ECE 398

Spring 2022 All Classes

All Classes

Credit: 0 TO 4 hours.

Subject offerings of new and developing areas of knowledge in electrical and computer engineering intended to augment the existing curriculum. See Class Schedule or departmental course information for topics and prerequisites.

Approved for both letter and S/U grading. May be repeated in the same or separate terms if topics vary.

ECE 398 class schedule data for spring 2022
CRN Type Section Time Day Location Instructor Section Details
54185
Lecture
AS
3:30PM -4:50PM
TR
2017 Electrical & Computer Eng Bldg
Han, A
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
3 hours
Section Title:
Progm Mthds - Machine Learning
Section Info:
Programming Methods for Machine Learning. In this course you will learn how to use auto-differentiation tools like PyTorch, how to leverage them for basic machine learning algorithms (linear regression, logistic regression, deep nets, k-means clustering), and how to extend them with custom methods to fit your needs. Auto-differentiation tools are one of the most important tools for data analysis and a solid understanding is increasingly important in many disciplines. In contrast to existing courses which focus on algorithmic and theoretical aspects, here we focus on studying material that permits to deploy auto-diff tools to your area of interest. Prerequisites: ECE 220 and (Math 286 or Math 257).
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
44435
Online Lecture
ASO
3:30PM -4:50PM
TR
n.a.
Han, A
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
3 hours
Section Title:
Progm Mthds - Machine Learning
Section Info:
Programming Methods for Machine Learning. In this course you will learn how to use auto-differentiation tools like PyTorch, how to leverage them for basic machine learning algorithms (linear regression, logistic regression, deep nets, k-means clustering), and how to extend them with custom methods to fit your needs. Auto-differentiation tools are one of the most important tools for data analysis and a solid understanding is increasingly important in many disciplines. In contrast to existing courses which focus on algorithmic and theoretical aspects, here we focus on studying material that permits to deploy auto-diff tools to your area of interest. Prerequisites: ECE 220 and (Math 286 or Math 257).
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
48831
Lecture
EC
1:00PM -1:50PM
MWF
2015 Electrical & Computer Eng Bldg
Chitambar, E
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
3 hours
Section Title:
Quantum Systems I
Section Info:
This course introduces the basic principles of quantum mechanics and its applications in modern electronics and quantum information science. The course covers three main topics: (i) the mathematical formalism of quantum mechanics and solutions to Schrödinger’s equation, (ii) semi-classical theory of light-matter interaction and quantum control, and (iii) qubits and principles of quantum information processing. Sub-topics studied in detail include finite versus infinite-dimensional quantum systems, bra/ket notation, quantum harmonic oscillator, crystalline structures and semi-conductors, atomic absorption and emission, Rabi oscillations, atomic qubits and the Bloch sphere, quantum entanglement, quantum gates and algorithms, quantum teleportation, and quantum key distribution. A primary goal of this course is to prepare the student for higher-level courses in quantum information science. Prerequisites: PHYS 214, ECE 329
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
51057
Lecture
GG
9:30AM -10:50AM
TR
1015 Electrical & Computer Eng Bldg
Gross, G
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
3 hours
Section Title:
Electric Vehicles (EVs)
Section Info:
Electric vehicles (EVs) have the potential to drastically reduce the global CO2 footprint to effectively address climate change issues. Massive EV adoption requires the establishment of an EV charging infrastructure (EVCI) to supply the energy needs of EV owners/users. The course examines technical, economic, environmental and policy aspects of EVs and the required EVCI. A basic physics discussion of rolling vehicles serves to determine the power and energy requirements and their implications for energy storage and transfer. The course covers the EV architectures and configurations, as well as the detailed description of the deployment of motors and generators, drives for traction applications, batteries and their management and the EV-grid nexus. The description of the various technologies and approaches deployed in EV design and operations is augmented by the detailed examination of the energy efficiency and environmental benefits of EVs. The application of power electronics to EV charging is accompanied by a detailed examination of the EVCI and its interactions with the existing infrastructures. Throughout the course there is a strong focus on the efficient utilization of energy in an environmentally sensitive manner to emphasize the significant role of EVs and EVCI in the energy transition. Prerequisites: Junior standing in Engineering; ECE 210 or 205
