Engineering Technology

Electrical Engineering Technology Concentration

The Electrical Engineering Technology (EET) concentration at Drexel University prepares students to design, develop, implement, and maintain the electrical and electronic systems that power and connect today’s world. Rooted in Drexel’s multidisciplinary, practice-based approach to engineering education, the EET concentration emphasizes applied learning, systems thinking, and real-world problem solving.

Students in this program gain a deep understanding of electrical and electronic principles, paired with extensive experience applying these concepts to modern technologies. The curriculum is designed to develop engineers who are technically skilled, solution-oriented, and equipped to work across industries that demand innovative thinking and hands-on capability.


Curriculum Highlights

The EET concentration provides a strong foundation in:

  • Electric circuit analysis and electronic systems
  • Digital and analog electronics
  • Embedded systems and digital design
  • Power systems and renewable energy
  • Control systems and automation
  • Instrumentation, testing, and troubleshooting
  • Computer-aided design and simulation tools

Students participate in lab-intensive courses, team-based projects, and a three-term senior capstone design project, often conducted in partnership with industry sponsors. Through these experiences, students learn how to analyze requirements, develop system-level solutions, and build functional prototypes that reflect real-world applications.

In addition to core coursework, students take technical and free electives, enabling them to explore specialized topics and tailor the program to their career interests.


Applied, Multidisciplinary Education

Consistent with the Engineering Technology program’s broader mission, EET students benefit from exposure to mechanical, industrial, and computer systems, preparing them to work effectively in multidisciplinary engineering teams. The program emphasizes communication, project management, and the integration of engineering technologies, reflecting the complexity and collaborative nature of modern technical environments.

Students also participate in Drexel’s cooperative education (co-op) program, gaining up to 18 months of paid, full-time industry experience. These co-op placements provide a competitive edge in the job market and often lead directly to full-time employment opportunities.


Career Outlook

Graduates of the EET concentration are well prepared for careers in industries such as:

  • Power systems and energy distribution
  • Electronics design and development
  • Automation and control systems
  • Telecommunications and embedded systems
  • Medical device and healthcare technology
  • Aerospace, defense, and security systems

Representative job titles include:

  • Electrical Systems Engineer
  • Electronics Design Engineer
  • Test and Validation Engineer
  • Power Systems Engineer
  • Automation and Controls Engineer
  • Embedded Systems Engineer 
  • Field Applications Engineer

Graduates are recognized as technically proficient engineers who can translate electrical theory into functional, efficient, and innovative systems. The program also serves as a solid foundation for graduate studies in areas such as engineering management, systems engineering, and applied research.

The EET concentration is part of Drexel’s ABET-accredited Engineering Technology program, supporting students’ eligibility for Fundamentals of Engineering (FE) and Professional Engineer (PE) licensure.

Additional Information

For more information, visit the BS in Engineering Technology page.

