses designed to acquaint advanced graduate students with research topics of current interest.
Research topics
Ai and machine learning.
Ahmed Alkhateeb
Krishnendu Chakrabarty
Angelia Nedich
Lalitha Sankar
Konstantinos Tsakalis
Jeff (Jun) Zhang
Visar Berisha
Vidya Chhabria
Oliver Kosut
Anamitra Pal
Pavan Turaga
Yanchao Zhang
Daniel Bliss
Gautam Dasarathy
Ying-Cheng Lai
Amarsagar Reddy Ramapuram Matavalam
Andreas Spanias
Vijay Vittal
Chaitali Chakrabarti
Suren Jayasuriya
Nicolo Michelusi
Martin Reisslein
Cihan Tepedelenlioglu
Electric vehicles
Raja Ayyanar
Mike Ranjram
Yong-Hang Zhang
Electromagnetics and microwaves
James Aberle
Georgios Trichopoulos
Rodolfo Diaz
Seyedmohammadreza Imani
Electronic communications
Constantine Balanis
Sayfe Kiaei
Lawrence Clark
Joseph Palais
Saeed Zeinolabedinzadeh
Electronic design automation
Arindam Sanyal
Information theory
Duong Nguyen
Integrated circuits
Jennifer Blain Christen
David Allee
David Ferry
Stephen Phillips
Bertan Bakkaloglu
Hugh Barnaby
Jennifer Kitchen
Media and engineering
Robert LiKamWa
Nanoelectronics
Umberto Celano
Zachary Holman
Houqiang Fu
Matthew Marinella
Stephen Goodnick
Ivan Sanchez Esqueda
Josh Hihath
Power grid engineering and power electronics
Kory Hedman
Gerald Heydt
Michael Kozicki
Mojdeh Khorsand Hedman
Quantum engineering
Christian Arenz
Michael Goryll
Radiation effects
Renewable energy, photovoltaics, photonics and optoelectronics
Mariana Bertoni
Nick Rolston
Christiana Honsberg
Dragica Vasileska
Richard King
Semiconductors
Chris Bailey
Marco Saraniti
Brian Skromme
Nidhin Kurian Kalarickal
Trevor Thornton
Zhaoyang Fan
Signal processing
Antonia Papandreou-Suppappola
Master's in Power Systems Engineering Online (MEng)
Engineer the Future of Energy. Power Up Your Career.
Bringing together a variety of analytical and practical subjects, both classical and current, WPIâs MS in Power Systems Engineering Online prepares electrical engineers for professional practice in the electric utility industry. Through course topics in analysis, rotating machinery, transmission and distribution systems, protection and controls, and more, you will be prepared to:
Value Proposition Description
- Analyze power flows in delivery networksâboth for steady state and transients
- Understand electro-mechanical energy conversion and power system operations and planning
- Design power delivery networksâboth transmission and distribution
- Analyze dynamic system response to disturbances
- Design protection and control systems
- Evaluate design alternatives, including both technical and economic analysis
- Lead projects using a full suite of management tools
- Understand group and individual dynamics leading to more effective interactions
- Identify and mitigate operational risks
Admissions Qualifications for the Power Systems Engineering Masterâs Degree
Excellent candidates have an ABET accredited undergraduate degree in Electrical Engineering with a GPA of 3.0 or higher. Engineers from other disciplines may be successful in Power Systems with coursework in AC Circuits and Signals as well as significant mathematics including Linear Algebra and Differential Equations.
If you do not have a bachelor's degree, please view our list of undergraduate programs .
For specific application requirements, visit our admissions for online programs page. Have additional questions? Please contact our WPI Online team to review individual situations.
The online power systems engineering degree requires the completion of 30 graduate credit hours. The distribution of credits is as follows:
- Must include ECE 5500 . Power System Analysis
- Up to 9 credit hours from engineering, mathematics, science or business .
All Power Systems Engineering graduate courses are 3 credits.
- ECE 523. Power Electronics
- ECE 5500. Power System Analysis*
- ECE 5511. Transients in Power Systems
- ECE 5512. Electromechanical Energy Conversion
- ECE 5520. Protection and Control (not to be taken with ECE 5521)
- ECE 5521. Protective Relaying (not be taken with ECE 5520)
- ECE 5522. Advanced Applications in Protective Relaying
- ECE 5523. Power System Dynamics
- ECE 5530. Power Distribution
- ECE 5531. Power System Operations and Planning
- ECE 5532. Distributed and Renewable Power Generation
- ECE 5540. Power Transmission
To find the next offering of online Power Systems Engineering courses, visit the Registrarâs site .
To view a course description, visit the Graduate Catalog.
Subject to change based on availability.
Learn from Power Industry Experts
WPI students work closely with WPIâs renowned Power Systems faculty: real-world, industry experts who enrich the curriculum with decades of experience. That's part of what makes WPI among the best universities for MS in power systems!
Read the faculty biographies
See all the events and webinars that the Graduate Studies team are hosting and attending.
View the Calendar
Got 7 minutes? Take this short survey and help improve the grad-school-research experience for you and your peers.
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- John Sonnelitter
- Protection & Controls Engineer
Other Online Graduate Programs in Power Systems:
Interested in gaining a foundation in key disciplines related to power systems engineering like protection and controls and power transmission? WPI's power systems engineering certificate online is perfect for those interested in elevating their career in the power industry. Maybe you're looking to gain a business edge? The online master's in Power Systems Management may be just the degree for you. Students work with industry experts and learn about the business side of the power industry.
- Online graduate certificates in Power Systems
- Online master's in Power Systems Management
Refer a Friend
Do you have a friend, colleague, or family member who might be interested in Worcester Polytechnic Instituteâs (WPI) graduate programs? Click below to tell them about our programs.
Graduate Studies Series
Team members from Graduate & Professional Studies host quick and convenient webinars designed to highlight popular topics when starting grad school. Take a deep dive into specific areas of interest such as how to secure funding, how to ace your application, an overview of student services, and more!
Power Systems Info Session
View our on-demand webinar to be introduced to WPI's online graduate programs in Power Systems. Get an overview of program logistics, what online learning looks like, the application process, and more!
Ask Us Anything â Power Systems Podcast
Listen and learn! Enjoy this recording from our June 2020 Q&A webinar. Questions were answered by online power students Ahvinash Bansi and Benjamin Franco, along with an online programs manager, a student success manager, and Mike Ahern, Dir. of Power Systems Engineering.
Energy Education Program
WPI and the Energy Providers Coalition for Education (EPCE) are partners in providing quality online education to the energy industry. If you work for an organization that is a member of EPCE, you receive a 10% discount on your online WPI tuition. Contact EPCE to determine if you qualify.
