Engineering (EGR) at Laurel Ridge Community College
Distance Learning
Time of Day
Term
- EGR 120 - Introduction to Engineering
- Introduces the engineering profession, professional concepts, ethics, and responsibility. Reviews hand calculators, number systems, and unit conversions. Introduces the personal computer and operating systems. Includes engineering problem solving techniques using computer software. This course applies to career/technical education (CTE) programs. EGR 121-122 serve both transfer and CTE programs.Lecture 0-2 hours. Laboratory 0-3 hours. Total 1-4 hours per week.
1-2 credits - EGR 121 - Foundations of Engineering
- Introduces the engineering profession and its impact on society and the environment, including engineering problem solving, the engineering design process, and professional practices. Covers fundamental engineering calculations, descriptive statistics, basic spreadsheet and mathematical scripting language applications, professional ethics, teamwork, and communicationLecture 2 hours. Total 2 hour per week.
Prerequisites: ENG 111 eligible; MTH 162 or MTH 167, or equivalent; or departmental approval.2 credits - EGR 122 - Engineering Design
- Applies engineering methods to a semester-long team design project with an emphasis on engineering software involving 2D and 3D computer aided design; data modeling and analysis; and iterative programming solutions. Covers design drawings and dimensioning; spreadsheet software usage; mathematical scripting language; and professional practices.Lecture 2 hours. Laboratory 2 hours. Total 4 hours per week.
Prerequisite: EGR 121 or departmental permission.3 credits - EGR 125 - Introduction to Computer Programming for Engineers
- Introduces problem solving and implementation of computer software solutions using a high-level programming language in a structured environment. Includes concepts and practice of algorithm design, language syntax, control structures, arrays, and introduction to object-oriented programming. Covers engineering applications, such as mathematical modeling, file input and output, and basic numerical methods. The assignments in this course require mathematical problem-solving skills, algebraic modeling, and functions, and use of variables.Lecture 4 hours. Total 4 hours per week.
Prerequisites: MTH 162 or MTH 167 or equivalent; Corequisites: EGR 1214 credits - EGR 135 - Statics for Engineering Technology
- Introduces Newton's Laws, resultants and equilibrium of force systems, analysis of trusses and frames. Teaches determination of centroids, distributed loads and moments of inertia. Covers dry friction and force systems in space.Lecture 3 hours per week.
3 credits - EGR 136 - Strength of Materials for Engineering Technology
- Presents concepts of stress and strain. Focuses on analysis of stresses and deformations in loaded members, connectors, shafts, beams, columns and combined stress.Lecture 3 hours per week.
3 credits - EGR 206 - Engineering Economics
- Presents economic analysis of engineering alternatives. Studies economic and cost concepts, calculation of economic equivalence, comparison of alternatives, replacement economy, economic optimization in design and operation, depreciation, and after tax analysis.Lecture 2-3 hours per week.
2-3 credits - EGR 216 - Computer Methods in Engineering and Technology
- Provides advanced level experience in using a computer as a tool for solving technical problems and performing office functions. Includes computer hardware and operating system usage, structured programming in a selected high level language, use of word processing software, computer graphics and spreadsheets. Focuses on the analysis and solution of problems in engineering and technology.Lecture 2 hours. Laboratory 2 hours. Total 4 hours per week.
3 credits - EGR 240 - Statics
- Introduces basic concepts of engineering mechanics, systems of forces and couples, equilibrium of particles and rigid bodies, and internal forces and analysis of structures, including SI and U.S. customary units. Includes trusses, frames, machines, beams, distributed forces, friction, and centroids.Lecture 3 hours. Total 3 hours per week.
Prerequisites: MTH 263 or department permission3 credits - EGR 245 - Dynamics
- Presents approach to kinematics and kinetics of particles (and systems of particles) in linear and curvilinear motion. Includes kinematics and kinetics of rigid bodies in plane motion. Teaches Newton's second law, work-energy, and impulse-momentum methods.Lecture 3 hours. Total 3 hours per week.
Prerequisites: EGR 240 or departmental approval.3 credits - EGR 246 - Mechanics of Materials
- Introduces concepts of stress, strain, deformation, internal equilibrium, and basic properties of engineering materials. Analyzes axial loads, torsion, bending, shear and combined loading. Studies stress transformation, principal stresses, and buckling.Lecture 3 hours. Total 3 hours per week.
Prerequisites: EGR 240 or departmental approval.3 credits - EGR 248 - Thermodynamics for Engineering
- Presents fundamental concepts of classical thermodynamics. Includes the first and second law of thermodynamics, thermodynamic properties of pure substances, processes involving energy transfer as work and heat, reversibility and irreversibility, closed and open systems, and thermodynamic cycles.3 credits
- EGR 270 - Fundamentals of Computer Engineering
- Covers digital system analysis, design, and implementation. Includes digital logic, Boolean algebra, combinational and sequential circuits, hierarchical design, and introduction to computer organization and assembly language. Features in laboratory work the use of discrete logic, programmable logic devices, and hardware description language to design, simulate, implement, validate, and document digital circuitsLecture 3 hours. Laboratory 3 hours. Total 6 hours per week.
Prerequisites: EGR 121 and either EGR 125 or CSC 2214 credits - EGR 271 - Electric Circuits I
- Covers fundamentals of electric circuits. Teaches resistive circuit analysis methods, including network theorems. Features operational amplifiers, capacitors, inductors, resistor-capacitor (RC), resistor-inductor (RL) and resistance-inductance-capacitance (RLC) circuit transient response. Introduces phasor representation of alternating current (AC) circuits. Utilizes circuit design processes, technical writing and computer software for problem solving. Includes laboratory analysis to explore course concepts. Part I of II.4 credits
- EGR 272 - Electric Circuits II
- Covers sinusoidal steady-state circuit response using phasors, frequency analysis of linear circuits including frequency response, Bode plots, Fourier series analysis, and design of basic filters. Examines Laplace circuit analysis and transfer functions, AC power analysis, nonlinear diode models, and technical writing. Includes laboratory analysis and open-ended design project. Part II of II.4 credits