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  • 16.453: Software EngineeringCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Introduces software life cycle models, and engineering methods for software design and development. Design and implementation, testing, and maintenance of large software packages in a dynamic environment, and systematic approach to software design with emphasis on portabili-ty and ease of modification. Laboratories include a project where some of the software engineer-ing methods (from modeling to testing) are applied in an engineering example. Pre-Req: 16.216 Dig Control Programming and 16.322 Data Structures
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  • 16.460: Biomedical InstrumentationCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Analysis and design of Biomedical Instrumentation systems that acquire and process biophysical signals. Properties of Biopotential signals and electrodes; Biopotential Amplifiers and Signal Processing; Basic Sensors and Principles; Medical Imaging Systems; Electrical Safety.
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  • 16.461: Engineering Electromagnetics IICredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Continuation of Magnetostatics, Maxwell's Equations for Time-varying Fields, plane waves: time-harmonic fields, polarization, current flow in good conductors and skin effect, power density and Poynting vector, wave reflection and transmission; Snell's Law, fiber optics, Brewster angle, radiation and simple antennas, electromagnetic concepts involved in a topical technology in development. " Pre-Req: 16.360 Emag Theory I
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  • 16.462: Antenna Theory and DesignCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 An introduction to properties of individual antennas and arrays of antennas. Retarded potentials, dipoles of arbitrary length, radiation pattern, gain, directivity, radiation resistance. The loop antenna. Effects of the earth. Reciprocity, receiving antennas, effective length and area. Moment methods. Arrays: collinear, broadside, endfire. Array synthesis. Mutual coupling. Log-periodic and Yagi arrays. Radiation from apertures: the waveguide horn antenna, parabolic dish. Antenna noise temperature. Numerical software packages. A design project is required in the course. Pre-Req: 16.461 Emag Theory II
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  • 16.468: Electro-optics & Integrated OpticsCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 An introduction to physical optics,electro-optics and integrated optics. Topics include: Waves and polarization, optical resonators, optical waveguides, coupling between waveguides, electro-optical properties of crystals, electro-optic modulators, Micro-Optical-Electro-Mechanical (MEMS) Devices and photonic and microwave wireless systems. Pre-Req: 16.360 Emag Theory I
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  • 16.469: VLSI DesignCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Introduction to CMOS circuits including transmission gate, inverter, NAND, NOR gates, MUXEs, latches and registers. MOS transistor theory including threshold voltage and design equations. CMOS inverter's DC and AC characteristics along with noise margins. Circuit characterization and performance estimation including resistance, capacitance, routing capacitance, multiple conductor capacitance, distributed RC capacitance, multiple conductor capacitance, distributed RC capacitance, switching characteristics incorporating analytic delay models, transistor sizing and power dissipation. CMOS circuit and logic design including fan-in, fan-out, gate delays, logic gate layout incorporating standard cell design, gate array layout, and single as well as two-phase clocking. CMOS test methodologies including stuck-at-0, stuck-at-1, fault models, fault coverage, ATPG, fault grading and simulation including scan-based and self test techniques with signature analysis. A project of modest complexity would be designed to be fabricated at MOSIS. Pre-Reqs: 16.265 Intro Logic Design and 16.365 Electronics I
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  • 16.470: VLSI FabricationCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Fabrication of resistors, capacitors, p-n junction and Schottky barrier diodes, BJT's and MOS devices and integrated circuits. Topics include: silicon structure, wafer preparation, sequential techniques in microelectronic processing, testing and packaging, yield and clean room environments. MOS structures, crystal defects, Fick's laws of diffusion; oxidation of silicon, photolithography including photoresist, development and stripping. Metallization for conductors, Ion implantation for depletion mode and CMOS transistors for better yield speed, low power dissipation and reliability. Students will fabricate circuits using the DSIPL Laboratory. Pre-Req: 16.365 Electronics I
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  • 16.472: Embedded Real Time SystemsCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Designing embedded real-time computer systems. Types of real-time systems, including foreground/background, non-preemptive multitasking, and priority-based pre-emptive multitasking systems. Soft vs. hard real time systems. Task scheduling algorithms and deterministic behavior. Ask synchronization: semaphores, mailboxes and message queues. Robust memory management schemes. Application and design of a real-time kernel. A project is required. Pre-Reqs: 16.216 Dig Control Programming,16.317 Microprocessor Sys Desgn I, 16.322 Data Structures
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  • 16.473: Power ElectronicsCredits

    1.00 Credits
    University of Massachusetts-Lowell

    3 A one-semester course with emphasis on the engineering design and performance analysis of power electronics converters. Topics include: power electronics devices (power MOSFETs, power transistors, diodes, silicon controlled rectifiers SCRs, TRIACs, DIACs and Power Darlington Transistors), rectifiers, inverters, ac voltage controllers, dc choppers, cycloconverters, and power supplies. The course includes a project, which requires that the student design and build one of the power electronics converters. A demonstrative laboratory to expose the students to all kinds of projects is part of the course. Pre-Reqs: 16.355 Electromechanics and 16.366 Electronics II
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  • 16.474: Principles Of Solid State DevicesCredits

    3.00 Credits
    University of Massachusetts-Lowell

    3 Principles of Solid State Devices: Crystal properties and growth of semi-conductors, atoms and electrons, Bohr's model, quantum mechanics, bonding forces and energy bands in solids, charge carriers in semiconductors, drift of carriers in electric and magnetic fields, carrier lifetime and photoconductivity, junctions, forward and reverse bias, reverse bias breakdown (Zener effect), tunnel diodes, photodiodes, LED, bipolar junction transistors, field effect transistors. A design project is included in the course. Pre-Req: 16.365 Electronics I
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