400
Prerequisites: MATH 213 or MATH 112 or PSY 211 or ECMG 212, and Level III Mathematics Placement, and CS 200 or CS 219; or Permission of Instructor
Introduces basic principles and methods for data analysis and knowledge discovery to computer science students. Topics include preprocessing, association, classification, and anomaly detection. Students develop basic skills for modeling and performance evaluation.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 522
Offered
Fall Semester
Prerequisites: MATH 213 or MATH 112 or PSY 211 or ECMG 212, and Level III Mathematics Placement, and CS 200 or CS 219; or Permission of Instructor
This course provides an overview of Data Science, covering a broad selection of challenges and methodologies for working with big data. Topics to be covered include data collection, integration, management, modeling, analysis, visualization, prediction, and informed decision making. Students work on hands-on projects and case studies using real data sets from a variety of domains including science, business, engineering, social sciences, and life sciences.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 527
Offered
Spring Semester
Prerequisite: Junior standing and CS 219 or permission of the instructor. History, fundamental principles, and future directions of A.I. Topics include state-space searching, knowledge representation, logic and deduction, natural language processing, neural networks, learning, vision, robotics, and cognitive science. Topics will be treated at a level of depth and detail appropriate for a first course in AI.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 528
Offered
Fall Semester
Prerequisites: MATH 213 or MATH 112 or PSY 211 or ECMG 212, and Level III Mathematics Placement, and CS 200 or CS 219; or Permission of Instructor
Introduction to the field of modeling learning with computers. Topics included are explorations of inductive learning, learning decision trees, ensemble learning, computational learning theory, and statistical learning methods.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 543
Offered
Spring Semester (Even Years)
Prerequisite: CS 226 or permission of the instructor. Introduction to combinational and sequential circuit design. Topics include Boolean algebra and simplification techniques, arithmetic circuits, decoders, flip-flops, counters, registers, memory systems, analog-to-digital conversion and VHDL programming.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 550
Offered
Spring Semester (Even Years)
Prerequisite: CS 219 or Permission of Instructor. Digital Signal Processing (DSP) is concerned with the representation, transformation and manipulation of signals using computer technology. This course will introduce the basic concepts and techniques for processing discrete-time signals.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level CS 551
Offered
Spring Semester (Odd Years)
Prerequisites: CS 226. Foundations of networking technology and understanding of challenges faced in design and architecture of Data networks. Topics include networking principles, Transmission, Control Protocol, Internet Protocol, data encoding/decoding techniques and wireless communication.
Credits
3.0
Offered
Spring Semester
Prerequisites: CS 226 and CS 219 or permission of the instructor. An in-depth study of architectural concepts and principles including performance-based design tradeoffs. Topics to be covered include: instruction set design, arithmetic algorithms, hardwired and microprogrammed control, memory hierarchy design, input/output, pipelines, RISC, CISC, vector processors, parallel processors and superscalar machines.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 561
Offered
Fall Semester (Even Years)
Prerequisites: CS 226 and CS 219 or permission of the instructor. Fundamental principles of operating systems. Topics include: process management; concurrency; deadlock; CPU scheduling; memory management; disk management; files systems; security; and distributed, real-time and multiprocessor operating systems.
Credits
3.0
Offered
Spring Semester
Prerequisites: Junior standing and CS 219 or permission of the instructor. A comprehensive introduction to both the principles and the practice of parallel computing. Topics to be covered include: programming and architectural models, parallel algorithms and parallelizing compilers.
Credits
3.0
Cross Listed Courses
Double-numbered course; offered with graduate-level
CS 566
Offered
As Needed
Prerequisites: CS 226 and CS 219. A survey of the major programming paradigms and their related languages, including procedural, functional, logic and object-oriented programming. Topics include: binding, exception handling, data sharing, scope, parameter passing, type checking, runtime storage management, lexical analysis, syntactic analysis, parsing, code generation and optimization.
Credits
3.0
Offered
Fall Semester
Prerequisites: CS 329 and senior standing, or permission of the instructor. Course focuses on cultivating proficiency in technical communication, using appropriate research methods, enhancing the ability to identify computational problems, properly state research questions, critically assess scientific literature, present data and results, work in teams and improve technical writing and time management skills.
Credits
3.0
Offered
Fall Semester
Prerequisites: CS 324, CS 474 and senior standing, or permission of the instructor Students majoring in computer science complete a capstone project, serving as a culmination of their studies. The project entails the development of a significant piece of software or carrying out a research study by a student team, supervised by a designated faculty member within the department and evaluated by a faculty committee.
Credits
3.0
Offered
Spring Semester
Credits
3.0
Offered
As Needed
Prerequisite: By invitation of the department.
The departmental honors paper is a two-semester senior-year program designed for students who wish to pursue intensive research or special projects in close coordination with faculty advisers. Departmental honors students are known as the Christine P. Tischer Scholars and receive 6 credits for this work.
Credits
3.0
Offered
Both Semesters and/or Summer
Prerequisite: By invitation of the department.
The departmental honors paper is a two-semester senior-year program designed for students who wish to pursue intensive research or special projects in close coordination with faculty advisers. Departmental honors students are known as the Christine P. Tischer Scholars and receive 6 credits for this work.
Credits
3.0
Offered
Both Semesters and/or Summer