Timeroom: Spring 2025

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (04) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 51498

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: STAFF

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (05) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 51499

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: John LaCourse

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (06) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 51500

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Kent Chamberlin

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (07) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 52682

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Se Young Yoon

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (08) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 53013

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Nicholas Kirsch

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (09) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 53014

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Edward Song

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (10) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 53064

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Dean Sullivan

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 899 (11) - Master's Thesis

Master's Thesis

Credits: 1.0 to 6.0
Term: Spring 2025 - Full Term - Grad Thesis (01/21/2025 - 05/05/2025)
Grade Mode: Graduate Credit/Fail grading

Class Size: 5
CRN: 53512

Master's Thesis.

Department Approval Required. Contact Academic Department for permission then register through Webcat.

Repeat Rule: May be repeated for a maximum of 6 credits.

Instructors: Diliang Chen

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025		Hours Arranged	TBA

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 941 (01) - Digital Signal Processing

Digital Signal Processing

Credits: 3.0
Term: Spring 2025 - Full Term (01/21/2025 - 05/05/2025)
Grade Mode: Letter Grading

Class Size: 15
CRN: 56487

Discrete-time stochastic signals, signal modeling, parameter estimation, optimal filtering and decision making, with application to adaptive filters, echo cancellation, channel equalization and parametric spectral estimation. Requires prior coursework in discrete-time LTI systems, analysis and design of recursive and non-recursive linear digital filters, and Fournier based spectral estimation.

Instructors: Wayne Smith

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025	MWF	11:10am - 12:00pm	KING N129

Click to see: Booklist

Durham Engineering&Physical Sciences :: Electrical&Comp Engineering

ECE 992 (01) - Advanced Topics

Advanced Topics

Credits: 1.0 to 4.0
Term: Spring 2025 - Full Term (01/21/2025 - 05/05/2025)
Grade Mode: Letter Grading

Class Size: 15
CRN: 56488

Special course covering advanced topics in electrical and computer engineering. Refer to section description for details about the covered topics. Course may be repeated, but not in duplicate subjects.

Instructors: Edward Song

Start Date	End Date	Days	Time	Location
1/21/2025	5/5/2025	TR	2:10pm - 3:30pm	KING N345

Additional Course Details:

Title: Microelectromechanical Systems (MEMS) and their applications

Description: The objective of this course is to introduce to the students the topics of miniaturized (micro- and nanoscale) systems and devices for various applications in the areas of sensors and actuators. This course will discuss the fundamentals of micro- and nanoscale systems and how they differ from the macroscopic systems. Modeling and design challenges will be discussed from the physics, engineering and the material science perspectives. Topics covered will include semiconductor materials and devices, techniques of microfabrication and photolithography, commercial MEMS devices, microfluidics and lab-on-a-chip systems, biosensors, microactuators, and other related topics.