Moizuddin Mohammed is seeking a position in electrical power systems engineering. He has an MS in Electrical Engineering from Michigan Technological University with a 3.62 GPA expected in December 2015. His areas of expertise include power system protection, load flow studies, and power electronics. His projects include series and shunt compensation techniques, designing a distance protection scheme, and developing programs for unit commitment and economic dispatch. He has skills in software like ASPEN, PowerWorld, GAMS, and MATLAB. He completed an internship at Bharat Heavy Electricals where he studied circuit breaker testing and dielectric mediums.

1. 2013, 2013 Woodmar Dr, Apt C
Moizuddin Mohammed
mmohamm4@mtu.edu
HouH Houghton, MI, 49931 309-566-9293
OBJECTIVE
To obtain a full-time opportunity in the field of electrical power systems engineering.
EDUCATION
Michigan Technological University Houghton, MI
MS Electrical Engineering, GPA: 3.62 Expected Dec 2015
Relevant Courses: Advanced Methods in Power Systems, Power System Operations, Transient System Analysis,
Distribution Engineering, PowerSystem Protection (Course & Lab),Computer Models of PowerSystem,PowerElectronics
(Course & Lab), Energy Storage Systems.
JawaharlalNehru Technological University Hyderabad, India
B-Tech in Electrical and Electronics Engineering, GPA: 3.75 October 2009 – May 2013
PROFILE
 Specialization in Electrical Power Systems.
 Developed Mini-UPS system to provide uninterrupted power supply.
 Designed Distance Protection scheme for a 110 KV, 3 BUS system using ASPEN.
 Load flow study of 57-BUS IEEE system and calculation of incremental loss factors.
 Simulated and studied the different series and shunt compensation techniques.
 Developed program for Unit Commitment and Economic Dispatch for Large Power System.
 Feedback control of Buck, Boost converters, both simulation and hardware.
 Load flow study of 14-Bus IEEE system using MATLAB.
INTERESTS AND EXPERTISE:
Electrical Power Systems, Power System Protection, Load Flow Studies, Short-Circuit Analysis, Economic Operations of
Power Systems, Distribution Systems, Computer Modeling of Power Systems,Power Electronics, and Feedback Control of
Power Converters.
COMPUTER/TECHNICAL SKILLS:
 ASPEN
 PowerWorld
 GAMS
 CYME
 MATLAB
 Simulink
 EMTP-ATP
 Ms-Office
 Multisim
 LabVIEW
 C/C++
 AcSELerator Quickset
ENGINEERING PROJECT EXPERIENCE:
Series and Shunt Compensation ofexisting AC line
 The Power Transfer Capability of an existing transmission line is increased using voltage compensation techniques.
 Designed a 6-Bus interconnected system using ASPEN and PowerWorld.
 Implemented the different techniques such as series capacitor compensation, shunt compensation, phase shifting
transformer, adding additional lines and maintained the p.u voltage at all the buses in the range 0.95-1.00 p.u.
 Analyzed the advantages and disadvantages of different techniques employed.
 Shunt compensation was the most feasible technique among all. Series compensation technique had the limitation
of sub-synchronous resonance.
110 KV Transmission Line Protection using Distance Relay Scheme
 Aim was to design and implement a distance protection scheme for a 110 KV transmission line.
 Considered a 2-Generator, 3-Bus interconnected system.
 Designed the model in EMTP-ATP and the transients due to different faults and switching were studies.
 Developed a code in MATLAB to calculate the relay settings.
 SEL 221f relay was considered and the relay scheme was verified for different fault conditions using ASPEN.
Load Flow Study of IEEE-57 Bus System and determining Incremental Loss Factors
 Developed a MATLAB code to read data form IEEE-57 Bus .cdf file and to form the bus admittance and Jacobian
matrices.
 The active power injection at the PV buses was varied by +/- 10% and the variation in the voltage phase angles was
observed by solving the load flow problem using the Newton – Raphson method.
 Developed a code in MATLAB which calculated the loss factors using Hill-Stevenson method.

2. Unit Commitment and Economic Dispatch of Large Power System
 Considered a standard IEEE-118 Bus system with 54 generating units.
 Considered different constraints on the system such as generator constraints, minimum up and down time
constraints, ramp up and ramp down constraints.
 Solved the system using GAMS simulation tool.
 Unit commitment problem was successfully demonstrated for a 24 hour schedule.
Feedback Control of Power Converters
 Designed and implemented a 10-15V input 40V output boost converter.
 Calculated the passive elements required for the given specifications and designed a simulation model using
Simulink tool.
 Verified the working of the simulation model to meet the given requirements over an output load range.
 Constructed the PWM switching circuit and implemented the hardware model for the given requirements.
 The hardware model was successfully implemented and working of the model was verified for an output load range
of 10-100W and with 1% variation in the output voltage.
Load Flow Study of IEEE 14-Bus system
 Aim of the project was to develop a MATLAB code to solve the Newton –Raphson load flow problem.
 MATLAB code was developed to extract the data form a standard IEEE-14 Bus .cdf file and to form the bus
admittance and Jacobian matrices.
 Developed a MATLAB code to solve the load flow problem using Newton-Raphson method and write the output
to a text file.
 Load flow problem wassuccessfully solved using Newton-Raphson method and the tolerance considered was0.001.
Mini-UPS System (Under Graduate Level)
 Aim of the project was to construct a model to provide uninterrupted power supply.
 Designed a model which provides supply to a load from a 230V AC supply and charges the battery.
 The battery rating was 5V, 1020mAH.
 The battery was charged using a step-down transformer, rectifier and a voltage regulator circuits.
 Using sensors and inverter circuits the battery was discharged to supply the load whenever the main supply was
cut-off.
 A single-phase 50W load was considered for this design project.
Internal Fault modelling of Transformers
 Developed a transformer model using EMTP-ATP.
 The internal core of the transformer was considered in the model.
 Developed internal faults on the transformer.
 Studied the transient over-voltages and current behavior of the transformer under fault conditions.
3-Phase fault detection system (Under Graduate Level)
 Designed a fault detection and display system.
 Used CT’s and microprocessor to detect the fault.
 Used relays and circuit breakers to cut of the faulted phases from supply.
 Displayed the type of fault occurred using LED display.
PROFESSIONAL EXPERIENCE
Bharat Heavy Electricals Limited,Hyderabad, India
 Literature review on the operation and different kinds of circuit breakers was done.
 The arc-quenching mechanism was studied.
 Studied the testing of 800 KV double pole circuit breaker.
 Analyzed the different tests done on the circuit breaker.
 Studied the different types of dielectric mediums used.
HONORS AND ACTIVITIES
 Presented papers on topics like “Corona and its effects” and “Lightning Arresters“.
 Participated in many seminars and Tech-fests.
 Active member of Council of Hansen’s Social Welfare.
 Student supervisor at the Wadsworth dining hall.