Degree Requirements

University Requirements
CIVC 101Introduction to Civic Engagement1.0
COOP 101Career Management and Professional Development *1.0
UNIV E101The Drexel Experience1.0
Humanites and Social Sciences Requirements
COM 230Techniques of Speaking3.0
ENGL 101Composition and Rhetoric I: Inquiry and Exploratory Research3.0
or ENGL 111 English Composition I
ENGL 102Composition and Rhetoric II: Advanced Research and Evidence-Based Writing3.0
or ENGL 112 English Composition II
ENGL 103Composition and Rhetoric III: Themes and Genres3.0
or ENGL 113 English Composition III
HIST 285Technology in Historical Perspective4.0
PHIL 315Engineering Ethics3.0
General Education Electives **9.0
Basic Science Requirements
Chemistry Requirements ***
Select one of the following options based on placement test scores3.5-5.5
Option A:
General Chemistry I
Option B:
General Chemistry I
and General Chemistry I Laboratory
Physics Requirements
Select one of the following options based on placement exam:8.0-12.0
Option A:
Introductory Physics I
Introductory Physics II
Introductory Physics III
Option B:
Fundamentals of Physics I
Fundamentals of Physics II
Mathematics Requirements ††
Select one of the following options based on placement exam:4.0-10.0
Option A:
Calculus I
Option B:
Calculus and Functions I
and Calculus and Functions II †††
Option C:
Algebra, Functions, and Trigonometry
and Calculus I
Option D (Transfer students):
Precalculus
and Calculus I
MATH 122Calculus II4.0
STAT 201Introduction to Business Statistics4.0
Engineering Technology Core
CMGT 240Economic Planning for Construction3.0
or CIVE 240 Engineering Economic Analysis
ENGR 111Introduction to Engineering Design & Data Analysis3.0
EET 201Circuit Analysis I4.0
EET 202Circuit Analysis II4.0
EET 205Digital Electronics 4.0
EET 208Introduction to Programming for Embedded Systems3.0
EET 209Fundamentals of Virtual Instrumentation3.0
EET 210Introduction to Intelligent Systems for Engineering Applications3.0
EET 311Modeling of Engineering Systems4.0
EET 319PLC Fundamentals4.0
EET 320Renewable Energy Systems3.0
EET 401Applied Microcontrollers4.0
INDE 370Industrial Project Management3.0
or PROJ 401 Introduction to Project Management
MET 100Graphical Communication3.0
MET 101Engineering Materials3.0
MET 204Applied Quality Control3.0
MET 205Robotics and Mechatronics3.0
MET 209Fluid Power4.0
MET 213Applied Mechanics4.0
MET 300Principles of Engineering Design4.0
MHT 205Thermodynamics I3.0
MHT 226Measurement Techniques and Instrumentation3.0
Electrical Engineering Technology Concentration Requirements
EET 206Analog Electronics I4.0
EET 313Signals and Systems I4.0
EET 317Analog Electronics II4.0
EET 322Energy Conversion4.0
EET 323Electrical Systems Design3.0
EET 324Power Electronics4.0
EET 325Microprocessors3.0
EET 412Electronics Manufacturing4.0
EET (Electrical Engineering Technology) Electives
Select 6.0 of 300-499 non-required courses from the list below: 6.0
Any EET (Electrical Engineering Technology) course
Any INDE (Industrial Engineering) course
Any MET (Manufacturing Engineering Technology) course
Any MHT (Mechanical Engineering Technology) course
Capstone Course Requirements
MET 421Senior Design Project I3.0
MET 422Senior Design Project II3.0
MET 423Senior Design Project III3.0
Free Electives
Select any unrestricted course within the 100-499 level6.0
Total Credits180.5-192.5
*

Students not participating in co-op will not take COOP 101; 1 credit of Free Elective will be added in place of COOP 101.

**

See General Education Requirements

***

CHEM sequence is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

PHYS course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score. Students must also successfully complete MATH 121 to take PHYS 101. Students may instead place into PHYS 152 in Fall term.

††

MATH course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

†††

Some students may need a one-credit concurrent practicum course depending on their calculus exam score and summer preparatory review participation.

See advisor.

Writing-Intensive Course Requirements

In order to graduate, all students must pass three writing-intensive courses after their freshman year. Two writing-intensive courses must be in a student's major. The third can be in any discipline. Students are advised to take one writing-intensive class each year, beginning with the sophomore year, and to avoid “clustering” these courses near the end of their matriculation. Transfer students need to meet with an academic advisor to review the number of writing-intensive courses required to graduate.

A "WI" next to a course in this catalog may indicate that this course can fulfill a writing-intensive requirement. For the most up-to-date list of writing-intensive courses being offered, students should check the Writing Intensive Course List at the University Writing Program. Students scheduling their courses can also conduct a search for courses with the attribute "WI" to bring up a list of all writing-intensive courses available that term.