- School of Engineering and Applied Sciences
- UB Directory
- Department of Electrical Engineering >
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Areas of Research
Our faculty, students and researchers are actively engaged in research in the areas of Networking and Communications; Electronics and Photonics; and Power and Energy Systems.
Networking & Communications
Networking & Communications faculty carry out research on fundamental aspects of signal acquisition, data representation, transmission, and processing, single and multi-user wireless point-to-point and networked communications.
Electronics & Photonics
Faculty in the area of Electronics & Photonics undertake research into cutting-edge electronic and optoelectronic devices and circuits, with broad application to state-of-the-art technologies. These include high-performance, high-speed, computer and communication networks, photovoltaics, electric vehicles, and "smart" medical devices.
Power & Energy Systems
The Power & Energy Systems Area focuses on various aspects of the generation, storage, transmission, and distribution of electric power. The program integrates energy systems research with research in energy control, efficiency improvement, demand side management, power quality and economics, renewable resources and integration, and smart grid communications.
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Electrical and electronic engineering articles from across Nature Portfolio
Electrical and electronic engineering is the branch of engineering that makes use of electricity. Electrical engineering concentrates on systems for generating and transmitting large electrical currents and converting them into other forms of energy, such as mechanical motion. Electronic engineering focusses on lower energy currents for processing and communicating information.
Wireless radiofrequency network of distributed microsensors
Distributed sensing of a dynamic environment is typically characterized by the sparsity of events, such as neuronal firing in the brain. Using the brain as inspiration, an event-driven communication strategy is developed that enables the efficient transmission, accurate retrieval and interpretation of sparse events across a network of thousands of wireless microsensors.
Latest Research and Reviews
Thermogalvanic hydrogel-based e-skin for self-powered on-body dual-modal temperature and strain sensing
- Zhaosu Wang
- Xiaojing Cui
Frequency-encoded eye tracking smart contact lens for humanâmachine interaction
Eye tracking techniques enable high-efficient, natural, and effortless human-machine interaction. Here, Zhu et al. proposed a contact lens to track eye movement for wireless eye-machine interaction
- Hengtian Zhu
Frequency tunable magnetostatic wave filters with zero static power magnetic biasing circuitry
Magnetostatic wave filters have a wide working frequency range, small size and high Q-factor, however, they are hampered by the need for a large external electromagnet to provide a bias magnetic field. Here, Du et al demonstrate an extremely small and low power external magnetic bias assembly with zero static power consumption, removing the need for bulky and energy intensive electromagnets.
- Mohamad Hossein Idjadi
- Roy H. Olsson III
Broadband unidirectional twin-element MIMO antenna scheme for mid-band 5G and WLAN laptops
- Bancha Luadang
- Pisit Janpangngern
- Chuwong Phongcharoenpanich
Improved phase-to-height mapping method combine with device attitude
- Shuhuan Han
- Xinyu Zhang
Recyclable vitrimer-based printed circuit boards for sustainable electronics
Recycling of printed circuit boards (PCBs) is currently restricted by the intrinsic materials design of conventional PCBs. This work presents a vitrimer-based PCB that shows great end-of-life recyclability.
- Zhihan Zhang
- Agni K. Biswal
- Vikram Iyer
News and Comment
Advanced transport systems: the future is sustainable and technology-enabled.
Transport has always played a major role in shaping society. By enabling or restricting the movement of people and goods, the presence or absence of transport services and infrastructure has historically been determining for cultures to connect, for knowledge to be shared, and for societies to evolve and prosper, or, in contrast, for societies to decay and fail. Since the beginning of the twenty-first century, transport has been going through a revolution worldwide. One of the primary goals for the transport sector is clear: it needs to be decarbonized and become more sustainable. At the same time, technological advances are shaping the transport sector toward smart services and societies. The Special Collection showcases some of the latest advances in research towards sustainable and technology-enabled transport.
- Sybil Derrible
Scaling up stretchable electronics
- Katharina Zeissler
Searching for MXenes
- Matthew Parker
Hybrid perovskites unlocking the development of light-emitting solar cells
Light-emitting perovskite solar cells are emerging optoelectronic devices that integrate light-emitting and electricity-generating functions in one device. This type of device unlocks new possibilities for applications as outdoor light sources, in multifunctional architecture, smart automobiles, self-powered displays and portable power floodlights.
- Alexey Tarasov
Tailoring materials, structures and fabrication processes for stretchable electronics
An article in Nature presents large-area, high-performance intrinsically stretchable electronics thanks to innovation in materials selection, fabrication processes, device engineering and circuit design.
- Silvia Conti
Van der Waals magnet integration for energy-efficient spintronics
An article in Science Advances reports an integrated van der Waals system that enables field-free electric control of the magnetization of Fe 3 GaTe 2 above room temperature.
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Electrical Power Engineering MSc
Awards: MSc
Study modes: Full-time
Accreditation
Funding opportunities
Upcoming Introduction to Postgraduate Study and Research events
Join us online on the 19th June or 26th June to learn more about studying and researching at Edinburgh.
Choose your event and register
Programme description
Our Electrical Power Engineering MSc is a one-year programme designed to equip you with broad and robust training on modern power engineering technologies, with a strong focus on renewable energy conversion and smart grids.
In semesters 1 and 2, you will acquire the advanced fundamentals, research tools and techniques of power engineering, as well as an in-depth knowledge of emerging technologies and advanced numerical methods to address some of the world's grand challenges, such as integration of wind energy, offshore renewables, energy storage and photovoltaics.
You will also complete an individual dissertation project over the summer months, which provides a good opportunity for you to apply your acquired skills to a real-world problem.
How will I learn?
You will be taught by our experts who are leaders in their field and you will deepen your knowledge through:
- our connections with leading power engineering companies in the sector
- practical labs where you will benefit from our specialist power electronics and machines facilities
- participating in site visits so you can experience the application of theory to real situations
- gaining experience of using industry-approved software
- being exposed to industrial guest speakers on leading technology and power engineering challenges
- actively engaging in our world-leading research on power engineering as part of your dissertation project
Research project
In close collaboration with our academics, you will undertake a research project to put into practice the knowledge and skills you have acquired during the first two taught semesters, during which you will investigate an actual power engineering problem.
You can carry out your project within either:
- one of our power research groups working alongside academics and researchers from the Institute for Energy Systems
- in an industrial placement at one of our collaborating companies within the power sector
The MSc in Electrical Power Engineering is accredited by the UK Institution of Engineering and Technology (IET), one the largest professional engineering bodies in the world. Accredited programmes undergo continuous and robust quality review by the IET and are internationally recognised for the quality of the education they provide.
