[4 credit(s)] Prerequisite or corequisite: ESC 250 and ESC 120. Basic electrical concepts; network theorems; circuit laws; resistance, capacitance, inductance; response of RC, RL and RLC circuits to initial conditions and constant forcing functions; AC steady-state analysis and AC power; integration of computer applications using PSPICE.
[4 credit(s)] Prerequisites: EEC 310 (C or better), ESC 250. Prerequisite or corequisite: PHY 244. Continuation of EEC 310. Polyphase AC circuits; magnetically-coupled circuits; frequency response and resonance; two-port networks; Laplace transform analysis of circuits; transfer functions, poles and zeros; convolution; Fourier series and Fourier transform analysis; integration of computer applications using PSPICE.
[3 credit(s)] Prerequisites: ESC 250, EEC 310. Prerequisite or corequisite: EEC 311. Rectifier diodes and applications; Zener diodes and applications; biasing BJT and FET amplifiers; small signal analysis of BJT and FET amplifiers; power amplifiers; amplifier frequency response.
[3 credit(s)] Pre- or Co-requisite: EEC 311. Continuous and discrete-time signals and systems. Linear system modeling via differential and difference equations, and convolution. Fourier series, Fourier transform, Laplace transform and Z-transform. Frequency domain analysis of continuous and discrete-time systems. Applications to communications and control systems.
[3 credit(s)] Prerequisites: EEC 311and MTH 283. Ampere’s and Faraday’s laws applied to electromechanical energy conversion devices. Induced torque and induced voltage in both motors and generators. Analysis of the sinusoidal steady-state operation and performance of three-phase motors and generators. Control under different steady-state loading conditions.
[2 credit(s)] Prerequisites: Gen Ed Eng/Comp, PHL 215. This course is designed to enhance the ability of students to communicate effectively on topics within engineering and science. A substantial written report is one of the requirements.
Semesters Offered: Every Fall
General Education Category: Writing Across Curriculum
[3 credit(s)] Prerequisites: EEC 315 or 316, EEC 384. Software design of microcontroller-based embedded systems. Topics covered include microcontroller architecture, assembly programming, real-time interrupts, external interrupts, program size considerations, input/output issues, analog-to-digital conversion, serial port reception/transmission, step motor control, RS232 communication, and mathematics in a fixed point microcontroller.
[3 credit(s)] Prerequisite: EEC 483. Software process, methods, and tools; phases of software development process including requirements analysis, design, coding, and testing; methods and techniques for software engineering, and software project management, metrics, and quality assurance.
[3 credit(s)] Prerequisites: EEC 315 or 316, EEC 383. Modeling of DSP operations using discrete-time signals and systems: difference equations, Z-transforms, Fourier methods; signal sampling (A/D) and reconstruction (D/A); digital filters; sample rate converters and oversampling; DFT, and fast convolution; delta-sigma converters; selected applications. Out-of-class projects done using Matlab.
[3 credit(s)] Prerequisites: EEC 315 or EEC 316, EEC 318. Analysis and design of control systems. Topics covered include: the use of feedback; modeling and the use of mathematical model in understanding behavior of dynamic systems; useful design tools such as PID, root-locus, loop shaping, pole placement; robustness in stability and performance; real world problem solving using control theory.
[2 credit(s)] Pre- or co-requisite: EEC 440. A series of control system experiments including process control using a PID controller, and modeling and digital control of a torsion mechanism.
EEC 443 - Modeling and Simulation of Mechatronic Systems
[3 credit(s)] Pre or co-requisite: EEC 440. Unified approach to modeling of dynamic systems using bond graphs, with emphasis in electromechanical systems; object-oriented and automated modeling concepts; computer simulation.
EEC 447 - Engineering Applications of Programmable Logic Controllers
[3 credit(s)] Prerequisites: EEC 315 or 316. Applications of PLC’s including ladder logic concepts, data manipulation, analog input and output with an emphasis on PID control, network configurations and concepts, and the solution of practical industrial problems through design projects.
[3 credit(s)] Prerequisites: ESC 310, EEC 313, EEC 318. Baseband pulse and digital signaling; bandpass signaling principles and circuitry; AM, FM and digital modulated systems.
[2 credit(s)] Prerequisites: EEC 315 or 316. Pre- or co-requisite: EEC 450. Use of communications-specific test and measurement equipment. Experiments on spectrum analysis, noise, amplitude, frequency and phase modulation, mixers, IF amplifiers, pulse modulation, sampling, baseband modulation, optimum receivers, and amplitude-, frequency-, and phase-shift keying.
