Robotics Engineering, BS

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Program Education Objectives
Student Outcomes
Dual Degrees With Robotics Engineering
Curriculum Sequence

Robotics engineering is an emerging discipline that is appearing in a wide variety of industries and is on the cusp of impacting every aspect of the way we work and live. This multidisciplinary field integrates knowledge from various areas such as smart sensors, controls, and electrical and mechanical engineering. The overarching goal of robotics engineers is to create systems that can do work that is dangerous or not suitable for humans, or perform tasks with speed and accuracy that are otherwise unachievable.

A degree in robotics engineering provides an excellent springboard into an engineering career in a variety of potential fields. Some examples of robotics engineering applications include intelligent, collaborative, and adaptive robots; assistive devices and rehabilitation; autonomous vehicles; precision and remote surgery; military/law enforcement; environmental remediation; and office/consumer appliances. Job growth for robotics engineers is anticipated to rise rapidly to meet the demand to invent, research, design, manufacture, sell, and service robotic systems and components.

The robotics engineering program provides a broad-based education in a supportive environment that encourages inquisitive, analytical, and creative thinking and exposes students to real-world practical aspects of the engineering profession.

Program Education Objectives

Graduates of Widener’s Robotics Engineering program are expected to demonstrate the following career and professional accomplishments a few years after graduation:

Successfully practice in robotics or related fields in a wide array of industries, academia, nonprofit organizations, and government agencies
Engage in continuous learning through professional development or pursuit of advanced degrees
Assume increasing levels of leadership and enhance leadership competencies
Demostrate ethical decision making, professionalism, and service to the community

Student Outcomes

Over the course of their studies, graduates of the program shall have demonstrated:

1. an ability to identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics

2. an ability to apply engineering design to produce solutions that meet specified needs with consideration of public health, safety, and welfare, as well as global, cultural, social, environmental, and economic factors

3. an ability to communicate effectively with a range of audiences

4. an ability to recognize ethical and professional responsibilities in engineering situations and make informed judgments, which must consider the impact of engineering solutions in global, economic, environmental, and societal contexts

5. an ability to function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives

6. an ability to develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions

7. an ability to acquire and apply new knowledge as needed, using appropriate learning strategies

Curriculum Sequence

First Year

Fall (16.5 Credits)

ASC 101 - Thinking Through 3 Credit(s)
ENGL 101 - Reading, Thinking and Writing 3 Credit(s)
ENGR 111 - Engineering Techniques 2 Credit(s)
MATH 141 - Calculus I 4 Credit(s)
CHEM 135 - General Chemistry for Engineers 3 Credit(s)
CHEM 137 - General Chemistry Lab for Engineers (W) 1 Credit(s)
Physical Education Elective 0.5 Credit(s)

Spring (16.5 Credits)

ENGR 112 - Computer Programming and Engineering Problem Solving 2 Credit(s)
ENGR 114 - Engineering Graphics and Computer-Aided Design 2 Credit(s) *
MATH 142 - Calculus II 4 Credit(s)
PHYS 161 - Physics I 3 Credit(s)
PHYS 163 - Physics I Laboratory 1 Credit(s)
RE 101 - Introduction to Robotic Systems 1 Credit(s)
Humanities Elective 3 Credit(s)
Physical Education Elective 0.5 Credit(s)

Sophomore

Fall (18 Credits)

ENGR 213 - Statics 3 Credit(s)
ENGR 219 - Electric Circuits 3 Credit(s)
ENGR 223 - Electric Circuits Laboratory 1 Credit(s)
MATH 241 - Multivariable Calculus 4 Credit(s)
PHYS 162 - Physics II 3 Credit(s)
PHYS 164 - Physics II Laboratory 1 Credit(s)
RE 202 - Object-Oriented Programming for Robotic Applications 3 Credit(s)

Spring (17 Credits)

EC 202 - Principles of Microeconomics 3 Credit(s)
EE 230 - Logic Design 3 Credit(s)
ENGR 214 - Dynamics 3 Credit(s)
MATH 331 - Linear Algebra 4 Credit(s)
RE 203 - Introduction to Mechatronics 3 Credit(s)
RE 204 - Introduction to Mechatronics Laboratory (W) 1 Credit(s)

Junior

Fall (16 Credits)

EE 347 - Introduction to Electronics 3 Credit(s)
ENGR 315 - Probability, Statistics, and Random Processes 3 Credit(s)
MATH 242 - Elementary Differential Equations 3 Credit(s)
ME 351 - Kinematics 3 Credit(s)
RE 301 - Signal Analysis in Robotic Systems 3 Credit(s)
RE 303 - Programmable Logic Controller Laboratory 1 Credit(s)

Spring (16 Credits)

EE 471 - Controls I 3 Credit(s)
ENGR 328 - Computational Methods in Engineering 3 Credit(s)
ENGR 323 - Mechanics of Deformable Bodies 3 Credit(s)
PHIL 352 - Business Ethics 3 Credit(s)
RE 302 - Mechanics of Robotic Systems 3 Credit(s)
RE 304 - Advanced Automation Laboratory 1 Credit(s)

Senior

Fall (15 Credits)

ASC 401 - Transformations Capstone 3 Credit(s)
ENGR 401 - Senior Project I 2 Credit(s)
RE 401 - Control of Robotic Systems 3 Credit(s)
RE 406 - Robotic Vision 3 Credit(s)
RE 407 - Mobile Robotics and Perception Lab 1 Credit(s)
Social Science Elective 3 Credit(s)

Spring (15 Credits)

ENGR 402 - Senior Project II 2 Credit(s)
RE 402 - Professional Seminar (W) 1 Credit(s)
Two RE Technical Electives 6 Credits **
Humanities Elective 3 Credit(s)
Social Science Elective 3 Credit(s)

Total Credits: 130

*Students may take ENGR 113 Computer-Aided Engineering Design in lieu of ENGR 114 Engineering Graphics and Computer-Aided Design.

**Students may take 400-level courses in BME, EE and ME, subject to the approval from academic advisor and course instructor.

**A student who wishes to take a graduate course must have a cumulative GPA and a cumulative Tech GPA of 3.0 or higher, and must get the approval of their academic advisor.

The program of study that appears here applies to students who were admitted for the summer session of this catalog year and later. Students admitted prior to that term should select the appropriate catalog year of their admission. Choose previous catalogs from the Home, Graduate, or Undergraduate Catalog Page at http://Catalog.widener.edu.

Dual Degrees with Robotics Engineering

Students have the option to pursue dual degrees with other majors such as Biomedical Engineering, BS , Electrical Engineering, BS , Mechanical Engineering, BS , and computer science. Additional credits are required to satisfy the requirements of each degree earned. Students should contact the department chair to coordinate their plan of study early in the freshman year.