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Course Criteria
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6.00 Credits
2 lecture hours, 4 laboratory hours; 4 credits, 6 hours Power and three-phase circuits, power transmission, and transformers. Real and reactive power, power flow and power handling capacity of parallel lines. Long haul high-voltage power transmission. Applications of Convolution. Complete response of first, second, and higher-order circuits. Sinusoidal steady-state and transient analysis. The application of Laplace transform in circuit analysis. Frequency response. Analog filter design. Prerequisite: ENS 241 Corequisite: MTH 330
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4.00 Credits
(Also CSC 446) 4 hours; 4 credits Instruction formats and addressing schemes. Arithmetic and logic unit design. Control unit design: hardwired and microprogrammed. Main memory technology. Virtual, high-speed, associative, and read-only memories. Programmable logic arrays. Computer organizations including stack, parallel, and pipeline. System structures: time sharing, multiprocessing, and networking. Digital communications. Input/output systems; direct memory access. Prerequisite: CSC 346 or ENS 220
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4.00 Credits
(Also PHY 450) 4 hours; 4 credits Fluid properties, fluid statics, buoyancy and stability, fluids in rigid-body motion. Basic fluid equations in differential and integral form, Navier- Stokes equation. Euler equation, Bernoulli equation and engineering applications. Dimensional analysis and similitude. Internal incompressible viscous flow and flow measurement. Prerequisite: ENS 310 Pre- or corequisite: MTH 330
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4.00 Credits
4 hours; 2 credits Experiments in conduction, convection, and radiation. Experiments with floating body stability, fluid losses under different flow configurations. Experiments with engines, governors, and pumps. Design, building, testing, and evaluation of simple heat transfer and mechanical systems. Prerequisite: ENS 249 Pre- or corequisite: ENS 450
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2.00 Credits
(also PHY 463) 2 hours lecture, 4 hours laboratory; 4 credits This is an introductory course on nanotechnology. It covers the physical basics of submicron- and nano-size structures, methods and materials of nanotechnology, characterization of nanostructures and their industrial applications. The course covers (i) mechanical, electronic, and optical properties of nanoscopic systems; (ii) engineering approaches in nanoelectro- mechanics; nanoelectronics, and nanophotonics; (iii) practical computer simulation and design of nanodevices; (iv) practical nanofabrication of rudimentary nanodevices with focused ion beams. Prerequisite: ENS/PHY 385
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4.00 Credits
4 hours laboratory; 2 credits A microcontroller integrating experience where students will develop a device that will be documented, built, and tested in the laboratory. The course will emphasize application of engineering design subject to realistic constraints covering applications in areas such as industrial control, automation, appliances, medical devices, computer architectures and robotics. Prerequisite: ENS 362 or CSC 462
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4.00 Credits
4 hours; 4 credits Principles of systems analysis as applied to environmental problems. Topics to be chosen from air and water pollution, energy utilization, thermal pollution, transportation systems, solid and liquid waste disposal, etc. Prerequisite: ENS 310 or permission of the instructor
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4.00 Credits
4 hours; 4 credits Concepts of feedback control system. State space and transfer function models of dynamic systems. System reduction and response analysis. Sensitivity, stability, and steady-state error analysis. Root locus and frequency response (Bode and Nyquist) design methods, compensator design. Computer-aided analysis/design. Prerequisites: ENS 241, ENS 310, ENS 336, and MTH 330
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4.00 Credits
4 hours laboratory, 2 hours lecture; 4 credits: An introduction to digital image fundamentals, digital image systems, image enhancement, image transforms, image restoration, image segmentation, and image/video compression techniques with applications in areas of radar, forward-looking infra-red (FLIR), medical imaging, and astrophysics. Prerequisites: ENS 331, ENS 336
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4.00 Credits
(Also PHY 485) 4 hours; 4 credits Structure of crystalline and noncrystalline solids. Defects in solids. Phase equilibrium and transformations, thermodynamics of multicomponent systems, surfaces, diffusions, and structural changes. Mechanical properties, plasticity, strengthening. Heat treatment. Electrical properties, conductivity, energy bands, semiconductors, superconductors, and devices. Optical and dielectric properties, optical fibers, and lasers. Magnetic and thermal properties. Material consideration in the engineering design process. Prerequisite: Physics 240 or permission of the instructor
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