[3 credit(s)] Prerequisites: EEC 450. A review of communication concepts and systems, waveform generation, and analog and digital modulation schemes. Use of the hardware elements of an SDR system such as the front-end RF system, analog-to-digital and digital-to-analog conversion, and FPGAs with NI USRP SDR units. Coupling of the hardware elements with the software-defined elements of the radio system through the use of NI LabView environment. Implementation of functioning SDR systems involving modulation, detection, pulse shaping, channel estimation and equalization.
[4 credit(s)] Prerequisites: PHY 244 and EEC 361. Fundamental laws of electromagnetic fields: Gauss’s, Faraday’s, Ampere’s, and Biot-Savart’s. Maxwell’s equations as applicable to finite and infinitesimal regions in three-dimensional space and their engineering implications. Source distribution and boundary value engineering problems and their analytical or numerical solution. Electromagnetic waves propagation. Applications to the design of transmission lines, waveguides, and antennas.
[3 credit(s)] Prerequisites: EEC 314 and EEC 361. Analysis, performance, characterization, and design of power electronics converters using diodes, thyristors, transistors and other controllable semiconductor switches.
[2 credit(s)] Prerequisite: EEC 470. Experiments dealing with single-phase and three-phase transformers; steady-state performance of dc, induction, and synchronous machines; rectifiers, inverters, switch-mode converters and their applications in adjustable motor drives.
[3 credit(s)] Prerequisite: EEC 361.Power system components modeling: transformers, generators, and transmission lines. Power flow analysis. Must be enrolled in the College of Engineering to be eligible for this course.
[3 credit(s)] Prerequisite: EEC 470. Advanced Course in Power Electronics: switching function representation of converter circuits (DC-DC, AC-DC, DC-AC and AC-AC), resonant converters, adjustable torque drives, field oriented induction motor control, residential and industrial applications, utility applications, power supply applications.
[3 credit(s)] Prerequisite: EEC 383, 384; CIS 260, 265. Illustration of basic architecture concepts and control circuit implementation. Topics include basic computer organization, central processor organization, instruction set design, arithmetic logic unit design, datapath and control, and memory organization.
[3 credit(s)] Prerequisite: EEC 383, 384. Network architectures, layered network protocol design issues, reference models, network standards, data link and medium access control protocols, routing algorithms and the Internet Protocol, ARP and DHCP, transport-level protocols including TCP and UDP, application-level protocols such as HTTP and DNS.
[3 credit(s)] Prerequisite: EEC 483. The design of high-performance computer systems, with emphasis on cost-performance tradeoff, performance evaluation, instruction set design, hardwired control-unit design, micro- and nano-programming, pipelining, memory hierarchy, and I/O interfaces.
[3 credit(s)] Prerequisite: EEC 384. Coverage includes CPLD/FPGA devices, digital design methodology, VHDL hardware description language, VHDL description for combinational circuits, sequential circuits, FSM (finite state machine) and FSMD (finite state machine with datapath).
[3 credit(s)] Prerequisite or co-requisite: EEC 487, CIS 340. Partition, design and implementation of hardware and software concurrently; including experiments and projects utilizing VHDL, EDA software tools and FPGA devices to design, synthesize, simulate, implement and test advanced digital systems with soft-core processor and hardware accelerators
[1-3 credit(s)] Prerequisites: approval of instructor and academic advisor. Presentation and discussion of a current topic in electrical and computer engineering. May be repeated for credit for a total of 6 credit hours with a change of topic.
[2 credit(s)] BEE: Pre-/corequisites: EEC 440, EEC 450, or EEC 470; BCE: Pre-/corequisites: EEC 487 or CIS 454 or EEC 484; BSCS: Pre-/corequisite: CIS 345. First of a two-consecutive semester senior design sequence. Students are formed into small design groups (typically 3 students) and assigned an open-ended design project. In addition, students are required to keep an engineering notebook, to write progress reports and a final report, and to make an oral presentation of the design effort.
[3 credit(s)] Prerequisite: EEC 493. Second of a two-consecutive semester senior design sequence. Students are formed into small design groups (typically 3 students) and assigned an open-ended design project. In addition, students are required to keep an engineering notebook, to write progress reports and a final report, and to make an oral presentation of the design effort.