Your MSc can therefore count towards the academic requirements for registration as a Chartered Engineer (CEng) in the UK. Chartered Engineers not only have a firm grasp of the underpinning knowledge of their field, but also possess the required professional skills to excel in the modern engineering environment.
Programme structure
You will learn through a combination of:
- taught courses
- practical laboratories
- group design projects
- a research dissertation
The courses correspond to 120 credits of taught material, plus 60 credits of a research project.
You will take the following compulsory courses in Semester 1:
- Distributed Energy Resources and Smart Grids
- Engineering Research Methods with Grand Challenge
- Power Conversion
- Power Systems
You will take the following compulsory courses in Semester 2:
- Power Systems Engineering and Economics
- Principles of Wind Energy
- Solar Energy & Photovoltaic Systems
- Advanced Power Electronics and Machines
Research Project
- Electrical Power Engineering Dissertation
Courses can change from year to year. Those listed provide a representation of courses previously offered. Courses for the forthcoming year will be published on the Degree Programme Table in the Spring.
Find out more about compulsory and optional courses
We link to the latest information available. Please note that this may be for a previous academic year and should be considered indicative.
Learning outcomes
Our aim is to train the next generation of power engineers who are equipped to contribute to the rapidly changing needs of the industry and society. We will support you to:
- build your knowledge of the most recent, cutting-edge developments in power engineering
- acquire advanced research and development skills and training, allowing you to excel in both industrial and academic settings
- understand and tackle the global energy trilemma of supplying secure, equitable and environmentally sustainable energy, while appreciating the technical, social and economic challenges faced in both developed and developing countries.
Career opportunities
Power engineering is one of the most in-demand professions in the UK and worldwide with Governments putting plans in place to decarbonise and modernise the electricity sector.
The transition to a green economy will require a highly skilled workforce led by electrical power engineers with a solid academic background, an appreciation of the trajectory of the industry and an understanding of the challenges and implications brought about by the introduction of new power technologies.
As a graduate from our MSc Electrical Power Engineering programme, you will be equipped to go into a wide range of careers anywhere in the world, such as in:
- energy consultancies
- energy utilities or manufacturers
- engineering or construction companies
- renewable energy developers
- governments
The programme runs in a close association with other activities within the broader Electrical Engineering programme within the School, and existing research associations and consortia (such as the EPSRC Centre for Energy Systems Integration), meaning you will benefit from:
- networking events
- industrial presentations
Careers service
Entry requirements
These entry requirements are for the 2024/25 academic year and requirements for future academic years may differ. Entry requirements for the 2025/26 academic year will be published on 1 Oct 2024.
A UK 2:1 degree, or international equivalent, in Electrical and/or Electronic Engineering.
Applicants with different academic backgrounds may be considered but we expect you to have passed at least two power engineering related courses with marks equivalent to UK 2:1 as a minimum. Examples of relevant courses are power electronics, power systems, electric machines, control engineering, renewable energy etc. This requirement may be partially met by relevant industrial experience; applicants with non-standard backgrounds may be considered on a case-by-case basis.
Applicants will also need to submit a personal statement, which should clearly demonstrate both their level of understanding of power engineering, and their strong interest in and commitment to the field.
Please note that entry to this programme is very competitive. A typical offer will normally require a UK first class honours degree or equivalent.
Students from China
This degree is Band B.
- Postgraduate entry requirements for students from China
International qualifications
Check whether your international qualifications meet our general entry requirements:
- Entry requirements by country
- English language requirements
Regardless of your nationality or country of residence, you must demonstrate a level of English language competency at a level that will enable you to succeed in your studies.
English language tests
We accept the following English language qualifications at the grades specified:
- IELTS Academic: total 6.5 with at least 6.0 in each component. We do not accept IELTS One Skill Retake to meet our English language requirements.
- TOEFL-iBT (including Home Edition): total 92 with at least 20 in each component. We do not accept TOEFL MyBest Score to meet our English language requirements.
- C1 Advanced ( CAE ) / C2 Proficiency ( CPE ): total 176 with at least 169 in each component.
- Trinity ISE : ISE II with distinctions in all four components.
- PTE Academic: total 62 with at least 59 in each component.
Your English language qualification must be no more than three and a half years old from the start date of the programme you are applying to study, unless you are using IELTS , TOEFL, Trinity ISE or PTE , in which case it must be no more than two years old.
Degrees taught and assessed in English
We also accept an undergraduate or postgraduate degree that has been taught and assessed in English in a majority English speaking country, as defined by UK Visas and Immigration:
- UKVI list of majority English speaking countries
We also accept a degree that has been taught and assessed in English from a university on our list of approved universities in non-majority English speaking countries (non-MESC).
- Approved universities in non-MESC
If you are not a national of a majority English speaking country, then your degree must be no more than five years old* at the beginning of your programme of study. (*Revised 05 March 2024 to extend degree validity to five years.)
Find out more about our language requirements:
Fees and costs
If you receive an offer of admission you will need to pay a deposit to secure your place.
- ÂŁ1,500 (this contributes towards your tuition fees)
Any applicants who are required to pay will receive an offer with full details. (If there is no information on your offer about the deposit, then you are not required to pay.)
Find out more about tuition fee deposits:
- Tuition fee deposits
Living costs
You will be responsible for covering living costs for the duration of your studies.
Tuition fees
Scholarships and funding, uk government postgraduate loans.
If you live in the UK, you may be able to apply for a postgraduate loan from one of the UKâs governments.
The type and amount of financial support you are eligible for will depend on:
- your programme
- the duration of your studies
- your tuition fee status
Programmes studied on a part-time intermittent basis are not eligible.
- UK government and other external funding
Engineering International Masters Scholarships
The scholarships will be awarded to overseas applicants who have been accepted for admission on a full-time basis for an eligible postgraduate taught Masters programme within the School of Engineering.
The scholarship will be awarded broadly on the basis of academic merit with candidates requiring a first-class honours degree from a UK university or overseas equivalent.
Learn more about this scholarship:
- Engineering International Masters Scholarship
- Scottish Power Scholarship
- Full tuition fees plus a monthly maintenance allowance
ScottishPower has been building relationships with universities in our communities for a number of years. Working together, we aim to support development of future talent while mitigating the projected skills gap within the energy sector.
The programme is designed to financially support high achieving recent graduates in Spain, the United Kingdom and Mexico, who are interested in pursuing an advanced degree in industry relevant fields such as engineering, smart grids, renewable energy, sustainability, energy and environment, information technology, big data, cybersecurity, and more.
