EE 101B: Circuits II
Continuation of
EE101A. Introduction to circuit design for modern electronic systems. Modeling and analysis of analog gain stages, frequency response, feedback. Filtering and analog¿to¿digital conversion. Fundamentals of circuit simulation. Prerequisites:
EE101A,
EE102A. Recommended:
CME102.
Terms: Spr
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Units: 4
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UG Reqs: GER:DB-EngrAppSci, WAY-SMA
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Grading: Letter or Credit/No Credit
Instructors:
Murmann, B. (PI)
EE 133: Analog Communications Design Laboratory (EE 233)
Design, testing, and applications. Amplitude modulation (AM) using multiplier circuits. Frequency modulation (FM) based on discrete oscillator and integrated modulator circuits such as voltage-controlled oscillators (VCOs). Phased-lock loop (PLL) techniques, characterization of key parameters, and their applications. Practical aspects of circuit implementations. Labs involve building and characterization of AM and FM modulation/demodulation circuits and subsystems. Enrollment limited to 30 undergraduates and coterminal EE students. Prerequisite:
EE101B. Undergraduate students enroll in EE133 and Graduate students enroll in
EE233. Recommended:
EE114/214A.
Terms: Win
|
Units: 3-4
|
Grading: Letter or Credit/No Credit
EE 155: Green Electronics (EE 255)
Many green technologies including hybrid cars, photovoltaic energy systems, efficient power supplies, and energy-conserving control systems have at their heart intelligent, high-power electronics. This course examines this technology and uses green-tech examples to teach the engineering principles of modeling, optimization, analysis, simulation, and design. Topics include power converter topologies, periodic steady-state analysis, control, motors and drives, photovol-taic systems, and design of magnetic components. The course involves a hands-on laboratory and a substantial final project. Formerly
EE 152. Required:
EE101B,
EE102A,
EE108. Recommended: ENGR40 or
EE122A.
Terms: Aut
|
Units: 4
|
Grading: Letter (ABCD/NP)
Instructors:
Dally, B. (PI)
EE 233: Analog Communications Design Laboratory (EE 133)
Design, testing, and applications. Amplitude modulation (AM) using multiplier circuits. Frequency modulation (FM) based on discrete oscillator and integrated modulator circuits such as voltage-controlled oscillators (VCOs). Phased-lock loop (PLL) techniques, characterization of key parameters, and their applications. Practical aspects of circuit implementations. Labs involve building and characterization of AM and FM modulation/demodulation circuits and subsystems. Enrollment limited to 30 undergraduates and coterminal EE students. Prerequisite:
EE101B. Undergraduate students enroll in EE133 and Graduate students enroll in
EE233. Recommended:
EE114/214A.
Terms: Win
|
Units: 3-4
|
Grading: Letter or Credit/No Credit
EE 255: Green Electronics (EE 155)
Many green technologies including hybrid cars, photovoltaic energy systems, efficient power supplies, and energy-conserving control systems have at their heart intelligent, high-power electronics. This course examines this technology and uses green-tech examples to teach the engineering principles of modeling, optimization, analysis, simulation, and design. Topics include power converter topologies, periodic steady-state analysis, control, motors and drives, photovol-taic systems, and design of magnetic components. The course involves a hands-on laboratory and a substantial final project. Formerly
EE 152. Required:
EE101B,
EE102A,
EE108. Recommended: ENGR40 or
EE122A.
Terms: Aut
|
Units: 4
|
Grading: Letter (ABCD/NP)
Instructors:
Dally, B. (PI)
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