[1-9 credit(s)] Prerequisites: approval of research advisor and academic advisor. Participation in on-going research. Student will be involved in an original investigation. Course may be substituted for a regularly required departmental course in the curriculum.
[1-3 credit(s)] Prerequisites: Junior or Senior standing, and approval of student’s honors advisor. Student will be involved in an engineering research or development project under the personal supervision of a faculty member. The specific responsibilities of the student will be arranged by mutual consent of the student, the student’s honors advisor, and the department’s undergraduate advisor. May be repeated for credit.
[1-9 credit(s)] Prerequisite: Approval of instructor and academic advisor. Independent study on a special topic under the guidance of a faculty member. May be repeated up to 8 credits.
[1-3 credit(s)] Prerequisites: Senior standing, and approval of student’s honors advisor. Student will be involved in an engineering research or development project under the personal supervision of a faculty member. The specific responsibilities of the student will be arranged by mutual consent of the student, the student’s honors advisor, and the department’s undergraduate advisor. The culmination of this course is a written thesis that is approved by a committee of departmental faculty members. The student will also present a public, oral defense of the thesis to the thesis committee. May be repeated for credit up to a total of six credit hours.
[3 credit(s)] Prerequisite: EET 205. Pre or corequisite: ESC 120. Introduction to analog and digital electronics, diodes, FET’s, BJT’s, DC biasing, VI characteristics, single-stage amplifiers, operational amplifiers, active filters, linear and digital ICs, power supplies and voltage regulators.
[3 credit(s)] Introduction to the fundamentals of digital electronics. Number systems and codes, simple and combinational logic circuits, flip-flops, counters, registers, IC logic families, MSI logic circuits, digital systems using HDL, analog-to-digital (A/D) and digital-to-analog (D/A) converters, memory devices, PLDs, and microprocessors.
[3 credit(s)] This course presents the fundamentals of DC circuit analysis. Topics include: voltage, current, sources, Ohm’s law; circuit analysis methods (nodal and mesh anaylses).
[3 credit(s)] Prerequisite: EET 205. This course presents the fundamentals of AC circuit analysis. Topics include: alternating-current voltage, current, sources, Ohm’s law applied to AC circuits; circuit analysis methods (nodal and mesh analyses), steady-state power, and three-phase balanced systems.
[3 credit(s)] Prerequisite: EET 202. Corequisite: EET 316. Architecture and hardware design of microprocessor-based system, including bus structure, interrupts handling, I/O ports, control signal, and peripherals. Combinational and sequential logic circuitry implemented with Field Programmable Gate Array design methodology.
EET 316 - Microprocessor & Digital System Design Laboratory
[1 credit(s)] Corequisite: EET 315. Experiments dealing with architecture and hardware design of microprocessor-based system, including bus structure, interrupts handling, I/O ports, control signal, and peripherals. Combinational and sequential logic circuitry implemented with Field Programmable Gate Array design methodology.
[3 credit(s)] Prerequisites: EET 315 and EET 316. A comprehensive understanding of the instruction set and the related programming algorithmic thought process required to design with and incorporate microprocessor-based systems in dedicated applications. Topics include serial and parallel data communication, exception processing, file transfer protocol, I/O interfacing and peripherals, and assembly language programming.
[3 credit(s)] Prerequisites: EET 207 and MTT 300. Pre or corequisite: MTT 301 or ESC 250. Transform methods in circuit analysis, including the detailed analysis of circuits, waveforms, time-domain techniques, Laplace transform solutions, transfer functions, frequency response and Bode diagrams.
[3 credit(s)] Prerequisites: MTT 301 and EET 330. Corequisite: EET 411. Fundamental concepts of real, reactive, and apparent power and AC power analysis reviewed. Design considerations of power electronic rectification, controlled rectification, DC chopper power modulators, and DC-to-AC inverters. Fourier series analysis of inverter waveforms and power filter design are examined.
[1 credit(s)] Corequisite: EET 410. Experiments dealing with single-phase AC power analysis, rectifiers, inverters, switch-mode converters and their applications in adjustable motor drives.
[3 credit(s)] Prerequisites: EET 201, EET 330. Corequisite: EET 416. Analog electronics with applications using current integrated circuit devices. Analysis techniques of linear and non-linear systems and ideal and non-ideal device characteristics with an emphasis on practical design concepts.