Other funding opportunities
Search for scholarships and funding opportunities:
- Search for funding
Further information
- Admissions Officer (lines open Mon-Fri 10am-4pm)
- Phone: +44 (0)131 650 5737
- Contact: [email protected]
- Programme Director, Dr Michael Merlin
- Phone: +44 (0)131 650 5726
- Contact: [email protected]
- School of Engineering
- Sanderson Building
- The King's Buildings Campus
- School: Engineering
- College: Science & Engineering
Select your programme and preferred start date to begin your application.
MSc Electrical Power Engineering - 1 Year (Full-time)
Application deadlines.
Due to high demand, the school operates a number of selection deadlines.
We strongly recommend you apply as early as possible. Applications may close earlier than the published deadlines if there is exceptionally high demand.
We will make a small number of offers to the most outstanding candidates on an ongoing basis, but hold the majority of applications until the next published selection deadline.
We aim to make the majority of decisions within eight weeks of the selection deadline.
If we have not made you an offer by a specific selection deadline this means one of two things:
- your application has been unsuccessful, in which case we will contact you to let you know, or
- your application is still being considered, will be carried forward for consideration in the next selection deadline and weâll be in touch once a decision is made
Selection Deadlines
- How to apply
You must submit one reference with your application.
Find out more about the general application process for postgraduate programmes:
Department of electric energy
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SprÄkvelger
Research - department of electric power engineering.
At the Department of Electric Energy (IEL), the mission is to contribute to the fundamental and applied knowledge of electric power engineering, and to develop technology and systems for the planning, operation and maintenance of efficient, sustainable energy systems. Both research and research-based education at the Department of Electric Energy cover the broad interdisciplinary aspects of power engineering: generation, transmission, conversion and the use of electric energy, including the accompanying techno-economic aspects.
The Department works in close collaboration with industry partners to develop technology for the production of electric energy from renewable energy sources, and contribute to research that leads to solutions for the future power grid, with high relevance for the society, addressing industrial needs and global challenges.
We have five research groups that are responsible for research and education within their areas; the groups also collaborate among each other in research projects.
Research Groups
Electrical machines and electromagnetics (eme).
The main research areas of the group are related to the development, design, optimisation and testing of electric machinery, especially permanent magnet machines and hydropower generators. In addition, research is also focused on advanced electromagnetic modelling and analyses of different power apparatus and installations.
Electricity Markets and Energy System Planning (EMESP)
The main research areas of the group are related to the integration of renewable energy sources, energy storage and consumption in the electricity market, and how to optimize the integration of the power system with other parts of the energy system, e.g. heating and transport.
High Voltage Technology (HVT)
The main research activities of the group are related to the design, modeling and operation of electric power components. Research into better insulation materials, both for ac and dc, is being conducted.
Power Electronic Systems and Components (PESC)
The research activities of the group are related to the development, design, optimization and control of power electronic converters and systems. Application areas include onshore and offshore power systems, marine, oil & gas as well as transportation sectors.
Power System Operation and Analysis (PSOA)
The main research areas of the group are related to the planning, operation, control and analysis of power systems, with applications in smart grids, transmission and distribution grids, microgrids and HVDC systems.
PhD studies
Phd studies.
The PhD programme in Electric Power Engineering is standardised to 180 credits (3 years). The final plan for the PhD programme is designed in consultation with the candidate, the supervisor and the Department depending on the subject area of the thesis and the candidate's needs and preferences.
- PhD programme in Electric Power Engineering
- Info on PhD studies at NTNU
Vacant positions at the Department
person-portlet
Anngjerd pleym head of department, frank mauseth, kjetil obstfelder uhlen, publications.
Cristin (Current Research Information system) is a nationwide database system for research results and documentation.
- All Publications by the Department of Electric E nergy
- All PhD theses from the Department of Electric E nergy
- All Masters theses from the Department of Electric Energy
Summary of PhD projects
Summary of master projects
Physical Laboratory
The Department has access to a broad spectrum of advanced laboratories and scientific equipment.
- Electrical Machines | PĂ„l Keim Olsen
- Electric Circuits
- High Voltage | Frank Mauseth
- High Current | Kaveh Niayesh
- Light and Lighting | Eilif Hugo Hansen
- Power Electronics | Dimosthenis Peftitsis , Anyuan Chen
- Renewable Energy
- Relay Protection Laboratory | Hans Kr. HĂžidalen
- Service Laboratory | BÄrd AlmÄs
- Smartgrid | Basanta Raj Pokhrel
- Smarthus | Eilif Hugo Hansen
- Workshop | Morten FlÄ
Digital Laboratory
The Department has many digital resources
- Digital Lab
- Computing Resources available at IEL
- Scientific Software
Strategic Research Areas
- IE Faculty Strategic Research Area: SMARTGRIDS
- NTNU Strategic Research Area: ENERGY
Gemini Centre
About Gemini Centres
- Gemini Centre for Electrical Energy and Energy Systems
EE Research at Stanford: The Big Picture
AI, machine learning, optimization
Optimal design and engineering systems operation methodology is applied to things like integrated circuits, vehicles and autopilots, energy systems (storage, generation, distribution, and smart devices), ...
Computational Sensing, Imaging, and Display
This area combines advanced computational and algorithmic solutions with next-generation hardware and systems to unlock new paradigms in sensing, imaging, and displays.
Biology and Health
Discovering and creating fundamentally new devices and systems for critical diagnostics (sensors, imaging), therapeutic (lasers, pacemakers, and neural interfaces), and analytical (high-throughput sequencing, healthcare IT) technologies. ...
Information, Learning, Communication and Coding
Moving information efficiently and reliably across time and/or space supports the modern world and its sustainable future. This area advances fundamental understanding of the communicated information's structure, partitioning âŠ
Computer architecture, including energy efficiency, reliability, security
Exponential growth in performance and storage capacity has been the key enabler for information technology for decades. Yet, current shifts have motivated new system architectures and vertical co-design of hardware, system software, and applications. âŠ
Energy, environment, and sustainability
Motivated at the macro level by the rapid rise in demand for electricity and related threats to the environment, and on the micro level by the number of mobile devices and sensors whose performance and lifetimes are âŠ
Environmental sensors, embedded systems, remote sensing
Drawing on broad disciplines and approaches that advance the state-of-the-art in geoscience remote sensing instrumentation, plus technologies that advance knowledge for the betterment of society and âŠ
Integrated Circuits and Systems
This area is concerned with the application-driven design of electronic circuits and systems, spanning a wide spectrum from low frequencies to mm-wave and THz. These systems are designed with a variety of fabrics and technologies, ranging from silicon subsystems and modules, CMOS and BiCMOS chips, emerging nano and MEMS devices, as well as discrete electronics.