Sample Plan of Study

4 year, no co-op

Plan of Study Grid
First Year
FallCredits
CHEM 101 General Chemistry I * 0.0,3.5
ENGL 101
Composition and Rhetoric I: Inquiry and Exploratory Research
or English Composition I
3.0
ENGR 111 Introduction to Engineering Design & Data Analysis 3.0
MATH 121 Calculus I ** 4.0
UNIV E101 The Drexel Experience 1.0
 Credits11-14.5
Winter
CIVC 101 Introduction to Civic Engagement 1.0
EET 208 Introduction to Programming for Embedded Systems 3.0
ENGL 102
Composition and Rhetoric II: Advanced Research and Evidence-Based Writing
or English Composition II
3.0
MATH 122 Calculus II 4.0
MET 100 Graphical Communication 3.0
PHYS 101 Fundamentals of Physics I *** 4.0
 Credits18
Spring
EET 209 Fundamentals of Virtual Instrumentation 3.0
ENGL 103
Composition and Rhetoric III: Themes and Genres
or English Composition III
3.0
MET 101 Engineering Materials 0.0,3.0
PHYS 102 Fundamentals of Physics II 4.0
 Credits10-13
Summer
VACATION  
 Credits0
Second Year
Fall
EET 201 Circuit Analysis I 0.0,4.0
EET 320 Renewable Energy Systems 3.0
MET 209 Fluid Power 0.0,4.0
STAT 201 Introduction to Business Statistics 4.0
 Credits7-15
Winter
EET 202 Circuit Analysis II 0.0,4.0
EET 205 Digital Electronics 0.0,4.0
EET 210 Introduction to Intelligent Systems for Engineering Applications 3.0
MET 205 Robotics and Mechatronics 0.0,3.0
MHT 205 Thermodynamics I 3.0
 Credits6-17
Spring
CMGT 240 Economic Planning for Construction 3.0
COM 230 Techniques of Speaking 3.0
HIST 285 Technology in Historical Perspective 4.0
PHIL 315 Engineering Ethics 3.0
 Credits13
Summer
VACATION  
 Credits0
Third Year
Fall
EET 206 Analog Electronics I 4.0
EET 311 Modeling of Engineering Systems 4.0
EET 319 PLC Fundamentals 4.0
MET 213 Applied Mechanics 4.0
 Credits16
Winter
EET 401 Applied Microcontrollers 4.0
INDE 370 Industrial Project Management 3.0
MET 204 Applied Quality Control 3.0
MET 300 Principles of Engineering Design 4.0
MHT 226 Measurement Techniques and Instrumentation 3.0
 Credits17
Spring
General Education Elective 6.0
Technical Elective †† 3.0
Free Elective 4.0
 Credits13
Summer
VACATION  
 Credits0
Fourth Year
Fall
EET 322 Energy Conversion 4.0
EET 323 Electrical Systems Design 3.0
EET 412 Electronics Manufacturing 4.0
MET 421 Senior Design Project I 3.0
 Credits14
Winter
EET 313 Signals and Systems I 4.0
EET 317 Analog Electronics II 4.0
EET 324 Power Electronics 4.0
MET 422 Senior Design Project II 3.0
 Credits15
Spring
EET 325 Microprocessors 3.0
MET 423 Senior Design Project III 3.0
General Education elective 3.0
Technical Elective †† 3.0
Free Elective 3.0
 Credits15
 Total Credits155-180.5
*

CHEM course is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

**

MATH course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

***

PHYS course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score. Students must also successfully complete MATH 121 to take PHYS 101. Students may instead place into PHYS 152 in the Fall term.

See General Education Requirements

††

Select 6.0 additional credits from any BET, EET, MET, MHT or INDE courses not already required. See advisor for specific courses.

