Course Offerings | Computer Science

Division of Science and Mathematics

Christine Shannon (chair); Michael Bradshaw, Alex McAllister, Art Moore, Joseph Oldham; student: Luke Hatcher



Computer science is a rapidly evolving discipline, born in the mid-twentieth century with roots in mathematics, logic, and engineering. Computing has become a necessary tool in nearly every area of human endeavor: critical to our workplace production, to our communication, and a means to play and to express ourselves artistically. Regardless of what computer science seems to be at the beginning of a four year course of study, both the discipline itself and the student's understanding of it will have changed substantially by the end. However, certain themes endure.

Computer science deals with problems: identifying those that are solvable in a computing environment, developing and applying appropriate algorithms for their solution, and dealing computationally with their complexity. Frequently these problems appear in the midst of incomplete, contradictory, and changing information. Indeed, much of computer science is devoted to creating software solutions to problems. Software development and computing in general rely on theory, on formalism, on abstraction, and on principles from engineering, but require more.

Computer scientists must be able to apply their own knowledge and understanding of how to solve problems computationally to situations involving both diverse people and subject matters. Software is used in human systems and must be built for humans, and so computer scientists must learn how to accomplish this. Powerful computational tools are as subject to abuse and social side effects as are physical tools and computer scientists must understand the broader role and implications of their work.

One of the benefits of gaining this technical competence in a liberal arts setting is the opportunity to develop sound communication skills. And while a strong classroom foundation in the fundamentals is essential, the rewards of internships, summer jobs, and independent projects can also be profound. Upon graduation most majors have successfully entered professional positions where they have been very successful, while others have first pursued graduate study in computing or other disciplines.


Requirements for the Major

MAT 170 or both MAT 140 and 141, MAT 190;
CSC 117, 221, 223, 300, 332, 334;
One foundations course selected from CSC 341, 342, 343;
One major project course selected from CSC 336, 410;
One applications course selected from CSC 339, 347.

Prospective majors must complete CSC 117 no later than the fall term of their sophomore year and should complete MAT 190 by the end of the sophomore year. The CSC 117 class is open to non-programmers as well as to those with some programming experience.

Students are encouraged to supplement this preparation with additional courses in mathematics (especially MAT 130 and MAT 24
0), physics, and logic. In particular, students who plan on graduate study in computer science need to select additional courses in mathematics and science.

Requirements for the Minor

CSC 117, 221, 223;
MAT 190 and one of MAT 140, MAT 170;
One of CSC 300, 332, 334;
One additional course selected from courses numbered 300 or higher.


Computer Science Courses

CSC 117 Introduction to Computer Science (four credit hours)
An examination of the ideas behind the operation of computers and the Internet, with an emphasis on programming. Students learn to use selection, repetition, function definition, structured types, and standard libraries to build useful programs. Topics include databases, an introduction to robotics, the basic operation of the Internet, and related social, legal, and ethical issues. Prerequisite: basic skills in mathematics or permission of the instructor.

CSC 221 Computer Organization
A study of basic computer architecture. Topics include numerical representation and arithmetic, the levels of computer organization (digital logic, microprogramming, machine language, and macro language), internal machine processes (discrete instruction execution, memory, registers, addressing, input/output considerations, and synchronization), instruction sets (addressing, data flow, flow of control, interrupts, and multitasking), and the assembly process (translation, linking, loading, and the use of macros). Assembly language programming is part of the course. Prerequisite: CSC 117 or permission of the instructor.

CSC 223 Intermediate Programming and Data Structures (four credit hours)
Continued instruction in the use of object oriented techniques. Study of the standard data structures including lists, stacks, queues, trees, and hash tables. Introduction to space and time complexity. Prerequisite: CSC 117. Laboratory work is required.