Nanotechnology, nanofabrication, materials, advanced packaging and manufacturing technologies
Design methodology, validation and test, approximate computing, and robust circuits and systems; Mixed-signal integrated circuit design ...
Physics, materials, devices, and systems are investigated using light and electromagnetism. Applications including sensing, imaging, communications, computing, energy, biology, medicine, security, and information processing. ...
Quantum science and engineering
Quantum mechanical entanglement is the main resource for implementation of all quantum technologies (quantum computers, simulators, sensors, and networks). Our goal is to study and scale entanglement in a variety of physical systems âŠ
Develop broadly intelligent behavior through learning and interaction. Exploring the intersection of machine learning and robotic control, including visual perception and manipulation skills, deep reinforcement learning of general skills âŠ
Signal processing and control
Securing useful information while reducing unwanted noise can be achieved using mathematical methods and computation. Optimal design and engineering systemsâ operation methodologies enable the understanding, design, and control of systems âŠ
Software systems, security, distributed systems and networks
Efficient storage, compression, and transmission of information, applies to a wide range of domains, such as communications, genomics, neuroscience, societal networks and urban systems, and statistics. âŠ
Curious about designing a program?
If you are interested in designing a program that fits your interests, please contact the undergrad advisor or graduate advisor.
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Visit Faculty research and lab sites. Deeper dive links are available by clicking on our faculty's name.
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Electrical engineers design the most sophisticated systems ever built. From computers with billions of transistors to microgrids fed by renewable energy sources, from algorithms that predict disease to solar cells and electric vehicles, electrical engineering touches all parts of modern society. We leverage computational, theoretical, and experimental tools to develop groundbreaking sensors and energy transducers, new physical substrates for computation, and the systems that address the shared challenges facing humanity.
Our research is interdisciplinary by nature, and has far-reaching effects on almost every field of human activity, including energy and climate, human health, communications and computation, finance and music. We make the future.
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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, âŠ), statistical learning (inference, graphical models, causal analysis, âŠ), 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 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.
We bring some of the most powerful tools in computation to bear on design problems, including modeling, simulation, processing and fabrication.
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.
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 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.
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.
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.
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Doctoral thesis: machine learning for sepsis prognosis: prediction models and dissecting electronic health records, doctoral thesis: machine learning approaches for healthcare discovery, delivery, and equity, doctoral thesis: heterogeneous integration of spin-photon interfaces with a scalable cmos platform , doctoral thesis: efficient deep learning with sparsity: algorithms, systems, and applications, doctoral thesis: lightwave electronics based on nanoantenna networks, doctoral thesis: toward ultra-resolution biomolecular mapping in cells with expansion microscopy.
- 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 .
âThis article is dedicated to the enthusiasts who are dynamically surfing for the research topics in electrical engineeringâ
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 letâs begin this article with our expertsâ skills in EEE.
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 studentsâ 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 articleâs theme. Guys donât 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 letâs 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
- Â 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 letâs try to understand them.
What are the Current Elements in EEE? Â
- 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 expertsâ 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.Â
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? Letâs 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!!!
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. Letâs make execute your ideas in the form of researches.
Stay educated! Stay experimented! Stay exposed!!!
Research in ECE
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Applied Electromagnetics & RF Circuits
Applied electromagnetics plays an essential role in areas such as wireless technologies, the environment, life sciences, transportation, and more.
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Computer Vision
Our faculty are exploring a number of critical problems in the area of computer vision, with a focus on the analysis and modeling of visual scenes from static images as well as video sequences.
Control Systems
Applications for control include such areas as cyber-physical systems, biological systems, networks, production lines, and biped locomotion.
Embedded Systems
The market is booming for embedded systems such as computers in vehicles, wireless sensors, medical devices, wearable fitness devices, and smartphones.
ECE Education Research
Scholars focus on and apply research methods from education, learning sciences, and social-behavioral sciences to advance the success of engineering.
Integrated Circuits & VLSI
Specialties include analog circuits, data converters, digital circuits, energy harvesting, hardware DSP implementation, low power circuits, RF circuits, and sensing systems.
MEMS & Microsystems
This research area encompasses projects on a variety of micromachined sensors and actuators and on integrated microsystems that combine these components.
Network, Communication, and Information Systems
Communications research at U-M is investigating the fundamental limits of performance possible in communication systems and communication networks and the practical methods of achieving close to the fundamental limits.
Optics & Photonics
The Optics and Photonics laboratories conduct research in the general areas of photonics, quantum optoelectronics, and ultrafast optical science.
Plasma Science and Engineering
Investigating fundamental transport and reaction chemistry of partially ionized gases and their application to technologies ranging from lighting sources, lasers, and sensors to materials processing, biotechnology, microelectronics fabrication, and space sciences.
Power & Energy
Energy is one of the most crucial aspects to our world today. From climate change to environmental justice to security and health, power and energy plays a major role in shaping the future.
Quantum Science & Technology
Quantum science and devices is a research area that is developing new concepts and hardware for information processing and communications using theoretical computer science, atomic physics and optics.
Robotics & Autonomous Systems
We work to improve the information gathering, computing, and decision making platforms to mobilize fully autonomous robots and systems.
Signal & Image Processing and Machine Learning
Our research is developing new models, methods, and technologies that will continue to impact diagnostic and therapeutic medicine, radar imaging, sensor networking, image compression, communications, and other areas.
Solid-State Devices & Nanotechnology
Research projects in the Solid-State area cover a wide variety of topics from integrated photonics and optoelectronics to semiconductor materials to high-frequency devices and integrated circuits to nanoscience and the development of nanotechnogies.
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Digital Commons @ USF > College of Engineering > Electrical Engineering > Theses and Dissertations
Electrical Engineering Theses and Dissertations
Theses/dissertations from 2023 2023.
