With lab. Continuation of ECE 211. Analysis techniques for ac circuits, frequency response, resonance, Bode plots, phasor representation of sinusoidal steady-state systems, complex frequency domain, transfer functions. MOSFETs as amplifiers; operational amplifiers. Transformers, two-port networks, Fourier series. Lab includes circuit hardware and PSPICE simulation experiments.

With lab. Continuation of ECE 211. Analysis techniques for ac circuits, frequency response, resonance, Bode plots, phasor representation of sinusoidal steady-state systems, complex frequency domain, transfer functions. MOSFETs as amplifiers; operational amplifiers. Transformers, two-port networks, Fourier series. Lab includes circuit hardware and PSPICE simulation experiments.

With lab. Continuation of ECE 211. Analysis techniques for ac circuits, frequency response, resonance, Bode plots, phasor representation of sinusoidal steady-state systems, complex frequency domain, transfer functions. MOSFETs as amplifiers; operational amplifiers. Transformers, two-port networks, Fourier series. Lab includes circuit hardware and PSPICE simulation experiments.

With lab. Continuation of ECE 211. Analysis techniques for ac circuits, frequency response, resonance, Bode plots, phasor representation of sinusoidal steady-state systems, complex frequency domain, transfer functions. MOSFETs as amplifiers; operational amplifiers. Transformers, two-port networks, Fourier series. Lab includes circuit hardware and PSPICE simulation experiments.

With lab. Interpretation of geology for the purpose of planning, siting, design, and construction of engineered facilities. Includes plate tectonics, mineral and rock identification, engineering geologic mapping, air photo interpretation, residual soils, glaciation, and engineering problems associated with geologic features. Prerequisite: CE-ENGIN 320.

Chemical equilibrium principles of acids-bases, dissolution-precipitation, oxidation-reduction, and complexation applied to understanding the chemistry of surface waters, groundwaters, and water and wastewater treatment.

Design, selection, and use of instrumentation for geotechnical engineering purposes. Laboratory and field instrumentation considered. Topics include: purpose of instrumentation, planning projects, procurement of instruments and services, measuring devices, and examples of applications. Lab demonstration.

Chemical equilibrium principles of acids-bases, dissolution-precipitation, oxidation-reduction, and complexation applied to understanding the chemistry of surface waters, groundwaters, and water and wastewater treatment.

Principles of geographic information systems (GIS) and spatial analysis for engineering applications. Topics include data structures and manipulation, topology, and attribute information. Use of spatial data for mapping and spatial analysis to address real-world problems.

With Lab. Introduction to environmental engineering with a focus on physical, chemical, and biological principles. Topics include environmental standards and legislation, material balances, reaction kinetics, environmental chemistry and microbiology, biogeochemical cycles, water quality, water resources, air quality, and solid and hazardous wastes.

Prerequisite: MATH 331 and CHEM 112
Corequisite: CE-ENGIN 357