| Master of Engineering | MENG | 400 | Engineering Law | 3 OR 4 hours. | Overview of the legal system. Legal principles affecting the engineering profession. Professional ethics in engineering. Intellectual property law. Basic contract and tort principles. Environmental law. Same as ENGR 400. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. This is an online web-based course. Prerequisite(s): Senior standing or above. |
| Master of Engineering | MENG | 401 | Engineering Management | 3 OR 4 hours. | Theory, strategy, and tactics of the use of project management including project planning, matrix management concept, and team meetings. Same as ENGR 401. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. This is an online web-based course. Prerequisite(s): Senior standing or above. |
| Master of Engineering | MENG | 402 | Intellectual Property Law | 3 OR 4 hours. | Patent, copyright, trade secret, mask work, and cyber-squatting legal and procedural principles; protection for novel software, biotech inventions, and business methods; and trademark protection for domain names. Same as ENGR 402. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. This is an online web-based course. Prerequisite(s): Senior standing or above. |
| Master of Engineering | MENG | 403 | Reliability Engineering | 3 OR 4 hours. | Probability overview; statistics overview; system reliability modeling and prediction-static methods; system reliability modeling and prediction-dynamic methods; maintainability and availability; reliability optimization; and risk analysis. Same as ENGR 403. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. This is an online web-based course. Prerequisite(s): Senior standing or above. |
| Master of Engineering | MENG | 410 | Transport Phenomena | 3 OR 4 hours. | Continuum theory of momentum, energy, and mass transfer. Viscous behavior of fluids. Laminar and turbulent flow. Thermal conduction and convection, diffusion and coupled operations. Same as CHE 410. 3 undergraduate hours. 4 graduate hours. Prerequisite(s): CHE 312 or consent of the instructor. |
| Master of Engineering | MENG | 411 | Non-Newtonian Fluids | 3 OR 4 hours. | Fluid mechanics and transport processes involving non-Newtonian fluids. Purely viscous and viscoelastic behavior. Viscometric functions and rheometry. Heat and mass transfer in non-Newtonian fluids. Same as CHE 440. 3 undergraduate hours. 4 graduate hours. Prerequisite(s): CHE 410 or MENG 410 or consent of the instructor. |
| Master of Engineering | MENG | 412 | Computational Molecular Modeling | 3 OR 4 hours. | Provide students with a fundamental understanding of the methods, capabilities and limitations of molecular simulations. Same as CHE 438. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. Prerequisite(s): CHE 301. Recommended background: Engineering/Science. |
| Master of Engineering | MENG | 413 | Fundamentals and Design of Microelectronics Processes | 3 OR 4 hours. | Design and practical aspects of the most advanced state of micro- and nano-electronics processing with emphasis on thin film deposition, substrate passivation, lithography and etching with thermodynamics, kinetics, reactor design, and optimization. Same as CHE 456. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. Prerequisite(s): Graduate standing or consent of the instructor. Recommended background: Engineering/Science. |
| Master of Engineering | MENG | 436 | Wireless Data | 3 OR 4 hours. | Data communications, existing Wireless Data Networks, planning, topology, performance, and operation. Same as ENGR 436. 3 undergraduate hours. 4 graduate hours. Extensive computer use required. This is an online web-based course. Prerequisite(s): Senior standing or above and a course in digital communications and an introductory course in wireless communications. |
| Master of Engineering | MENG | 512 | Microhydrodynamics, Diffusion and Membrane Transport | 4 hours. | Theoretical and numerical fluid mechanics of microstructure: potential flow and virtual mass, quasistatic versus transient Stokes flow, integral theorems, multipole expansions, singularity solutions, fluctuations, and current applications. Same as CHE 512. Prerequisite(s): CHE 410 or MENG 410 and CHE 445 or consent of the instructor. |