On the Performance Enhancement of Beamspace MIMO and Non-orthogonal Multiple Access for Future Cellular Networks , Sinasi Cetinkaya
Enhancing Smart Grid Security and Reliability through Graph Signal Processing and Energy Data Analytics , Md Abul Hasnat
Fabric-Based Organic Electrochemical Transistor Towards Wearable pH Sensing Electronics , Nestor Osvaldo Marquez Rios
Novel Systems Engineering Framework Analysis of Photovoltaic Models and Equations , Peter R. Michael
Deep Learning Enhancement and Privacy-Preserving Deep Learning: A Data-Centric Approach , Hung S. Nguyen
Cyber-Physical Multi-Robot Systems in a Smart Factory: A Networked AI Agents Approach , Zixiang Nie
Multiple Access Techniques Enabling Diverse Wireless Services , Mehmet Mert Ćahin
Deep Reinforcement Learning Based Optimization Techniques for Energy and Socioeconomic Systems , Salman Sadiq Shuvo
Process Automation and Robotics Engineering for Industrial Processing Systems , Drake Stimpson
Theses/Dissertations from 2022 2022
Stability and Interaction Analysis of Inverter-Based Resources in Power Grids , Li Bao
Healthcare IoT System and Network Design , Halil Ibrahim Deniz
Video Anomaly Detection: Practical Challenges for Learning Algorithms , Keval Doshi
Data-Driven State Estimation for Improved Wide Area Situational Awareness in Smart Grids , Md Jakir Hossain
Deep Learning and Feature Engineering for Human Activity Recognition: Exploiting Novel Rich Learning Representations and Sub-transfer Learning to Boost Practical Performance , Ria Kanjilal
Assistive Technologies for Independent Navigation for People with Blindness , Howard Kaplan
Diagnosis of Neurodegenerative Diseases Using Higher Order Statistical Analysis of Electroencephalography Signals , Seyed Alireza Khoshnevis
Accelerating Multiparametric MRI for Adaptive Radiotherapy , Shraddha Pandey
A Model-Based Fault Diagnosis in Dynamic Systems via Asynchronous Motors System Identification or Testing, and Control Engineering Observers , Kenelt Pierre
Improving Wireless Networking from the Learning and Security Perspectives , Zhe Qu
Improving Robustness of Deep Learning Models and Privacy-Preserving Image Denoising , Hadi Zanddizari
Theses/Dissertations from 2021 2021
A Method for Compact Representation of Heterogenous and Multivariate Time Series for Robust Classification and Visualization , Alla Abdella
Dynamical System and Parameter Identification for Power Systems , Abdullah Abdulrahman Alassaf
Phasor Domain Modeling of Type-III Wind Turbines , Mohammed Alqahtani
An Automated Framework for Connected Speech Evaluation of Neurodegenerative Disease: A Case Study in Parkinson's Disease , Sai Bharadwaj Appakaya
Investigation of CoO ATO for Solar Cells and Infrared Sheaths , Manopriya Devisetty Subramanyam
Thermal Management of Lithium-ion Batteries Using Supercapacitors , Sanskruta Dhotre
Effect of Se Composition in CdSe 1-X T eX /CdTe Solar Cells , Sheikh Tawsif Elahi
Microencapsulation of Thermochromic Materials for Thermal Storage and Energy Efficiency of Buildings , Abdullatif Hakami
Piezoelectrically-Transduced ZnO-on-Diamond Resonators with Enhanced Signal-to-Noise Ratio and Power-handling Capability for Sensing and Wireless Communication Applications , Xu Han
Preparation and Characterization of Single Layer Conducting Polymer Electrochromic and Touchchromic Devices , Sharan Kumar Indrakar
Security Attacks and Defenses in Cyber Systems: From an AI Perspective , Zhengping Luo
Power System Optimization Methods: Convex Relaxation and Benders Decomposition , Minyue Ma
Metal Oxide Sensor Array Test Bed Prototype for Diagnostic Breath Analysis , Tiffany C. Miller
Packaging of Active RF Beamforming IC Utilizing Additive Manufacturing , Ryan Murphy
Adaptive Network Slicing in Fog RAN for IoT with Heterogeneous Latency and Computing Requirements: A Deep Reinforcement Learning Approach , Almuthanna Nassar
Development of a Bipolar Radiofrequency Ablation Device for Renal Denervation , Noel Perez
Copper Electrodeposition Assisted by Hydrogen Evolution for Wearable Electronics: Interconnections and Fiber Metallization , Sabrina M. Rosa Ortiz
Theory and Application of Dielectric Rod Antennas and Arrays , Gabriel Saffold
Advanced Organic Polymers for the Nanoscale Fabrication of Fiber-based Electronics Using the Electrospinning Technique , William Serrano Garcia
Transparent Planar Micro-Electrode Array for In-Vitro Electric Field Mediated Gene Delivery , Raj Himatlal Shah
High Speed Switching for Plasma Based Electroporation , Shivangi Sharma
Development of Small-Scale Power Supplies for Wearable Medical Diagnostic Devices , Donny Stiner
Novel Approach to Integrate CAN Based Vehicle Sensors with GPS Using Adaptive Filters to Improve Localization Precision in Connected Vehicles from a Systems Engineering Perspective , Abhijit Vasili
Modeling, Control and Analysis of Inverter-Based Generators in the Power Grids , Yangkun Xu
Fiber-Based Supercapacitor for Wearable Electronics , Rohit Lallansingh Yadav
Modeling, Identification, and Stability Analysis of Inverter-Based Resources Integrated Systems , Miao Zhang
Data-Oriented Approaches towards Mobile, Network and Secure Systems , Shangqing Zhao
Strategies in Botnet Detection and Privacy Preserving Machine Learning , Di Zhuang
Theses/Dissertations from 2020 2020
Architecture design and optimization of Edge-enabled Smart Grids , Adetola B. Adeniran
Multimodal Data Fusion and Attack Detection in Recommender Systems , Mehmet Aktukmak
Artificial Intelligence Towards the Wireless Channel Modeling Communications in 5G , Saud Mobark Aldossari
Enhancement of 5G Network Performance Using Non-Orthogonal Multiple Access (NOMA) , Faeik Tayseer Al Rabee
Investigation of Machine Learning Algorithms for Intrusion Detection System in Cybersecurity , Mohmmed Alrowaily
Comprehensive Optimization Models for Voltage Regulation in PV-rich Multi-phase Distribution Systems , Ibrahim Alsaleh
Design and Implementation of Solid/Solid Phononic Crystal Structures in Lateral Extensional Thin-film Piezoelectric on Silicon Micromechanical Resonators , Abdulrahman Alsolami
Analysis of Computational Modeling Methods as Applied to Single-Crystal Organohalide Perovskites , Jon M. Bebeau
Development of a Monolithic Implantable Neural Interface from Cubic Silicon Carbide and Evaluation of Its MRI Compatibility , Mohammad Beygi
Performance Enhancement Techniques for Next-Generation Multi-Service Communication and Medical Cyber-Physical Systems , Ali Fatih Demir
Microfluidically Reconfigurable Millimeter-Wave Switches, Antenna Arrays and Filters with Fast-Actuation Using Movable Metallized Plates and Integrated Actuation , Enrique J. Gonzalez Carvajal
Multilayered Transmission Lines, Antennas and Phased Arrays with Structurally Integrated Control Electronics Using Additive Manufacturing , Merve Kacar
Cost EïŹcient Algorithms and Methods for Spectral EïŹciency in Future Radio Access , Murat Karabacak
Design of DeLRo Autonomous Delivery Robot and AI Based Localization , Tolga Karakurt