4 year, one co-op

Plan of Study Grid
First Year
FallCredits
CHEM 101 General Chemistry I * 0.0,3.5
ENGL 101
Composition and Rhetoric I: Inquiry and Exploratory Research
or English Composition I
3.0
ENGR 111 Introduction to Engineering Design & Data Analysis 3.0
MATH 121 Calculus I ** 4.0
UNIV E101 The Drexel Experience 1.0
 Credits11-14.5
Winter
CIVC 101 Introduction to Civic Engagement 1.0
EET 208 Introduction to Programming for Embedded Systems 3.0
ENGL 102
Composition and Rhetoric II: Advanced Research and Evidence-Based Writing
or English Composition II
3.0
MATH 122 Calculus II 4.0
MET 100 Graphical Communication 3.0
PHYS 101 Fundamentals of Physics I *** 4.0
 Credits18
Spring
COOP 101 Career Management and Professional Development 1.0
EET 209 Fundamentals of Virtual Instrumentation 3.0
ENGL 103
Composition and Rhetoric III: Themes and Genres
or English Composition III
3.0
MET 101 Engineering Materials 0.0,3.0
PHYS 102 Fundamentals of Physics II 4.0
 Credits11-14
Summer
VACATION  
 Credits0
Second Year
Fall
EET 201 Circuit Analysis I 0.0,4.0
EET 320 Renewable Energy Systems 3.0
MET 209 Fluid Power 0.0,4.0
STAT 201 Introduction to Business Statistics 4.0
 Credits7-15
Winter
EET 202 Circuit Analysis II 0.0,4.0
EET 205 Digital Electronics 0.0,4.0
EET 210 Introduction to Intelligent Systems for Engineering Applications 3.0
MET 205 Robotics and Mechatronics 0.0,3.0
MHT 205 Thermodynamics I 3.0
 Credits6-17
Spring
CMGT 240 Economic Planning for Construction 3.0
COM 230 Techniques of Speaking 3.0
HIST 285 Technology in Historical Perspective 4.0
PHIL 315 Engineering Ethics 3.0
 Credits13
Summer
General Education Elective †† 6.0
Technical Elective ††† 3.0
Free Elective 6.0
 Credits15
Third Year
Fall
EET 206 Analog Electronics I 4.0
EET 311 Modeling of Engineering Systems 4.0
EET 319 PLC Fundamentals 4.0
MET 213 Applied Mechanics 4.0
 Credits16
Winter
EET 401 Applied Microcontrollers 4.0
INDE 370 Industrial Project Management 3.0
MET 204 Applied Quality Control 3.0
MET 300 Principles of Engineering Design 4.0
MHT 226 Measurement Techniques and Instrumentation 3.0
 Credits17
Spring
COOP EXPERIENCE  
 Credits0
Summer
COOP EXPERIENCE  
 Credits0
Fourth Year
Fall
EET 322 Energy Conversion 4.0
EET 323 Electrical Systems Design 3.0
EET 412 Electronics Manufacturing 4.0
MET 421 Senior Design Project I 3.0
 Credits14
Winter
EET 313 Signals and Systems I 4.0
EET 317 Analog Electronics II 4.0
EET 324 Power Electronics 4.0
MET 422 Senior Design Project II 3.0
 Credits15
Spring
EET 325 Microprocessors 3.0
MET 423 Senior Design Project III 3.0
General Education elective †† 3.0
Technical elective ††† 3.0
 Credits12
 Total Credits155-180.5
*

CHEM course is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

**

MATH course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

***

PHYS course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score. Students must also successfully complete MATH 121 to take PHYS 101. Students may instead place into PHYS 152 in the Fall term.

COOP 101 registration is determined by the co-op cycle assigned and may be scheduled in a different term. Select students may be eligible to take COOP 001 in place of COOP 101.

††

See General Education Requirements

†††

Select 6.0 additional credits from any BET, EET, MET, MHT or INDE courses not already required. See advisor for specific courses.

