Difference between revisions of "Classes"

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(EE 330 - Integrated Electronics)
(EE 230 - Integrated Electronics)
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Dr. Tuttle's course website for EE230 can be found [http://tuttle.merc.iastate.edu/ee230/homepage.htm here]
 
Dr. Tuttle's course website for EE230 can be found [http://tuttle.merc.iastate.edu/ee230/homepage.htm here]
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Dr. Geiger's course website for EE230 can be found [http://class.ece.iastate.edu/ee230/ here]
 
Dr. Geiger's course website for EE230 can be found [http://class.ece.iastate.edu/ee230/ here]
  

Revision as of 18:50, 14 October 2015

Undergraduate EE Courses

EE 230 - Integrated Electronics

For more wiki content related to this class, see EE230
Also see the class website

The 2015-2016 course catalog gives the following description:

 
E E 230. Electronic Circuits and Systems. (3-3) Cr. 4. F.S. Prereq: E E 201, MATH 267, PHYS 222
Frequency domain characterization of electronic circuits and systems, transfer functions, sinusoidal steady state response. Time domain models of linear and nonlinear electronic circuits, linearization, small signal analysis. Stability and feedback circuits. Operational amplifiers, device models, linear and nonlinear applications, transfer function realizations. A/D and D/A converters, sources of distortions, converter linearity and spectral characterization, applications. Design and laboratory instrumentation and measurements. 

As of Fall 2015, EE230 was taught by Dr. Tuttle with four teaching assistants running the lab.

Dr. Tuttle's course website for EE230 can be found here

Dr. Geiger's course website for EE230 can be found here

EE 330 - Integrated Electronics

For more wiki content related to this class, see EE330
Also see the class website

The 2015-2016 course catalog gives the following description:

 
E E 330. Integrated Electronics. (Cross-listed with CPR E). (3-3) Cr. 4. Prereq: E E 201, credit or enrollment in E E 230, CPR E 281
Semiconductor technology for integrated circuits. Modeling of integrated devices including diodes, BJTs, and MOSFETs. Physical layout. Circuit simulation. Digital building blocks and digital circuit synthesis. Analysis and design of analog building blocks. Laboratory exercises and design projects with CAD tools and standard cells.

As of Fall 2015, EE330 was taught by Dr. Geiger with two undergraduate teaching assistants running the lab. The laboratory section of EE330 is a crash-course in practical use of EDA tools for manual design, the automated digital design flow, and layout.

Dr. Geiger's course website for EE330 can be found here

EE 435 - Analog VLSI Circuit Design

For content related to this class, see EE435
Also see Dr. Geiger's class website

According to the 2009-2011 course catalog:

E E 435. Analog VLSI Circuit Design. (Cross-listed with Cpr E). (3-3) Cr. 4. S.Prereq: 324, 330, 332, and either E E 322 or Stat 330. Basic analog integrated circuit and system design including design space exploration, performance enhancement strategies, operational amplifiers, references, integrated filters, and data converters. Nonmajor graduate credit.

As of Spring 2009, EE435 was taught by Dr. Geiger with two graduate TA's coordinating the lab. Grades for the class are made up of about a dozen homeworks, two tests, and a laboratory section which includes a final project. The 2009 project assignment was the complete design and layout of a 12-bit DAC.

EE 465 - Digital VLSI Design

The following description is given for EE465 (aka CprE465) in the 2009-2011 course catalog:

 
E E 465. Digital VLSI Design. (Cross-listed with Cpr E). (3-3) Cr. 4. S.Prereq: E E 330. Digital design of integrated circuits employing very large scale integration (VLSI) methodologies. Technology considerations in design. High level hardware design languages, CMOS logic design styles, area-energy-delay design space characterization, datapath blocks: arithmetic and memory, architectures and systems on a chip (SOC) considerations. VLSI chip hardware design project. Nonmajor graduate credit.

Graduate EE Courses

According to the 2009-2011 catalog of courses, these classes are primarily for graduate students but are open to qualified undergraduates as well.