Theory, Fabrication, and Characterization of Perovskite Phototransistor , Fatemeh Khorramshahi
Modeling and Control of Renewable Energy in Grids and Microgrids , Yin Li
Next-Generation Self-Organizing Communications Networks: Synergistic Application of Machine Learning and User-Centric Technologies , Chetana V. Murudkar
Reliability Analysis of Power Grids and its Interdependent Infrastructures: An Interaction Graph-based Approach , Upama Nakarmi
Algorithms Enabling Communications in the Presence of Adjacent Channel Interference , Berker Peköz
Electrospun Nanofibrous Membrane Based Glucose Sensor with Integration of Potentiostat Circuit , Kavyashree Puttananjegowda
Service Provisioning and Security Design in Software Defined Networks , Mohamed Rahouti
Reading and Programming Spintronic Devices for Biomimetic Applications and Fault-tolerant Memory Design , Kawsher Ahmed Roxy
Implementation of SR Flip-Flop Based PUF on FPGA for Hardware Security , Sai Praneeth Sagi
Trauma Detection Personal Locator Beacon System , Sakshi Sharma
Network Function Virtualization In Fog Networks , Nazli Siasi
Socially Aware Network User Mobility Analysis and Novel Approaches on Aerial Mobile Wireless Network Deployment , Ismail Uluturk
Spatial Stereo Sound Source Localization Optimization and CNN Based Source Feature Recognition , Cong Xu
Hybrid RF Acoustic Resonators and Arrays with Integrated Capacitive and Piezoelectric Transducers , Adnan Zaman
Theses/Dissertations from 2019 2019
Fabrication and Characterization of Electrical Energy Storage and Harvesting Energy Devices Using Gel Electrolytes , Belqasem Aljafari
Phasor Measurement Unit Data-Based Steady State and Dynamic Model Estimation , Anas Almunif
Cross Layer-based Intrusion Detection System Using Machine Learning for MANETs , Amar Amouri
Power Conditioning System on a Micro-Grid System , Tamoghna Banerjee
Thermal Response in a Field Oriented Controlled Three-phase Induction Motor , Niyem Mawenbe Bawana
Design and Development of a Wireless EEG System Integrated into a Football Helmet , Akshay V. Dunakhe
Machine Learning, Game Theory Algorithms, and Medium Access Protocols for 5G and Internet-of-Thing (IoT) Networks , Mohamed Elkourdi
Improving Stability by Enhancing Critical Fault Clearing Time , Ammara M. Ghani
RF Power Circuit Designs for Wi-Fi Applications , Krishna Manasa Gollapudi
Enhancing Secrecy and Capacity of Wireless Systems Using Directive Communications , Mohammed A. Hafez
Statistical Anomaly Detection and Mitigation of Cyber Attacks for Intelligent Transportation Systems , Ammar Haydari
Absorber and Window Study â CdSexTe1-x/CdTe Thin Film Solar Cells , Chih-An Hsu
Methods and Algorithms to Enhance the Security, Increase the Throughput, and Decrease the Synchronization Delay in 5G Networks , Asim Mazin
Piezoelectric ZnO Nanowires as a Tunable Interface Material for Opto-Electronic Applications , Anand Kumar Santhanakrishna
Security Framework for the Internet of Things Leveraging Network Telescopes and Machine Learning , Farooq Israr Ahmed Shaikh
Diversity and Network Coded 5G Wireless Network Infrastructure for Ultra-Reliable Communications , Nabeel Ibrahim Sulieman
The Design of Passive Networks with Full-Wave Component Models , Eric Valentino
CubeSat Constellation Design for Intersatellite Linking , Michael T. White
Theses/Dissertations from 2018 2018
Design of Micro-Scale Energy Harvesting Systems for Low Power Applications Using Enhanced Power Management System , Majdi M. Ababneh
A Study on the Adaptability of Immune System Principles to Wireless Sensor Network and IoT Security , Vishwa Alaparthy
Validation of Results of Smart Grid Protection through Self-Healing , Felipe Framil Assumpção
A Novel Framework to Determine Physiological Signals From Blood Flow Dynamics , Prashanth Chetlur Adithya
The Effect of Processing Conditions on the Energetic Diagram of CdTe Thin Films Studied by Photoluminescence , Shamara P. Collins
Physical Electronic Properties of Self-Assembled 2D and 3D Surface Mounted Metal-Organic Frameworks , Radwan Elzein
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Researching to better our world
The Texas A&M University Department of Electrical and Computer Engineering advances national and global prosperity. We research, develop and apply electrical and information technologies and sciences for the benefit of humanity. Our faculty are investigating a broad range of theoretical and real-world problems.
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Department of Electrical and Computer Engineering
MASEEH COLLEGE OF ENGINEERING AND COMPUTER SCIENCE
Power Engineering
Power engineering plays a significant role in the regional economy, with over eighty companies focused on various aspects of power. These include regional IOUs, munis, co-ops and PUDs; numerous power engineering consultancies; power equipment manufacturers; developers and independent power producers; high-tech firms focused on smart grid products; and federal entities like BPA and the Army Corp of Engineers. Investment in new generation and transmission, innovations in communications and IT, and rapidly-decreasing prices for renewable resources are all contributing to the industryâs growth.
PSUâs MS ECE power engineering track provides an industry-focused educational pathway for individuals who wish to enhance their depth in power engineering. Courses cover topics such as protection, power systems design, stability, planning and operations. Students are exposed to industry-relevant software, including ETAP, PowerWorld, ATP and ASPEN. Classes are offered in the evenings to accommodate work schedules. And, many of the instructors have been recruited from the local power industry.
Prerequisites
Students who begin this track should have a solid understanding of power systems components and fundamental power systems analysis techniques. PSUâs EE 347 (non-rotating power systems components, fundamental analytical methods) and EE 348 (rotating power systems components, power systems controls) together prepare students well for the MS ECE power engineering track.Â
EE 530 Analytical Methods for Power Systems EE 531 Power Systems Protection EE 532 Electrical Machine Analysis & Design EE 537 Advanced Power Systems Protection
Depth and Breadth Course list
EC 538 Energy Economics EE 534 Power Operations Fundamentals I EE 535 Power Operations Fundamentals II EE 536 Power Systems Stability EE 538 Dynamics and Control of AC Drives EE 539 Design of Electrical Machines ECE 533 Advanced Electromagnetics ECE 545 Power Electronic Systems Design I ECE 546 Power Electronic Systems Design II ECE 551 Control System Design I ECE 552 Control System Design II ECE 576 Computational Methods
Track Completion Forms
Program Completion Form
Thesis Program Completion Form
Track Director
Robert Bass, Associate Professor
Professor Bass established and directs the Power Engineering Research Group at Portland State University. Dr. Bassâ group focuses on utility-sector research and development challenges. His on-going projects include...
