Bachelor of Science in Electrical and Computer Engineering

Prerequisite: MTH 12A and MTH 12B, or Accuplacer test placement evaluation

Examines higher degree polynomials, rational, exponential and logarithmic functions, trigonometry and matrix algebra needed for more specialized study in mathematics, computer science, engineering and other related fields. Computer and/or graphing calculator use is highly recommended.

Prerequisite: 2 years of high school algebra and MTH 204, or MTH 215, or MTH 216A and MTH 216B

Non-calculus based general physics course for earth and life science majors. Study of force, laws of motion, heat, fluid mechanics, electricity, magnetism, light (optics) and modern physics.

Prerequisite: PHS 104, or PHS 171 for Science Majors.

A non-calculus based general physics lab course for earth and life science majors. Laboratory experiments and exercises will include data analysis and evaluation of measurements. Topics include, but are not limited to, the following: force, gravity, laws of motion, fluid mechanics, electricity, and light (optics). For the *Online Lab Courses ONLY*, students are expected to order their lab kits at least two weeks prior to the start of term.

Prerequisite: MTH 215

(Cross-listed and equivalent to MTH220) Focus on differential and integral calculus with applications. Topics include limits and continuity, derivatives, standard rules of differentiation including chain rule, exponential and logarithmic forms, curve sketching, definition of anti-derivatives; integration rules including substitution and by parts, coverage of Fundamental Theorem of Calculus and a brief exposure to numeric integration. Students may not receive credit for both CSC 208 and MTH 220.

Prerequisite: CSC 208

Continuation of Calculus I with emphasis on understanding of concepts and developing problem solving techniques and strategies. Topics include integration of trigonometric functions, functions of several variables, convergence of series and sequences. Applications in the areas of series approximation, continuous probability distributions, random variables, and modeling are discussed and examined.

Prerequisite: CSC 208, or MTH 220; EGR 220

Introduction to the theory and applications of probability and statistics. Topics include data and numerical summary measures, fundamental concepts of probability, conditional probability, random variables, common distributions, quality and reliability and statistical inference (estimation, hypothesis testing, and regression). The emphasis is on developing problem solving skills and application to business, social sciences and engineering.

Prerequisite: MTH 215

This course introduces modern programming design techniques using C++. A study of fundamental control structures in C++ as well as syntax and semantics of the constructs in the language. The coverage includes data types, looping and decision statements, functions, and arrays. The course examines problem analysis, decomposition and modern programming paradigms and methodologies with introduction to object-oriented programming.

Prerequisite: CSC 242

The course introduces the fundamentals of Object-Oriented Programming in C++ including class definition and object instantiation, inheritance and polymorphism. Detailed coverage of pointers, operator overloading, I/O and file streams, templates, and exception handling. Exposure to Data Structures and basic algorithms for sorting and searching.

Prerequisite: PHS 104 and MTH 220, or CSC 208 and MTH 221, or CSC 209

Calculus-based physics course. Intended for Science majors and Engineering students. Study of one, two and three-dimensional kinematics including integral calculus, graphical analysis, numerical integration and vector kinematic, dynamics, uniform and non-uniform circular motion, gravitation, and Newton’s synthesis, work and energy with vector algebra principles, linear momentum, rotational motion, statics including elasticity and fracture.

Prerequisite: PHS 104 PHS 231, MTH 220 or CSC 208, and MTH 221 or CSC 209

Calculus-based physics course. Intended for Science majors and Engineering students. Study of different types of oscillations and wave motion, electrostatics with electric field calculations for continuous charge distribution, Gauss’s law, electric potential due to any charge distribution, electric energy storage with applications, electric currents and resistance, magnetism and magnetic field, electromagnetic induction and transmission of power, DC and AC circuits, Maxwell’s equations and electromagnetic waves

Prerequisite: CSC 252, or CSC 272

Covers the key concepts and methodologies required for object-oriented design, evaluation and development with focus on practical techniques such as use-case, and scenario based analysis. Coverage of Unified Modeling Language (UML) and domain analysis design. Exposure to software development process models and software management and security.

Analysis of the values, ethics and ideologies in computing and their applications to current issues in computer industry within the contemporary sociocultural setting. Focuses on ethical decision-making in computing matters. Students develop an ethical outlook on a wide variety of workplace issues in computing through case study, debate and readings.

Prerequisite: CSC 252, or CSC 272

The course includes the study of vectors in the plane and space, systems of linear equations, matrices, determinants, vectors, vector spaces, linear transformations, inner products, eigenvalues and eigenvectors. The course will approach the study of linear algebra through computer-based exercises. Technology will be an integral part of this course. Students will also develop experience applying abstract concepts to concrete problems drawn from engineering and computer science.

Prerequisite: CSC 209 and CSC 310;

This course introduces the mathematical fundamentals and numerical methods for engineering practice. Emphasis is placed on mathematical modeling using differential equations and associated numerical methods for solutions. The topics include complex numbers, differential equations, systems of linear differential equations, Laplace transform and their applications in engineering. MATLAB is introduced as a tool for solving mathematical problems that require numerical solutions.

Prerequisite: CSC 252, or CSC 272

(Cross-listed and equivalent to MTH 325) A theoretical foundation for computer science. Introduction to topics such as sets, propositional logic, Boolean algebra, counting techniques, recursive equations and solution techniques, graph algorithms with application to trees. Introduction to mathematical proofs. Students may not receive credit for both CSC 331 and MTH 325.