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
44437
Laboratory
RI1
12:00PM -12:50PM
R
3014 Electrical & Computer Eng Bldg
Ilie, R
Zhang, C
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
1 hours
Section Title:
Fields and Waves VR Lab
Section Info:
This course is designed to be taken concurrently with ECE 329 “Fields and waves I”, to strengthen the students' understanding of the concepts in electromagnetism and their applications, through a combination of customized Virtual Reality (VR) experiences and computer simulations using Mathematica. Topics include static and quasi-static electric fields, polarization, static and quasi-static magnetic fields, dynamic fields and Maxwell’s equations, wave solutions of Maxwell's equations in free space and homogeneous media, time- and frequency-domain analysis of waves in transmission line circuits, and Smith Chart analysis.
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
44438
Laboratory
RI2
1:00PM -1:50PM
R
3014 Electrical & Computer Eng Bldg
Ilie, R
Zhang, C
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
1 hours
Section Title:
Fields and Waves VR Lab
Section Info:
This course is designed to be taken concurrently with ECE 329 “Fields and waves I”, to strengthen the students' understanding of the concepts in electromagnetism and their applications, through a combination of customized Virtual Reality (VR) experiences and computer simulations using Mathematica. Topics include static and quasi-static electric fields, polarization, static and quasi-static magnetic fields, dynamic fields and Maxwell’s equations, wave solutions of Maxwell's equations in free space and homogeneous media, time- and frequency-domain analysis of waves in transmission line circuits, and Smith Chart analysis.
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
44473
Laboratory
RI3
2:00PM -2:50PM
R
3014 Electrical & Computer Eng Bldg
Chen, H
Ilie, R
Zhang, C
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
1 hours
Section Title:
Fields and Waves VR Lab
Section Info:
This course is designed to be taken concurrently with ECE 329 “Fields and waves I”, to strengthen the students' understanding of the concepts in electromagnetism and their applications, through a combination of customized Virtual Reality (VR) experiences and computer simulations using Mathematica. Topics include static and quasi-static electric fields, polarization, static and quasi-static magnetic fields, dynamic fields and Maxwell’s equations, wave solutions of Maxwell's equations in free space and homogeneous media, time- and frequency-domain analysis of waves in transmission line circuits, and Smith Chart analysis.
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
40557
Laboratory
RI4
3:00PM -3:50PM
R
3014 Electrical & Computer Eng Bldg
Chen, H
Ilie, R
Zhang, C
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
1 hours
Section Title:
Fields and Waves VR Lab
Section Info:
This course is designed to be taken concurrently with ECE 329 “Fields and waves I”, to strengthen the students' understanding of the concepts in electromagnetism and their applications, through a combination of customized Virtual Reality (VR) experiences and computer simulations using Mathematica. Topics include static and quasi-static electric fields, polarization, static and quasi-static magnetic fields, dynamic fields and Maxwell’s equations, wave solutions of Maxwell's equations in free space and homogeneous media, time- and frequency-domain analysis of waves in transmission line circuits, and Smith Chart analysis.
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
51072
Laboratory
RI5
4:00PM -4:50PM
R
3014 Electrical & Computer Eng Bldg
Chen, H
Ilie, R
Zhang, C
Part of Term:
1
Date Range:
01/18/22-05/04/22
Credit:
1 hours
Section Info:
This course is designed to be taken concurrently with ECE 329 “Fields and waves I”, to strengthen the students' understanding of the concepts in electromagnetism and their applications, through a combination of customized Virtual Reality (VR) experiences and computer simulations using Mathematica. Topics include static and quasi-static electric fields, polarization, static and quasi-static magnetic fields, dynamic fields and Maxwell’s equations, wave solutions of Maxwell's equations in free space and homogeneous media, time- and frequency-domain analysis of waves in transmission line circuits, and Smith Chart analysis.
Restriction(s):
Not intended for Graduate - Urbana-Champaign.
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