EET 416 - Electronic Circuits, Signals, & Systems Laboratory
[1 credit(s)] Corequisite: EET 415. Experiments dealing with analog electronics applications using current integrated circuit devices, linear and non-linear systems and ideal and non-ideal device characteristics with an emphasis on practical design concepts.
[3 credit(s)] Prerequisite: MTT 300, EET 301 or equivalent. Co-requisite: EET 421. Survey of basic communication concepts involving rf amplifier, AM and FM modulation techniques, system performance under noise. Digital modulation and digital communication concepts. Data communication techniques. Digital radio and space communication. Fiberoptic communication.
EET 421 - Advanced Digital Communications Systems Lab
[1 credit(s)] Prerequisite: MTT 300, EET 301 or equivalent. Co-requisite: EET 420. Laboratory course for studying digital communication systems. Experimental study of modulation and demodulation in AM, FM, and dgital communication systems, A/D and D/A conversion, measurement of power spectra, and noise characterization in frequency domain.
[3 credit(s)] Prerequisites: EET 315, EET 316. Programming in Very High Speed Integrated Circuit Hardware Description Language (VHDL) that describes the inputs and outputs, behavior, and functions of circuits. Applications of logic circuitry will be implemented with Field Programmable Gate Array (FPGA) technology.
[3 credit(s)] Prerequisites: MTT 301, EET 330. Corequisite: EET 441. Algebraic diagram representation of open and closed loop processes. Block diagram reduction methods. Fundamental analysis methods of linear feedback controls using transfer function, time-domain, and frequency-domain methodologies. Analysis and design is also extended to non-linear processes using computer simulation methods. Simulation evaluations include closed loop tuning, dead-time process control, and electro-mechanical motion control.
[1 credit(s)] Corequisite: EET 440. Experiments dealing with feedback control system concepts, open and closed loop processes, block diagram reduction methods, analysis of linear feedback controls using transfer function, time-domain, and frequency-domain methodologies. Computer simulations of non-linear processes, closed loop tuning, dead-time process control, and electro-mechanical motion control. Writing Course.
Semesters Offered: Every Spring
General Education Category: Writing Across Curriculum
[3 credit(s)] Prerequisite: EET 320, EET 321 or equivalent. Co-requisite: EET 451. A comprehensive understanding of the related programming algorithmic thought process required to design with and incorporate microcontroller based systems in dedicated applications. Topics include: Microcontroller architecture, the instruction set, assembly and C program development, I/O interfacing, peripherials, interrupt processing and systems applications.
[1 credit(s)] Prerequisite: EET 450 (as a prerequiste or corequisite). Laboratory section designed to be taken concurrently with the lecture course, EET 450.
[1 credit(s)] Prerequisites: Senior standing and all required 300-level program courses. Planning for the capstone course, EET 480 Senior Design B, to demonstrate the ability to define a problem in engineering terms and develop a realistic plan to complete an engineering project. A comprehensive written plan including budget, equipment requirements, time schedule, problem description, design alternatives, and tentative design will be prepared. Students are expected to extend their knowledge through self-study and research in developing and assessing design options. Ethical, legal, and environmental considerations are included. Students are encouraged to propose team projects.
[3 credit(s)] Prerequisite: EET 460 in previous semester. Complete project development from concept and proposal submitted in EET 460. Final written and oral reports will be required.
[3 credit(s)] Prerequisite: Senior standing or permission of instructor. Topics of current technical interest in electronics, controls, and computer industries, applying core concepts across the electronics engineering technology curriculum. NOTE: The content of this course changes periodically to provide the injection of recent technological topic areas and subject material into the curriculum. May be repeated for credit under different course subtitles. Technical Elective.
[1-3 credit(s)] Prerequisite: Senior standing or permission of instructor. Independent study on a special topic or project under the guidance of a faculty member. May be repeated for credit for a total of 9 credit hours with a change of topic. Technical Elective.
[1 credit(s)] Strategies for a successful college experience, including study habits, time management, learning styles, and the many rules and regulations to consider when working toward a degree. A major portion of the course is an in-depth look at the differences between the six majors offered in the engineering college.
ESC 102 - Technical Writing and Professional Communication
[3 credit(s)] Prerequisite: ENG 101 or ENG 100. Technical writing as a process for organized and concise expression of ideas and knowledgeable opinion; ethical standards; oral presentations; research methods; source documentation; team writing; writing of memos, letters, reports, and proposals; running an effective meeting; utilizing word-processing software to assist in the writing process.
