ECE 528:Introduction to Random Processes in ECE

Syllabus PDf: ECE 528 Syllabus

Course Number	ECE 528
Prerequisites	Prerequisites: ECE 220 and STAT 346 (all with grade of C or better), or permission of instructor.
Instructor:	Bijan Jabbari, Professor
Semester:	Fall 2019
Lecture Time:	Monday 4:30-7:10pm
Location:	Innovation Hall 133
Office:	Eng. Bldg. Room 3232
Office Phone:	703-993-1618
Email:	bjabbari@gmu.edu
Web:	http://cnl.gmu.edu/
Office Hours:	Wednesday 3:00-4:15 pm, other times by appointment
Teaching Assistant:	Zheng Wang email: zwang23@gmu.edu Recitations: Wednesday 7:20 pm-8:35 pm
Office Hours:	Monday: 7:30 pm-9:30 pm & Thursday 4:30 pm-6:30 pm in Rm ENGR 3204 Grader: Snehashis Paul (email: spaul20@masonlive.gmu.edu)
Administrative Assistant:	N/A
Course Description	Probability and random processes are fundamental to communications, control, signal processing, and computer networks. Provides basic theory and important applications. Topics include probability concepts and axioms; stationarity and ergodicity; random variables and their functions; vectors; expectation and variance; conditional expectation; moment-generating and characteristic functions; random processes such as white noise and Gaussian; autocorrelation and power spectral density; linear filtering of random processes, and basic ideas of estimation and detection.

Course Outline

• Probability Models in ECE
• Review of probability: set theory, basic concepts, probability spaces, conditional probability, Bayes’ Rule, independence, Borel Fields, Generation of random numbers
• Discrete Random Variables: Notion of Random Variables, Probability Mass Functions (PMF), Expected Value and Moments, Important Discrete Random Variables, Generation of Discrete Random Variables
• General Random Variables (Single Variable): Cumulative Distribution Functions (CDF), Probability Density Functions (PDF), functions of random variables, expectations and characteristic function, Markov and ChebyShev inequalities
• Pairs of Random Variables: joint and marginal distributions, conditional distributions and independence, functions of two random variables, Expectations and correlations, pairs of jointly Gaussian Random Variables, generating jointly Gaussian Random Variables
• Random vectors: Functions of several random variables expected value of vector random variables, jointly Gaussian Random vectors, convergence of random sequences
• Sums of random variables and long-term averages: the sample mean and the Laws of Large Numbers, the Central Limit Theorem
• Stochastic Processes: Basic concepts, Covariance, correlation, and stationarity, Gaussian processes and Brownian motion, Poisson and related processes, Power spectral density, Stochastic processes and linear systems
• Markov Processes and Markov Chains

Textbooks and References:

• Probability, Statistics, and Random Processes, 3rd Edition, by Alberto Leon-Garcia, Pearson Prentice Hall, 2008.
• D. P. Bertsekas and J. N. Tsitsiklis, Introduction to Probability. Athena Scientific, Belmont, MA, 2nd Edition, 2008. See http://www.athenasc.com/probbook.html
  

Grading:

There will be weekly assignments, one Mid-term exam, and a Final exam. They will count towards the grade as follows:

• Homework 10%
• Mid-term 40% (on October 21)
• Final Exam 50% (up to 2 hours and 30 minutes)