Short Description:

This course is the first course on statistical signal processing in the graduate curriculum of Department of Electrical and Electronics Engineering, Middle East Technical University (METU). Topics covered in this course are random vectors, random processes, stationary random processes, wide sense stationary processes and their processing with LTI systems with applications in optimal filtering, smoothing and prediction. A major goal is to introduce the concept of mean square error (MSE) optimal processing of random signals by LTI systems.

For the processing of the random signals, it is assumed that some statistical information about the signal of interest and distortion is known. By utilizing this information, MSE optimal LTI filters (Wiener filters) are designed. This forms the processing part of the course. The estimation of the statistical information to construct Wiener filters forms the modeling part of the course. In the modeling part, we examine AR, MA, ARMA models for random signals and give a brief discussion of Pade, Prony methods for the deterministic modeling. Among other topics of importance are decorrelating transforms (whitening), spectral factorization, Karhunen-Loeve transform

This course is a natural pre-requisite (not a formal one) to EE5506 Advanced Statistical Signal Processing. The estimation theory topics in EE 503 is mostly limited to the moment description of random processes which forms a special, but the most important, case of EE 5506.

Outline of Topics:

1. Review
1. Basics of Mathematical Deduction
   1. Necessary, Sufficient Conditions
   2. Proofs via contradiction, contraposition
2. Basics of Linear Algebra
   1. Linear independence of vectors (points in linear space)
   2. Range and Null space of the combination process
   3. Projection to Range/Null Space (orthogonality principle)
   4. Positive Definite Matrices
3. Basics of Probability
   1. Probability as a mapping, axioms, conditional probability
   2. Expectation, law of large numbers
   3. Moments, moment generating function


2. Random Processes
   1. Random variables, random vectors (or a sequence of random variables), moment descriptions (mean, variance, correlation), decorrelating transforms
   2. Random processes, stationarity, wide Sense Stationarity (WSS), power spectral density, spectral factorization, linear time invariant processing of WSS random processes, ergodicity
   
   Ref: Therrien, Hayes, Papoulis, Ross
    
3. Signal Modeling
   1. LS methods, Pade, Prony (Deterministic methods)
   2. AR, MA, ARMA Processes (Stochastic approach), Yule-Walker Equations, Non-linear set of equations for MA system fit
   3. Harmonic Processes
   
   Ref: Hayes, Papoulis
    
4. Estimation Theory Topics
   1. Random parameter estimation
      1. Cost function, loss function, square error, absolute error
      2. Conditional mean (regression line) as the minimum mean square error (MSE) estimator, orthogonality properties
      3. Linear minimum mean square error (LMMSE) estimators, orthogonality principle
      4. Regression line, orthogonality
      5. FIR, IIR, Causal–IIR Wiener filters
      6. Linear Prediction, backward prediction
      7. Random vector LMMSE estimation (multiple parameter)
   2. Non-random parameter estimation
      1. Maximum likelihood method
      2. Best Linear Unbiased Estimator (BLUE)
      3. Discussion of linear estimators for the linear observation model y=Ax+n
   3. Karhunen – Loeve Transform
   
   Ref: Therrien, Hayes
    

[Hayes]: M. H. Hayes, Statistical Signal Processing and Modeling, Wiley, New York, NY, 1996.

[Therrien]: C. W. Therrien, Discrete random signals and statistical signal processing, Prentice Hall, c1992.

[Papoulis]: A. Papoulis, Probability, Random Variables, and Stochastic Processes, 3rd edition, McGraw Hill, 1991.

[Ross]: S. M. Ross, Introduction to probability models, 7th ed. Harcourt Academic Press, 2000.