[2 credit(s)] Prerequisite: Placement within one of the academic colleges at CSU. An introduction to the practice of engineering design, use of hand tools, reverse engineering, the creative process, and the various career paths within engineering. Course is intended for engineering students and for any other student interested in understanding the basics of engineering design and learning about engineering as a possible career.
[1 credit(s)] Prepares engineering students to enter the engineering co-op program. Students will learn about the co-op program structure and organization, and learn techniques on preparing a resume and searching for co-op positions. The students will receive assistance in planning their academic studies while they participate in the co-op program. The course will include lectures from company representatives to help students perform successful co-op assignments. Workshops and events will strengthen the students’ skills as they plan to participate and complete the co-op program.
[3 credit(s)] Prerequisite: MTH 168 or equivalent background. Fundamentals of scientific and engineering problem-solving using computers; covers ANSI C and concepts of accuracy and efficiency in programming solutions to engineering problems.
[3 credit(s)] Prerequisite: MTH 168 or equivalent. Fundamentals of scientific and engineering problem-solving using computers.Covers the MATLAB language and concepts of accuracy and efficiency in programming solutions to engineering problems.
[3 credit(s)] History and heritage of civil, environmental, mechanical, electrical, industrial, manufacturing, and chemical engineering. Uses a case study approach with emphasis on northeast Ohio. Examines how constraints and considerations such as economic, environmental, social, political, ethical, health and safety, manufacturability, and sustainability influence engineering practice. How professional and ethical responsibility affect engineering. Places the impact of engineering solutions in a global, economic, environmental, and societal context.
[3 credit(s)] Prerequisites: MTH 181, PHY 241 or 243. Mechanics of forces and force systems; static equilibrium, forces in structures and machines, friction, centroids, moments of inertia, radii of gyration, and virtual work.
[3 credit(s)] Prerequisite: ESC 201. Motion of particles and rigid bodies subjected to unbalanced force systems; the kinematics of plane motion, relative motion, coriolis acceleration; the concept of force, mass and acceleration; work and energy, and impulse and momentum.
[4 credit(s)] Prerequisites: MTH 181, PHY 241 or 243. Statics-mechanics of forces, friction, moment of a force, free body diagrams, 2D static equilibrium. Dynamics-kinematics of particles, kinetics of particles in 2D, force and acceleration, work and energy, impulse and momentum.
[1 credit(s)] This course aims to introduce students to the experience of people with disabilities and to develop empathy in students so they can have effective working partnerships with people with disabilities. Students will participate in four elements: 1. Presentations by experts in disability and assistive technology; 2. Classroom training in empathy skills; 3. Interactions with students in other disciplines; 4. Personal encounters with people with disabilities in the classroom, the clinic, and in the home.
[3 credit(s)] Prerequisite: ESC 201. Study of stress, strain and stress-strain relations; stress-load and load-deformation relationships for axial, torsion and bending members; buckling of columns; combined stresses, inelastic behavior.
[3 credit(s)] Prerequisites: CHM 261 and MTH 168 or equivalent. Structure of materials and their relationship to the mechanical and physical properties of materials, applications and uses.
[3 credit(s)] Prerequisites: MTH 182; student must have at least sophomore standing. Course focuses on the coupling of technical analysis and economic feasibility to determine the best course of action among alternatives competing for scarce resources in both public and private sector projects. Studies the principles, concepts, and methodology of the time value of money as applied to governmental, industrial, and personal economic decisions. Topics include benefit-cost analysis, inflation, depreciation, taxes, tax abatements, risk and sensitivity analysis, and the comparison of alternatives. Discussion includes the ethical and social responsibilities of engineers as they apply to project decisions affecting job creation and loss, personnel placement, and capital expenditure. Social Science.
ESC 300 - Fenn College Cooperative Education Experience
[6 credit(s)] Prerequisites: ESC 130, Acceptance into the Cooperative Education Program, Sophomore standing. Work with a designated faculty advisor to establish objectives for the co-op period, review progress during the work period and review results of the experience against objectives. A student final report is required. Course must be taken during every cooperative education period. May be repeated for a maximum of 4 co-op periods. (Satisfactory/Unsatisfactory grading)
[3 credit(s)] Prerequisite: ESC 250. Study of fluid properties, hydrostatics, friction loss, dimensional analysis, statics, and dynamics of compressible and incompressible fluids; continuity, energy, and momentum principles; laminar and turbulent flow; general concepts of boundary layer flow.
