EENG 330 — MICROELECTRONICS I and MICROELECTRONICS I LAB
Learning Objectives & Matches
1. Explain transport carriers in semiconductors, identify the pn junction and associated circuit models
Calculate the efficiency or power output of a fuel cell system or process.
Read and interpret electronic circuit diagrams, function block diagrams, specifications, engineering drawings, and service manuals.
Read and interpret electronic circuit diagrams, function block diagrams, specifications, engineering drawings, and service manuals.
Observe the current system in operation, and gather and analyze information about each of the component problems, using a variety of sources.
Test conductors, according to electrical diagrams and specifications, to identify corresponding conductors and to prevent incorrect connections.
Plan or implement research methodology or procedures to apply principles of electrical theory to engineering projects.
Perform complex, dynamic, and integrated mathematical modeling of ecological, environmental, or economic systems.
Calculate potential for energy savings.
Conduct research related to a range of nanotechnology topics, such as packaging, heat transfer, fluorescence detection, nanoparticle dispersion, hybrid systems, liquid systems, nanocomposites, nanofabrication, optoelectronics, or nanolithography.
Determine connection interfaces for additional subpanels or for connecting photovoltaic (PV) systems with utility services or other power generation sources.
2. Explain the ideal diode model and perform its circuit analysis, evaluate the exponential and constant voltage diode models and their applications in regulators and rectifiers.
Examine designs to determine current requirements for all parts of the photovoltaic (PV) system electrical circuit.
Formulate mathematical models or other methods of computer analysis to develop, evaluate, or modify design, according to customer engineering requirements.
Perform complex calculations as part of the analysis and evaluation of data, using computers.
Calculate amount of pollutant in samples or compute air pollution or gas flow in industrial processes, using chemical and mathematical formulas.
Devise or apply independent models or tools to help verify results of analytical systems.
Formulate mathematical or simulation models of problems, relating constants and variables, restrictions, alternatives, conflicting objectives, and their numerical parameters.
Specify power supply requirements and configuration, drawing on system performance expectations and design specifications.
Break systems into their components, assign numerical values to each component, and examine the mathematical relationships between them.
Deliver oral or written presentations of the results of mathematical modeling and data analysis to management or other end users.
Inspect electrical connections, wiring, relays, charging resistance boxes, and storage batteries, following wiring diagrams.
3. Explain the BJT transistor model and apply it to the design and analysis of different transistor circuits
Read and interpret electronic circuit diagrams, function block diagrams, specifications, engineering drawings, and service manuals.
Formulate mathematical models or other methods of computer analysis to develop, evaluate, or modify design, according to customer engineering requirements.
Read blueprints, wiring diagrams, schematic drawings, or engineering instructions for assembling electronics units, applying knowledge of electronic theory and components.
Develop or modify industrial electronic devices, circuits, or equipment, according to available specifications.
Plan or implement research methodology or procedures to apply principles of electrical theory to engineering projects.
Explain design specifications to integration or test engineers.
Direct the analysis, development, and operation of complete computer systems.
Develop computer models of chemical processes.
Consult with engineers to discuss or interpret design concepts, or determine requirements of detailed working drawings.
Specify manipulative or computational methods to be applied to models.
4. Identify input and output impedances, explain the concept of biasing and perform DC and small-signal analysis. Explain concepts of source degeneration and self-biasing
Process or interpret signals or sensor data.
Read and interpret electronic circuit diagrams, function block diagrams, specifications, engineering drawings, and service manuals.
Observe the current system in operation, and gather and analyze information about each of the component problems, using a variety of sources.
Specify inputs accessed by the system and plan the distribution and use of the results.
Determine voices, instruments, harmonic structures, rhythms, tempos, and tone balances required to achieve the effects desired in a musical composition.
Calculate the efficiency or power output of a fuel cell system or process.
Perform environmentally extended input-output (EE I-O) analyses.
Read dials and meters to determine amperage, voltage, electrical output and input at specific operating temperature to analyze parts performance.
Read blueprints, wiring diagrams, schematic drawings, or engineering instructions for assembling electronics units, applying knowledge of electronic theory and components.
Monitor and analyze network performance and reports on data input or output to detect problems, identify inefficient use of computer resources, or perform capacity planning.
5. Apply biasing techniques to BJT amplifier stages, design constant current sources, explain operation of common-emitter stage, common-base stage and emitter follower
Observe the current system in operation, and gather and analyze information about each of the component problems, using a variety of sources.
Read and interpret electronic circuit diagrams, function block diagrams, specifications, engineering drawings, and service manuals.
Read blueprints, wiring diagrams, schematic drawings, or engineering instructions for assembling electronics units, applying knowledge of electronic theory and components.
Write detailed functional specifications that document the hardware development process and support hardware introduction.
Conduct logical analyses of business, scientific, engineering, and other technical problems, formulating mathematical models of problems for solution by computers.
Create Web models or prototypes that include physical, interface, logical, or data models.
Create Web models or prototypes that include physical, interface, logical, or data models.
Review project instructions and blueprints to ascertain test specifications, procedures, and objectives, and test nature of technical problems such as redesign.
Plan or implement research methodology or procedures to apply principles of electrical theory to engineering projects.
Evaluate project work to ensure effectiveness, technical adequacy, or compatibility in the resolution of complex electronics engineering problems.