Program Overview

Bachelor of Science in Cybersecurity Engineering

Overview

Cybersecurity engineers identify threats and vulnerabilities in software, networks, and other systems. They apply their skills to design, develop, and implement high-tech solutions to defend against hacking, malware and ransomware, insider threats and all types of cyber crime. In addition to designing and developing safeguards, cybersecurity engineers continually monitor their systems and update them when necessary to prevent zero-day threats (from new and novel malware) and other emerging cybercriminal activity. For companies, cybersecurity engineers protect both information and the overall bottom line. Because of this, cybersecurity engineers are vital to the success of the organizations they serve.

Educational Objectives

Graduates who have earned a Bachelor’s Degree in Cybersecurity Engineering, within a few years following graduation, will have demonstrated technical proficiency, collaborative activities, and professional development.

• Technical Proficiency: Graduates will have achieved success and visibility in their chosen careers as shown by technical accomplishments in industry, government, entrepreneurial activities, or academia.
• Collaborative Activities: Graduates will have exercised shared responsibilities through activities such as contributions to multi-person or multi-disciplinary technical projects, participation in professional society/organization functions, or performing collaborative research. In all such cases, graduates will have contributed to documentation of the collaborative activities.
• Professional Development: Graduates will have demonstrated continual updating to extend their expertise and adapt to a changing environment through graduate studies; short courses, conferences, and seminars; or professional self-study. In addition, graduates will have demonstrated evidence of increasing technical and/or managerial impact.

Undergraduate Admission to the School of Engineering

Admission to the KU School of Engineering and its degree programs is selective. Students may be admitted to an engineering or computer science degree program as freshmen (first-year) students, but all admissions, for both in-state and out-of-state students, are selective. Applications are judged on several factors, such as high school record, scores on national tests, academic record at college or university level, and trend of grades and more. High school transcripts are required.

Freshman Admission Standards to the School of Engineering

To be considered for admission to the School of Engineering, beginning freshmen (first-year) students must meet or exceed the following minimum standards:

• Must be admissible to the University of Kansas by assured admissions or individual review, AND
• Have a 3.0+ high school GPA, AND
• Demonstrate mathematics preparedness by:
  • Obtaining a mathematics ACT score of 22+ (or math SAT score of 540+), OR
  • Achieving a ‘B’ or better in ‘college algebra’ or a more advanced mathematics course, OR
  • Achieving a ‘C’ or better in a high school calculus course; OR
  • Earning credit via IB or AP credit for the above-mentioned courses in accordance with KU placement credit requirements; OR
  • Achieving at minimum a qualifying score for MATH 104 on the ALEKS mathematics placement exam.

Transfer Student Admission Standards to the School of Engineering

Applications from all transfer students, whether from other institutions or from other academic schools at the University of Kansas, are evaluated on a case-by-case basis. Transfer students must:

• Be admissible to KU, AND
• Earn a cumulative college transferable grade-point average of 2.5+, AND
• Earn a grade of "C" or better in MATH 125 (Calculus I, or its direct equivalent), AND
• Earn grades of "C" or better in math, science, and engineering courses applicable to the engineering degree.

Current Student Admission Standards to the School of Engineering

Students who are currently enrolled at KU, need to meet the following:

• Earn a 2.5+ KU GPA, AND
• Earn a grade of "C" or better in MATH 125 or its direct equivalent, AND
• Earn a grade of "C" or better in all math, science, and engineering courses.

Bachelor of Science in Cybersecurity Engineering Degree Requirements

Course List Code | Title | Hours
---|---|---
Core 34 General Education|
Select courses to meet Core 34 General Education requirements.| 27
Basic Science|
EPHX 210| General Physics I for Engineers| 3
or PHSX 211| General Physics I
or PHSX 213| General Physics I Honors
Natural Science Elective|
Any course fulfilling Core 34 NPS totaling 4 credit hours. May be fulfilled with 3 credit hours of NLEC and 1 credit hour of NLAB.| 4
Mathematics|
MATH 125| Calculus I (Core 34: Math and Statistics (SGE)) 030| 4
or MATH 145| Calculus I, Honors
or MATH 115 & MATH 116| Calculus I and Calculus II
MATH 126| Calculus II| 4
or MATH 146| Calculus II, Honors
MATH 127| Calculus III| 4
or MATH 147| Calculus III, Honors
MATH 290| Elementary Linear Algebra| 2
or MATH 291| Elementary Linear Algebra, Honors
EECS 210| Discrete Structures| 4
EECS 461| Probability and Statistics| 3
Required Computing Courses|
EECS 101| New Student Seminar| 1
EECS 140| Introduction to Digital Logic Design| 4
or EECS 141| Introduction to Digital Logic: Honors
EECS 168| Programming I| 4
or EECS 169| Programming I: Honors
EECS 268| Programming II| 4
EECS 330| Data Structures and Algorithms | 4
EECS 348| Software Engineering I| 4
EECS 388| Embedded Systems| 4
EECS 581| Software Engineering II| 3
EECS 678| Introduction to Operating Systems| 4
Required Cybersecurity Engineering Courses|
EECS 465| Cyber Defense | 3
EECS 563| Introduction to Communication Networks| 3
EECS 565| Introduction to Information and Computer Security| 3
EECS 569| Computer Forensics| 3
EECS 677| Advanced Software Security Evaluation| 3
EECS 695| Software Reverse Engineering| 3
Capstone Course|
EECS 592| Cybersecurity Design| 3
Cybersecurity Electives|
CyE majors must choose 3 classes from the following list to fulfill CyE elective requirements. Under unusual circumstances, other courses can be considered, but only with an accompanying petition.| 9
EECS 665| Compiler Construction|
EECS 666| Introduction to Network Security|
EECS 677| Advanced Software Security Evaluation|
EECS 683| Introduction to Hardware Security and Trust|
EECS 685| Introduction to IoT Security (Same as EECS 700: IoT Security)|
EECS 687| Mobile Security (Same as EECS 700: Mobile Security)|
EECS 695| Software Reverse Engineering|
EECS 700| Special Topics: (Biometric Authentication)|
EECS 755| Software Modeling and Analysis|
EECS 765| Introduction to Cryptography and Computer Security|
ENGR 360| Special Topics: (Business for Engineers)|
POLS 687| Introduction to Cyber Intelligence|
EECS Electives|
Choose any 6 credit hours of EECS courses 400 or above, except EECS 498 and EECS 692. Only one of EECS 645 or EECS 643 may be used.| 6
Additional Math/Science Elective|
CYEN majors are required to complete an additional math or science course (3 credit hours). Select one course from either of the following categories:| 3
Natural Science: Any course fulfilling Core 34 NPS or NLEC with a minimum of 3 credit hours outside of the CyE Basic Science requirement. This must be in addition to Core 34: Natural and Physical Science requirement.|
Math: Any MATH course numbered 200 and above that is not a degree requirement, except MATH 209, MATH 365, MATH 510, or MATH 526.|
Total Hours| 126