EE 501 - Analog and Mixed-Signal VLSI Circuit Design Techniques

E E 501. Analog and Mixed-Signal VLSI Circuit Design Techniques. (Cross-listed with Cpr E). (3-3) Cr. 4. F.Prereq: 435. Design techniques for analog and mixed-signal VLSI circuits. Amplifiers; operational amplifiers, transconductance amplifiers, finite gain amplifiers and current amplifiers. Linear building blocks; differential amplifiers, current mirrors, references, cascading and buffering. Performance characterization of linear integrated circuits; offset, noise, sensitivity and stability. Layout considerations, simulation, yield and modeling for high-performance linear integrated circuits.

As of Fall 2009, EE501 is taught by Dr. Degang Chen. In the past, grades have been based strongly on lab work, and particularly on two large projects.

EE 504x - Power Management for VLSI Systems

Electrical Engineering 504X. Power Management for SLSI Systems. Cr. 3-4. F. (Same as Cpr E 504X) Prereq: EE 435, or credit or registration in EE 501, or permission of instructor. Theory, design and applications of power management and regulation circuits (Linear and switching regulators, battery chargers, and reference circuits) including: Architectures, Performance metrics and characterization, Noise and stability analysis, Practical implementation and on-chip integration issues, design considerations for portable, wireless, and RF SoCs. On campus students must take the 4 credit version of this course.

EE504 was offered as an experimental course in Fall 2009 and taught by Dr. Fayed. It may be offered as an alternating-year course in the future. Emphasis was on DC-DC converters (both linear and switching), including performance parameters, circuit topology, and stability considerations. Coursework included two tests and several homework assignments. During the first few weeks of laboratory, students performed bench characterization of two catalog switching converters; the rest of the lab time was spent on a final project which entalied the complete design of a buck converter.

EE 505 - CMOS and BiCMOS Data Conversion Circuits

E E 505. CMOS and BiCMOS Data Conversion Circuits. (Cross-listed with Cpr E). (3-3) Cr. 4. Alt. S., offered 2010.Prereq: 501. Theory, design and applications of data conversion circuits (A/D and D/A converters) including: architectures, characterization, quantization effects, conversion algorithms, spectral performance, element matching, design for yield, and practical comparators, implementation issues.

EE 506x - Design of CMOS Phase-Locked Loops

Electrical Engineering 506X. Design of CMOS Phase-Locked Loops. Cr. 4. (Same as Cpr E 506X) Prereq: EE 435, 501 and instructor approval.  Neihart. This course will cover the analysis and design of phase-locked loops implemented in modern CMOS processes including: architectures, performance metrics, and characterization; noise and stability analysis; and design issues of phase-frequency detectors, change pumps, loop filters (passive and active), voltage controlled oscillators, and frequency dividers.

EE 507 - VLSI Communication Circuits

E E 507. VLSI Communication Circuits. (Cross-listed with Cpr E). (3-0) Cr. 3. Alt. S., offered 2011.Prereq: 330 or 501. Phase-locked loops, frequency synthesizers, clock and data recovery circuits, theory and implementation of adaptive filters, low-noise amplifiers, mixers, power amplifiers, transmitter and receiver architectures.

EE 508 - Filter Design & Applications

E E 508. Filter Design and Applications. (3-3) Cr. 4.Prereq: 501. Filter design concepts. Approximation and synthesis. Transformations. Continuous-time and discrete time filters. Discrete, active and integrated synthesis techniques.

EE 514

E E 514. Microwave Engineering. (Dual-listed with 414). (3-3) Cr. 4. F.Prereq: 230, 311. Principles, analyses, and instrumentation used in the microwave portion of the electromagnetic spectrum. Wave theory in relation to circuit parameters. S parameters, couplers, discontinuities, and microwave device equivalent circuits. RF amplifier design, microwave sources, optimum noise figure and maximum power designs. Microwave filters and oscillators.