Principles of visually communicating engineering designs. Topics include technical sketching, technical drawing, engineering graphics and design; 3-D visualization with orthographic projection; dimensioning and tolerancing practices; computer aided drafting/design (CAD) software; graphical analytical methods of solutions to three-dimensional problems. Assignments develop sketching and 2-D and 3-D CAD skills. The use of CAD software is an integral part of this course.
An introduction to the construction and measurement of electrical circuits exercising DC, transient, and sinusoidal steady-state (AC) conditions. Use of test and measurement instruments, including multimeters, oscilloscopes, power supplies, and function generators. Introduction to component value tolerance and non-ideal aspects of laboratory instruments. Use of circuit simulation software. Interpretation of measured and simulated data based on principles of circuit analysis.
Introduction to circuit analysis. Determination of the natural, forced and complete responses of zero, first and second-order networks. Standard circuit-analysis techniques including Kirchhoff's Laws, mesh and nodal analysis, Thevenin and Norton's Theorems, generalized impedance and admittance techniques and phasor methods.
Introduction to team-oriented engineering design, problem solving processes, and the use of computers in the solution of engineering problems, including commercial spreadsheet applications and analysis/graphics applications. Emphasis on technical communication, teamwork, engineering design and problem solving methodologies. Multiple hands-on design projects.
The history and development of engineering as a profession. Engineering disciplines, job functions, educational requirements, transfer school information, academic success strategies, workplace skills, engineering ethics, sustainability principles applied to engineering, current and projected activities in the various branches of engineering.
Hands-on microcontroller interfacing, driver programs, input sensors, output electrical, and electromechanical devices.
Course covers digital interfaces and hardware programming. Topics include digital to analog interfacing using integrated circuits, programmable logic devices, field programmable gate arrays (FPGA), hardware description languages (e.g. VHDL and Verilog), and computer memory. Course requires hands-on project construction and troubleshooting. Industry standard testing methods, equipment, and protocols are used throughout the course.
Introduction to intermediate analog electronic circuits, including field effect transistor basics, various analog amplifiers, operational amplifiers and their use. Hands-on electronic projects include building summing and difference amplifiers, audio amplifiers, and AM/FM radios.
This course covers Boolean logic concepts, flip-flops, memory, counters, clocks, display decoders, and timers. Analysis of digital logic principles is practiced by building and testing functional and practical projects. There will be intense hands-on troubleshooting using logic analyzers, signal generators and digital multimeters. Standard industry testing methods, equipment, and protocols are used throughout the course.
This course covers diode characteristics, power supplies, bipolar transistors, simple one-stage amplifiers, constant current sources, and transformers. The students will learn the intermediate use of the oscilloscope and multi-meter for both calibration and troubleshooting. Hands-on electronic projects include building their own power supply, a current regulator, and various amplifier circuits.