[2 credit(s)] This course aims to further develop empathy skills that were learned in Disability, Empathy and Technology I and also to develop the ability to switch between empathic and analytic orientations. Students will participate in four elements: 1. Student presentations on professional roles in working with people with disabilities; 2. Classroom training in mode switching between empathic and analytic orientations; 3. Interprofessional interactions with other students; 4. Regular visits to the home of a specific person with a disability.
[3 credit(s)] Prerequisite: MTH 182, or MTT 300, or Equivalent. Concepts of statistics and probability for engineers. Probability distributions of engineering applications; sampling distributions; hypothesis testing; parameter estimation; response surface methodology.
[3 credit(s)] Prerequisites or corequisites: MTH 182, ESC 250. Solutions of linear DC and AC circuits, impedance, power, power factor correction, operational amplifiers and rotating DC and AC machines; applications to engineering situations.
[3 credit(s)] Prerequisite: MTH 182. Classical thermodynamic approach to systems and to control volumes containing simple compressible substances; establishment of important thermodynamic properties and their application to the zeroth, first and second laws analysis of systems and control volumes; analysis of ideal and actual gas cycles.
[3 credit(s)] Prerequisites: MTH 182, and ESC 151 or ESC 152 or CIS 260 or equivalent computer programming language. Vectors and vector operations, matrices and determinants, eigenvalues and eigenvectors, systems of linear and non-linear equations. Linear Algebra applications in Engineering. Introduction to related numerical methods for Engineering applications. MATLAB for linear algebra applications.
ESC 400 - Fenn College Cooperative Education Experience
[1 credit(s)] Prerequisites: ESC 130, Acceptance into the Cooperative Education Program, Sophomore standing. Work with a designated faculty advisor to establish objectives for the co-op period, review progress during the work period and review results of the experience against objectives. A student final report is required. Course must be taken during every cooperative education period. May be repeated for a maximum of 4 co-op periods. (Satisfactory/Unsatisfactory grading)
[0 credit(s)] Intensive workshop reviewing grammar and punctuation of standard written English, paragraphs, and introduction to the composition of essays. The workshop is part Viking Academic Boot Camp which is designed to prepare students for college-level coursework.
[2 credit(s)] Prerequisite: Placement by ACT/SAT scores or English Placement Exam. This course is a workshop course designed to provide individualized instruction for students working below the English 100 level by helping them become more confident and skillful college writers. Students who complete ENG 099 with a grade of “SC” or better are eligible to enroll in ENG 100. Credits earned in ENG 099 do not count toward graduation.
[3 credit(s)] Prerequisite: Placement by ACT/SAT scores or English Placement Exam. This course provides students with intensive writing instruction in the basic skills of expository and argumentative writing. Supplemental instruction is provided in the form of a tutorial component. Each Fall and Spring semester, a special section of ENG 100 is offered for students whose native language is not English. ENG 100 and ENG 101 cannot both be counted toward fulfillment of the first year writing requirement. ENG 100 requires class contact time of 4 credit hours and will be both applied towards financial aid and term billing as 4 credits. Only 3 credit hours count toward graduation requirements and will appear on a student schedule. The course requires a fee for supplemental writing center tutoring.
[3 credit(s)] Prerequisite: Placement by ACT/SAT scores or English Placement Exam. This course instructs students in the basic skills of expository and argumentative writing. Each Fall and Spring semester, a special section of ENG 101 is offered for students whose native language is not English. ENG 101 and ENG 100 cannot both be counted toward fulfillment of the first-year writing requirement. Supplemental instruction is available for this course by taking ENG 105.
[3 credit(s)] Prerequisite: Placement by ACT/SAT scores or English Placement Exam, or completion of ENG 100 or ENG 101. ENG 102 continues to cultivate and hone the skills acquired in ENG 100 or ENG 101, but also incorporates research and information literacy skills. Each Fall and Spring semester, a special section of ENG 102 is offered for students whose native language is not English. Supplemental instruction is available for this course by taking ENG 106.
[3 credit(s)] Prerequisites: Honors students or permission of university Honors Program. An advanced introduction to academic research and writing through intensive investigation of an issue or topic specified by the instructor. Students will be required to develop and organize a substantial research project related to the topic of the course and to demonstrate the information literacy skills required to find, evaluate, and make appropriate use of primary and secondary materials relevant to their project.