CSC 300 Software Development
A study of the pr
actices and techniques used in the development of modern software solutions. Topics are chosen from standard APIs, event models, graphical user interfaces, human-computer interaction, multi-threading, database connectivity, library development, debigging methods, exception handling, design patterns and advanced topics in object oriented design. Most development requires the same programming language as CSC 223, with new development tools introduced as appropriate. Students should expect to develop at least one portfolio quality piece of software. Prerequsite: CSC 223.

CSC 332 Design and Analysis of Algorithms
An introduction to the theoretical and empirical evaluation of algorithms and to some fundamental concepts in algorithm design and implementation. Topics include worst-case vs. average-case performance, complexity classes, recurrence relations, problem-solving strategies, heuristics, and NP-complete problems. Prerequisite: CSC 223 and MAT 190.

CSC 334 Theoretical Foundations of Computer Science
An introduction to the study of abstract models of computation and languages, and to the use of formal methods in computer science. Topics include Turing machines, Church's thesis, decision problems and undecidable problems, finite state automata and regular expressions, context free grammars and pushdown automata, symbolic logic, axiomatic semantics, and formal correctness proofs for small programs. Prerequisite: MAT 190 and CSC 117 or permission of the instructor.

CSC 336 Software Engineering
An introduction to methodologies used by teams to design and construct software. Prerequisite: CSC 223.

CSC 339 Topics in Artificial Intelligence
An introduction to some of the important ideas in artificial intelligence from the point of view of an intelligent agent. Topics include knowledge representation, pattern matching, automated reasoning, and searching techniques. Applications are selected from game playing, problem solving, and autonomous robots. Prerequisite: CSC 223 and MAT 190 or permission of the instructor.

CSC 341 Principles of Programming Languages
Various languages are used to study principles such as methods of representing data types, sequence control, data control, type checking, and run-time storage management. Includes an introduction to language translation and distributed and parallel programming constructs. Emphasizes differences in programming paradigms. Prerequisite: CSC 223.

CSC 342 Theory and Construction of Compilers
A study of ideas and techniques involved in the writing of a compiler for a high-level language, including grammars, finite state machines, top-down and bottom-up parsing, and symbol tables. Includes the writing of an actual compiler. Prerequisite: CSC 221 and CSC 223.

CSC 343 Operating Systems
An introduction to the role of an operating system in the management of memory, the processor, devices, and files. Topics covered include scheduling, memory management, deadlock, file structures, and concurrency. Examples are taken from actual systems. Prerequisite: CSC 223 and CSC 221 or permission of the instructor.

CSC 347 Computer Graphics
Essential topics of computer graphics necessary in the design of data structures for practical implementation in the development of software as well as the potential and limitations imposed by existing hardware. Raster-scan and vector-scan techniques are examined. Topics also include clipping, window management, color, and hidden line and hidden surface removal.. Some topics from linear algebra are included to support the development of primitives, two-dimensional figures, and three-dimensional transformations. Prerequisite: MAT 141 or 170 and CSC 223 or permission of the instructor.

CSC 350 Event Driven Programming
Students further their understanding of and skills in problem solving, and software design and development by focusing on problems in the graphical user interface (GUI). Event models, standard APIs, concepts of human computer interaction, and new development tools are introduced. Most development requires the same programming language as CSC 223, although other languages may be introduced for specific assignments or to illustrate points. Prerequisite: CSC 223, sophomore standing.

CSC 410 Database Systems
A study of the fundamental concepts underlying the design, implementation, and application of database systems. Topics include the historical development of database management systems, the common elements of modern database systems, entity relationships, the relational model of system implementation, data constraints, and the Structured Query Language. Programming activities are incorporated to expose students to typical database applications. Prerequisite: CSC 223 and MAT 190.

Special Topics Courses Offered 200
4-2005:

CSC 250 Intro to Networking Fundamentals
A study of the fundamental concepts of net-centric computing, i.e., computer communication, network concepts and protocols, management of networked applications, client-server computing, network security, and distributed systems. Programming activities are incorporated to expose students to typical real world networking environments. Prerequisite: CSC 221.


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