ENEE 627(721): Information Theory

Course Goals:

An analytical framework for modeling and evaluating point-to-point communication systems is developed. The key concepts of information content of a signal source and information capacity of a transmission medium are precisely defined, and their relationship to data compression algorithms and error control codes is examined in detail. The course aims to instil an appreciation for the fundamental capabilities and limitations of information transmission schemes; and to provide the mathematical tools for applying these ideas to a broad class of communication systems.

Course Prerequisite:

ENEE 620

Topic Prerequisite:

Required topics from probability/random processes are: calculus of distributions including the multivariate Gaussian, the Chebyshev and Jensen inequalities, conditional probability and independence, sequences of independent random variables and laws of large numbers, elements of Markov chains and stationary processes. It is important that students are comfortable with fundamentals of mathematical analysis or advanced calculus (e.g., concepts of continuity, convexity, optimization via Lagrange multipliers), and some linear algebra (up to diagonalization of square symmetric matrices).

References:

1. T.M. Cover and J.A. Thomas, Elements of Information Theory, John Wiley (1991).
2. R.G. Gallager, Information Theory and Reliable Communication, Wiley (1968). for Discrete Memoryless Systems, Academic Press (1981).
3. R.J. McEliece, The Theory of Information and Coding, Addison-Wesley (1977).

Core Topics:

• Measures of information: entropy, relative entropy and mutual information. Basic inequalities (Jensen, log-sum, Fano, data processing theorem).
• Data compression by fixed-to-variable-length codes: Unique decodability and the prefix condition. Kraft inequality, relationship of average codeword length to source entropy. Examples of coding techniques: Huffman, Shannon-Fano-Elias, Lempel-Ziv, universal.
• Data compression of discrete memoryless sources by fixed-to-fixed-length codes. Typicality and the asymptotic equi-partition property. Interpretation of entropy of this context.
• Entropy rate of stationary sources. Stationary Markov sources: entropy rate and data compression.
• Discrete memoryless channels. Definition of capacity and its computation.
• Communication over discrete channels: the channel coding theorem and the physical significance of capacity. Feedback in memoryless channels. The joint source-channel coding theorem. Elementary parity-check codes; maximum likelihood decoding.
• Measures of information for sources with continuous range.
• Discrete-time Gaussian channels and their capacity. Simple and parallel configurations. White and colored noise. Extension to band-limited waveform channels.
• Vector quantization of a discrete-time memoryless source under a fidelity criterion. Definition of the rate distortion function and its computation in simple cases. The rate distortion theorem.

Optional Topics:

• Arithmetic coding (CT: 5.8).
• Bandlimited Gaussian channels (CT: 10.3).
• Maximum entropy techniques (CT: 11).
• Asymptotics of hypothesis testing (CT: 12.7-12.9).
• Computation of channel capacity and the rate distortion function.
• Multiuser information theory (CT: 14).