Supporting Faculty
Jonathan Bird, Associate Professor
Professor Birdâs research areas are at the intersection of applied electromagnetics, mechanics and controls. His graduate work involved investigating the performance capabilities of an electrodynamic wheel for high-speed...
Mahima Gupta, Assistant Professor
Dr. Gupta's website Dr. Gupta's research focuses on energy conversion with the aim of high power density and efficiency. Ranging from a few kilowatts to several megawatts, the focus applications include electrified...
Adjunct Faculty
Guy AlLee , MS ECE, Canonical USA Inc. Expertise: Critical Infrastructure Cybersecurity, 380 Vdc Distribution Ian Beil ,  PhD, PE, Portland General Electric. Expertise: power systems planning  Jennifer Ferris, MS ECE, Bonneville Power Administration. Expertise: power systems protection Kevin Marnel, MS ECE, Portland General Electric. Expertise: power systems protection Uben Udeh, MS EERE, PE, Portland General Electric. Expertise: power systems analysis Song Wang, PhD, PE, Portland General Electric. Expertise: stability, protection
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Electrical Engineering Research Topics Examples. 1. 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.
4. Power system protection. 5. Technical barriers for harnessing the green hydrogen: A power system perspective. 6. Evolutionary game analysis on behavior strategies of multiple stakeholders in maritime shore power system. 7. Optimal analysis of a hybrid renewable power system for a remote island. 8.
The skills that electric power engineers will require are changing accordingly. The MS in Electrical Engineering (Electric Power) is a program option for students seeking careers in the electric power industry. The plan of study combines traditional topics in power generation, transmission, and distribution with cutting-edge topics such as the ...
PSU's MS ECE power engineering track provides an industry-focused educational pathway for individuals who wish to enhance their depth in power engineering. Courses cover topics such as protection, power systems design, stability, planning and operations. Students are exposed to industry-relevant software, including ETAP, PowerWorld, ATP and ...
Research. Our research areas reflect the diversity of the electrical engineering profession and range from the very small, such as nanoscale electronic devices and their modeling, to the very large, such as the U.S. electric power grid and its control. Our faculty includes experts in many application areas, such as the design of flight control ...
2017. Sachi Jayasuriya, " Modeling and Analysis of Information-Embedded Power Electronic Converter Systems " Ph.D. Thesis, May 2017. Edwin J. John, " Experimental Testbed for Load Control on an AC/DC Microgrid " M.S. Thesis, September 2017.
Admissions Qualifications for the Power Systems Engineering Master's Degree. Excellent candidates have an ABET accredited undergraduate degree in Electrical Engineering with a GPA of 3.0 or higher. Engineers from other disciplines may be successful in Power Systems with coursework in AC Circuits and Signals as well as significant mathematics ...
The program integrates energy systems research with research in energy control, efficiency improvement, demand side management, power quality and economics, renewable resources and integration, and smart grid communications. Our faculty members are actively engaged in research in the areas of Signals, Communications and Networking; Electronics ...
Find the latest research and news on electrical and electronic engineering from Nature Portfolio, covering various topics and applications.
Programme description. Our Electrical Power Engineering MSc is a one-year programme designed to equip you with broad and robust training on modern power engineering technologies, with a strong focus on renewable energy conversion and smart grids. In semesters 1 and 2, you will acquire the advanced fundamentals, research tools and techniques of ...
Comparative Analysis of Probabilistic and Deterministic Optimization Methods to Tune the Power System Stabilizers for Enhancement of System Small-Signal Stability. Article. Apr 2020. ELECTR POW ...
Both research and research-based education at the Department of Electric Energy cover the broad interdisciplinary aspects of power engineering: generation, transmission, conversion and the use of electric energy, including the accompanying techno-economic aspects. The Department works in close collaboration with industry partners to develop ...
Integrated Circuits and Systems. This area is concerned with the application-driven design of electronic circuits and systems, spanning a wide spectrum from low frequencies to mm-wave and THz. These systems are designed with a variety of fabrics and technologies, ranging from silicon subsystems and modules, CMOS and BiCMOS chips, emerging nano ...
This research area at Michigan focuses on new opportunities in electrical energy and power systems that are arising with advances in materials, communications, computation, and control. Students and faculty are investigating energy conversion systems where enhanced performance of electrical machines and power electronics is being exploited to ...
How Long It Will Take. To earn the Master of Science in Electrical Engineering degree, you must complete 45 units. As a part-time student, you can expect to finish the degree in 3 to 5 years. As a full-time student, you can expect to finish the degree in 1 to 2 years.
Electrical engineers design the most sophisticated systems ever built. From computers with billions of transistors to microgrids fed by renewable energy sources, from algorithms that predict disease to solar cells and electric vehicles, electrical engineering touches all parts of modern society. We leverage computational, theoretical, and ...
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.
Scholars focus on and apply research methods from education, learning sciences, and social-behavioral sciences to advance the success of engineering. ... Research projects in the Solid-State area cover a wide variety of topics from integrated photonics and optoelectronics to semiconductor materials to high-frequency devices and integrated ...
Design of Micro-Scale Energy Harvesting Systems for Low Power Applications Using Enhanced Power Management System, Majdi M. Ababneh. PDF. A Study on the Adaptability of Immune System Principles to Wireless Sensor Network and IoT Security, Vishwa Alaparthy. PDF. Validation of Results of Smart Grid Protection through Self-Healing, Felipe Framil ...
Core Courses ; Sr.No Course Code Subjects Credit Hours Related SDG Pre Requisite Course Content; 1: EE-863: Power Systems Analysis: 3+0: 7,8,9,11: 2: EPE-800: Power System Operation, Control and Optimization
What opportunities might MS Electrical Engineering lead to? ... Special Topics in Power Electronics: 3: Advanced Power Electronics: 7. EE5209: Power System Protection: 3: 8. ... Advanced Statistical Methods for Engineering Research: 3: General Electives. S. No. Course Code: Course Title: Credit Hours: Pre-requisite: 1.
Researching to better our world. The Texas A&M University Department of Electrical and Computer Engineering advances national and global prosperity. We research, develop and apply electrical and information technologies and sciences for the benefit of humanity. Our faculty are investigating a broad range of theoretical and real-world problems.
PSU's MS ECE power engineering track provides an industry-focused educational pathway for individuals who wish to enhance their depth in power engineering. Courses cover topics such as protection, power systems design, stability, planning and operations. Students are exposed to industry-relevant software, including ETAP, PowerWorld, ATP and ...