ÌìÃÀ´«Ã½ÖÆƬ³§

Skip to main content

Data Science, B.S. to Software Engineering, M.S. Accelerated Program

ÌìÃÀ´«Ã½ÖÆƬ³§'s data science B.S. to software engineering M.S. accelerated program allows a SLU student to complete both the Bachelor of Science in Data Science and the Master of Science in Artificial Intelligence in a shorter time period than if both degrees were pursued independently.

For additional information, see the catalog entries for the following SLU programs:

Data Science, B.S.

Software Engineering, M.S.

Students who want to apply to this accelerated program should have completed all 2000-level coursework required of the data science bachelor's program and have completed at least 75 credits at the time of application.

At the time of application, students must have a cumulative GPA of at least 3.00 and a GPA of at least 3.00 in their computer science coursework. Contact the graduate coordinator for more details.

Non-Course Requirements

All Science and Engineering B.A. and B.S. students must complete an exit interview/survey near the end of their bachelor's program.Ìý

Continuation Standards

Students must maintain a cumulative GPA of at least 3.00 and a GPA of at least 3.00 in their computer science coursework.Ìý

Students who drop belowÌýthat GPA while in the accelerated program will be placed on a one-semester probationary period before beingÌýdismissed from the accelerated program.Ìý

Only grades of "B" or better in the graduate courses taken while an undergraduate can be applied to the master's degree.

Roadmaps are recommended semester-by-semester plans of study for programs and assume full-time enrollmentÌýunless otherwise noted. Ìý

Courses and milestones designated as critical (marked with !) must be completed in the semester listed to ensure a timely graduation. Transfer credit may change the roadmap.

This roadmap should not be used in the place of regular academic advising appointments. All students are encouraged to meet with their advisor/mentor each semester. Requirements, course availability and sequencing are subject to change.

Plan of Study Grid
Year One
FallCredits
Critical course: ÌýCSCI 10xxIntroduction to Computer Science † 3
MATHÌý1660 Discrete Mathematics 3
University Core and/or General Electives 9
ÌýCredits15
Spring
CSCIÌý1300 Introduction to Object-Oriented Programming 4
MATHÌý1510 Calculus I 4
University Core and/or General Electives 6
ÌýCredits14
Year Two
Fall
CSCIÌý2100 Data Structures 4
MATHÌý1520 Calculus II 4
University Core and/or General Electives 9
ÌýCredits17
Spring
CSCIÌý2300 Object-Oriented Software Design 3
CSCIÌý2500 Computer Organization and Systems 3
University Core and/or General Electives 9
ÌýCredits15
Year Three
Fall
CSCIÌý2510 Principles of Computing Systems 3
Additional Mathematics (2000+) 3
University Core and/or General Electives 9
ÌýCredits15
Spring
Critical course: ÌýApplication Course 3
Critical course: ÌýTheory Course 3
PHILÌý3050X Computer Ethics 3
University Core and/or General Electives 6
ÌýCredits15
Year Four
Fall
CSCIÌý4961 Capstone Project I 2
CSCIÌý5090 Computer Science Colloquium 1
CSCI 51##CSCI Elective 3
University Core and/or General Electives 9
ÌýCredits15
Spring
CSCIÌý4962 Capstone Project II 2
CSCI 51xxCSCI Elective 3
University Core and/or General Electives 9
ÌýCredits14
Year Five
Fall
CSCIÌý5030 Principles of Software Development 3
CSCIÌý5050 Computing and Society 3
CSCIÌý5090 Computer Science Colloquium 1
Theory ElectiveTheory courses numbered CSCI5100-5199 3
Software Engineering ElectiveSoftware Engineering courses numbered CSCI5300-5399 3
ÌýCredits13
Spring
CSCIÌý5090 Computer Science Colloquium 1
CSCI Systems ElectiveSystems courses numbered CSCI5500-5599 3
Graduate Elective 3
Graduate Elective 3
Graduate Elective 3
ÌýCredits13
ÌýTotal Credits146

Introduction to Computer Science

CSCIÌý1010
Introduction to Computer Science: Principles
CSCIÌý1020
Introduction to Computer Science: Bioinformatics
CSCIÌý1025
Introduction to Computer Science: Cybersecurity
CSCIÌý1030
Introduction to Computer Science: Game Design
CSCIÌý1040
Introduction to Computer Science: Mobile Computing
CSCIÌý1050
Introduction to Computer Science: Multimedia
CSCIÌý1060
Introduction to Computer Science: Scientific Programming
CSCIÌý1070
Introduction to Computer Science: Taming Big Data
CSCIÌý1080
Introduction to Computer Science: World Wide Web
CSCIÌý1090
Introduction to Computer Science: Special Topics
With permission, a computing-intensive course from another discipline may be substituted. Examples of such courses include:
BMEÌý2000
Biomedical Engineering Computing
CVNGÌý1500
Civil Engineering Computing
STATÌý3850
Foundation of Statistics

Applied SystemsÌý

CSCIÌý4500
Advanced Operating Systems
CSCIÌý4530
Computer Security
CSCIÌý4550
Computer Networks
CSCIÌý4610
Concurrent and Parallel Programming
CSCIÌý4620
Distributed Computing

Theory CoursesÌý

CSCIÌý3100
Algorithms
CSCIÌý3200
Programming Languages

Graduate Electives

The general requirements must include a course from at least two of the following categories:

  • CSCI 5200-5299 (Language/Compilers courses)
  • CSCI 5600-5699 (Large Scale Systems courses)
  • CSCI 5700-5799 (Knowledge Systems)
  • CSCI 5800-5899 or BCB 5200/5250 (Advanced Applications)

Program Notes

CSCIÌý5050 Computing and Society (3 cr) requirement will be waived for students who took Computer Ethics as an
undergraduate; these hours would become an additional graduate elective.

Thesis Option

A master's thesis is optional. Students completing a thesis should take six credits of CSCIÌý5990 Thesis Research (0-6 cr) as part of the elective requirements.

Internship with Industry

Students may apply at most three credits of CSCIÌý5910 Internship with Industry (1-3 cr)Ìýtoward the degree requirements.

Closely Related Disciplines

With approval, students may include up to six credits of elective graduate coursework in closely related disciplines (e.g. mathematics and statistics, bioinformatics and computational biology, electrical and computer engineering).