Prerequisite: CEE 300; Corequisite: CEE 310L

An overview of basic circuit design and analysis. Introductory topics include: Ohm’s law, Kirchhoff’s Laws, the mesh-current method, and Thévenin and Norton Equivalent circuits. Students will apply these topics to RL, RC, and RLC circuit analysis. Advanced topics include the understanding and application of operational amplifiers.

Corequisite: CEE 310

Centers on experiments covering the theoretical material in CEE310. Students will design, implement and analyze basic circuits. Experiments include: Ohm’s law; Kirchhoff’s laws; series and parallel resistors; voltage and current dividers; delta-wye configurations; mesh-current and node-voltage analysis; superposition and Thevenin equivalents; inverting and non-inverting amplifier circuits; series RC and RL circuits.

Prerequisite: CSC 331; Corequisite: CSC 340L

Foundation in design and analysis of the operation of digital gates. Design and implementation of combinational and sequential logic circuits. Concepts of Boolean algebra, Karnaugh maps, flip-flops, registers, and counters along with various logic families and comparison of their behavior and characteristics.

Prerequisite: CSC 331; Corequisite: CSC 340

A study of basic digital logic circuit design and implementation. Circuit schematic development and computer modeling and simulation of digital systems. Experiments explore designs with combinational and sequential logic. Students work through design activities, which include testing, troubleshooting and documentation.

Prerequisite: CSC 340 and CSC 340L

An examination of advanced hardware design, analysis and low-level programming with emphasis on the structure of the machine. In addition, the machine cycles and instructions, pipelining, addressing modes, memory hierarchy, cache levels and virtual memory and architecture concepts are covered. A discussion of I/O architectures and data transmission modes, disk technologies, tapes and RAID concepts. Comparison of alternative architectures like RISC and parallel processing are presented.

Prerequisite: CEE 310; Corequisite: CEE 420L

Describes the fundamentals of semiconductor devices and microelectronic circuits. Students will explore the terminal characteristics of p-n junction and Zener diodes, diode circuits, and transistors and transistor circuits. Specifically, discussion includes principles of MOSFET and BJT operations, biasing technology, and their application in transistor circuit analysis.

Corequisite: CEE 420

This lab course is designed to supplement the material of CEE420, to assist students in obtaining a better understanding of the operation of microelectronic circuits. Laboratory activities include the design, construction, computer simulation, and analysis of transistor circuits, multi-stage amplifiers, operational amplifiers, current drivers and other semiconductor circuits.

Prerequisite: CSC 331

An in-depth study of fundamental concepts in the design and implementation of computer communication networks. Coverage of core problems such as framing, error recovery, multiple-access, flow control, congestion control, routing and end-to-end reliability. Topics include basics of switched communication networks, packet switch architecture, TCP/IP networking, routing algorithms, Quality-of-Service networks. Network tools are applied in quantitative modeling and analysis of networks.

Prerequisite: CEE 310; Corequisite: CEE 324L

Introduction to fundamental concepts, analysis and applications of continuous-time and discrete-time signals and linear systems. Course contents include time-domain and frequency-domain characterization of signals and systems, Fourier Series and Fourier Transform, basic sampling and filtering concepts, the Laplace Transform, and the Z Transform etc. The course will be supplemented with MATLAB based exercises.

Corequisite: CEE 324

This lab course provides a collection of hands-on experiments for supporting the lectures of CEE 324. The experiments are designed to enable students to understand the theory behind signals and systems as well as validate the theory with real-world examples. The lab will cover time-domain and frequency-domain characterization of signals and systems, transforms, filtering and sampling.

Prerequisite: CEE 324

Describes all the necessary tools and techniques required to understand and design digital signal processing systems. Topics include: transformations of discrete time signals, the fast Fourier transform, and the z-transform. Advanced topics include: A/D and D/A converters and digital signal filtering.

Prerequisite: CSC 208 and CSC 252, or CSC 262; Corequisite: CEE 340L

Exploration of design and interfacing of microcontroller based embedded systems. It covers various aspects of 8051 C and assembly language programming and interfacing. The course examines the architecture of the 8051 microcontroller along with a study of the I/O ports, addressing modes, interrupt routines, timings and the serial data communication in 8051.

Corequisite: CEE 340

This lab course provides a collection of experiments for supporting the lectures in CEE 340. The labs are designed to familiarize students with various aspects of hardware and software for microcontroller applications such as interfacing with various devices, programming I/O ports and interrupts and working with sensors.

Prerequisite: CEE 420

VLSI design introduces students to fabrication and layout techniques necessary to design large scale systems. Specific topics include: CMOS logic, MOSFET theory, layout design rules including all the factors required for an effective circuit design. Advanced topics include: capacitance requirements, clocking, and power consumption, circuit simulation and performance estimation.

Prerequisite: Complete all core courses except CEE499 capstone courses OR permission by the program lead.

Students apply the knowledge and skills that they gained from Electrical and Computer Engineering courses to solve a real-world engineering problem. Students start work on their project after it is approved by the faculty teaching the course. During this course students complete different phases of project. Students deal with a set of realistic constraints during the design and implementation of the project such as economic, social, political, ethical, and social impacts. Grading is S/U only. Eligible for In Progress (IP) grading.

Prerequisite: CEE 498

A second course of a three-course sequence in which students continue to develop their products/systems, refine their specifications, then assemble and debug their products/systems. At the end of the course each group of students demonstrates a product prototype. The students grading is H/S/U only. Course is eligible for In Progress (IP) grade.

Prerequisite: CEE 499A

A third course of a three-course sequence in which students finalize their designs and product specifications, and complete the design project. With the mentoring of the faculty, each group of the students completes the written report, presents and demos their capstone design project. Grading is H/S/U only. Course is eligible for In Progress (IP) grade.