5 Year, 3 co-op

Plan of Study Grid
First Year
FallCredits
CHEM 101 General Chemistry I * 0.0,3.5
ENGL 101
Composition and Rhetoric I: Inquiry and Exploratory Research
or English Composition I
3.0
ENGR 111 Introduction to Engineering Design & Data Analysis 3.0
MATH 121 Calculus I ** 4.0
UNIV E101 The Drexel Experience 1.0
 Credits11-14.5
Winter
CIVC 101 Introduction to Civic Engagement 1.0
EET 208 Introduction to Programming for Embedded Systems 3.0
ENGL 102
Composition and Rhetoric II: Advanced Research and Evidence-Based Writing
or English Composition II
3.0
MATH 122 Calculus II 4.0
MET 100 Graphical Communication 3.0
PHYS 101 Fundamentals of Physics I *** 4.0
 Credits18
Spring
COOP 101 Career Management and Professional Development 1.0
EET 209 Fundamentals of Virtual Instrumentation 3.0
ENGL 103
Composition and Rhetoric III: Themes and Genres
or English Composition III
3.0
MET 101 Engineering Materials 0.0,3.0
PHYS 102 Fundamentals of Physics II 4.0
 Credits11-14
Summer
VACATION  
 Credits0
Second Year
Fall
EET 201 Circuit Analysis I 0.0,4.0
EET 320 Renewable Energy Systems 3.0
MET 209 Fluid Power 0.0,4.0
STAT 201 Introduction to Business Statistics 4.0
 Credits7-15
Winter
EET 202 Circuit Analysis II 0.0,4.0
EET 205 Digital Electronics 0.0,4.0
EET 210 Introduction to Intelligent Systems for Engineering Applications 3.0
MET 205 Robotics and Mechatronics 0.0,3.0
MHT 205 Thermodynamics I 3.0
 Credits6-17
Spring
COOP EXPERIENCE  
 Credits0
Summer
COOP EXPERIENCE  
 Credits0
Third Year
Fall
COM 230 Techniques of Speaking 3.0
EET 311 Modeling of Engineering Systems 4.0
EET 319 PLC Fundamentals 4.0
MET 213 Applied Mechanics 4.0
 Credits15
Winter
CMGT 240
Economic Planning for Construction
or Engineering Economic Analysis
3.0
EET 401 Applied Microcontrollers 4.0
MET 204 Applied Quality Control 3.0
MET 300 Principles of Engineering Design 4.0
MHT 226 Measurement Techniques and Instrumentation 3.0
 Credits17
Spring
COOP EXPERIENCE  
 Credits0
Summer
COOP EXPERIENCE  
 Credits0
Fourth Year
Fall
EET 206 Analog Electronics I 4.0
EET 322 Energy Conversion 4.0
EET 323 Electrical Systems Design 3.0
PHIL 315 Engineering Ethics 3.0
 Credits14
Winter
EET 313 Signals and Systems I 0.0,4.0
EET 317 Analog Electronics II 0.0,4.0
EET 324 Power Electronics 4.0
INDE 370 Industrial Project Management 3.0
 Credits7-15
Spring
COOP EXPERIENCE  
 Credits0
Summer
COOP EXPERIENCE  
 Credits0
Fifth Year
Fall
EET 412 Electronics Manufacturing 4.0
HIST 285 Technology in Historical Perspective 4.0
MET 421 Senior Design Project I 3.0
Technical elective †† 3.0
 Credits14
Winter
MET 422 Senior Design Project II 3.0
General Education elective ††† 6.0
Technical elective †† 3.0
Free Elective 3.0
 Credits15
Spring
EET 325 Microprocessors 3.0
MET 423 Senior Design Project III 3.0
General Education elective ††† 3.0
Free elective 3.0
 Credits12
 Total Credits147-180.5
*

CHEM course is determined by the student's Chemistry Placement Exam score and the completion of a summer online preparatory course available based on that score.

**

MATH course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score.

***

PHYS course is determined by the student's Calculus Placement Exam score and the completion of any summer online preparatory courses available based on that score. Students must also successfully complete MATH 121 to take PHYS 101. Students may instead place into PHYS 152 in Fall term.

COOP 101 registration is determined by the co-op cycle assigned and may be scheduled in a different term. Select students may be eligible to take COOP 001 in place of COOP 101.

††

Select 6.0 additional credits from any BET, EET, MET, MHT or INDE courses not already required. See advisor for specific courses.

†††

See General Education Requirements

Program Level Outcomes

Upon completion of the program, graduates will be prepared to:

  • Apply knowledge, techniques, skills and modern tools of mathematics, science, engineering, and technology to solve broadly-defined engineering problems appropriate to the discipline;
  • Design systems, components, or processes meeting specified needs for broadly-defined engineering problems appropriate to the discipline;
  • Apply written, oral, and graphical communication in broadly-defined technical and non-technical environments; and an ability to identify and use appropriate technical literature;
  • Conduct standard tests, measurements, and experiments and to analyze and interpret the results to improve processes; and
  • Function effectively as a member as well as a leader on technical teams.