Course Prerequisites and Corequisites

Students must pass (with an appropriate grade) all prerequisite courses for a given course before taking the subsequent course. If Course A is a Corequisite for Course B, Course A must be taken in the same semester as Course B be completed prior to taking Course B.

Upper Level Eligibility

In addition to prerequisites and co-requisites, EECS undergraduates are required to earn Upper Level Course Eligibility (ULE) by attaining grades of C or better (C- does not qualify) in each of the following 13 courses:

• Core 34: English (Both)
• EPHX 210
• MATH 125, 126, 127, 290
• EECS 101, 140, 168, 210, 268, 348

If students earn less than a C in any of the above listed courses, they must repeat the course at the next available opportunity and must **** take a course for which that course is a prerequisite. It is the students' responsibility to contact their advisors before beginning the new semester regarding any required repetitions and the associated enrollment adjustments (drops and adds).

To enroll in upper‑level EECS course beyond the ULE list , students must have fulfilled the Upper Level Eligibility Requirements detailed above. Exceptions: EECS 312, EECS 330, EECS 361, and EECS 388 may be taken in the same semester as students are completing their upper level eligibility. Students may also petition for a Partial Waiver of Upper Level Eligibility Requirements by completing the appropriate petition.

Double Major

If students wish to double-major (earn two degrees), they must fulfill all the requirements for the degrees in question. They must also consult the Engineering Dean’s office and the department and/or school of the second major to find out if there are any additional requirements. If they wish to obtain two degrees offered by the EECS department, the following rule applies: a course that is required for one EECS degree program may not be used to satisfy a Senior Elective or General Elective requirement of another EECS degree program.

Degree Plan

Freshman

Fall| Hours| Spring| Hours
EECS 101| 1| EECS 140| 4
EECS 168| 4| MATH 126| 4
MATH 125 (Core 34: Math and Statistics (SGE))030| 4| EECS 268| 4
Core 34: English (SGE)010| 3| Core 34: English (SGE)010| 3
Core 34: Communications (SGE)020| 3| Natural and Physical Science Elective| 3
| 15| | 18
Sophomore
Fall| Hours| Spring| Hours
MATH 127| 4| MATH 290| 2
EECS 210| 4| EECS 330| 4
EPHX 210 (Core 34: Natural and Physical Sciences (SGE))040| 3| EECS 388| 4
PHSX 216 (Core 34: Natural and Physical Sciences (SGE))040| 1| Core 34: US Culture (SGE)070| 3
EECS 348| 4| Core 34: Social and Behavioral Science (SGE)050| 3
| 16| | 16
Junior
Fall| Hours| Spring| Hours
EECS 461| 3| EECS 563| 3
EECS 465| 3| EECS 565| 3
EECS 678| 4| EECS Elective 1| 3
PHIL 375 (Core 34: Arts and Humanities (SGE))060| 3| Add. Math/Science Elective2| 3
Core 34: Arts and Humanities (SGE)060| 3| Core 34: Global Culture (SGE)070| 3
| 16| | 15
Senior
Fall| Hours| Spring| Hours
EECS 581| 3| EECS 592 (Capstone)| 3
EECS 569| 3| EECS 695| 3
EECS 677| 3| CyE Elective 2| 3
EECS Elective 2| 3| CyE Elective 3| 3
CyE Elective 1| 3| Core 34: Social and Behavior Science (SGE)050| 3
| 15| | 15
Total Hours 126

Learning Outcomes

At the completion of this program, students will be able to:

• Identify, formulate, and solve complex engineering problems by applying principles of engineering, science, and mathematics.
• 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.
• Communicate effectively with a range of audiences.
• 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.
• Function effectively on a team whose members together provide leadership, create a collaborative and inclusive environment, establish goals, plan tasks, and meet objectives.
• Develop and conduct appropriate experimentation, analyze and interpret data, and use engineering judgment to draw conclusions.
• Acquire and apply new knowledge as needed, using appropriate strategies.

Honors

An undergraduate student may graduate with departmental honors in electrical engineering, computer engineering, computer science, or interdisciplinary computing by graduating with a minimum grade-point average requirement while maintaining full-time status. In addition, students must enroll in EECS 498 Honors Research for their last 2 semesters and must complete an independent research project paper and oral presentation to a panel of 3 judges. See the EECS Undergraduate Handbook for full details.