Adaptive Information Processing

I Information and automata.- 1 Communication theory.- 1.1 Communication systems.- 1.2 Information and entropy.- 1.3 Channel capacity.- Exercises.- 2 Coding information.- 2.1 Efficient codes.- 2.2 Error correcting codes.- Exercises.- 3 Finite automata.- 3.1 Modular nets.- 3.2 State transition functions.- 3.3 Regular expressions.- Exercises.- 4 Turing machines.- 4.1 Turing and Wang formulations.- 4.2 Universal Turing machines.- 4.3 Computability and unsolvability.- 4.4 Grammars and machines.- Exercises.- 5 Cellular automata.- 5.1 Von Neumann’s machines.- 5.2 Arbib’s machine.- Exercises.- II Biological information processing.- 6 Biochemical coding and control.- 6.1 Biological cells.- 6.2 Informational macromolecules.- 6.3 The genetic code.- 6.4 Biochemical control processes.- Exercises.- 7 Genetic information transmission.- 7.1 Recombination in viruses and bacteria.- 7.2 Recombination in higher organisms.- 13 Populations and evolution.- Exercises.- 8 Neural information transmission.- 8.1 Neural architecture.- 8.2 Neurons and synapses.- 8.3 Neural signals 101 Bibliography.- Exercises.- 9 Neural input-output.- 9.1 Reflex and motor systems.- 9.2 Sensory systems.- 9.3 The visual system.- Exercises.- 10 Computer simulation models.- 10.1 Kabrisky’s vision model.- 10.2 Finley’s cell assembly model.- 10.3 Weinberg’s E. coli model.- Exercises.- III Artificial intelligence.- 11 Pattern recognition.- 11.1 Perceptrons.- 11.2 A feature detection system.- 11.3 Scene analysis.- Exercises.- 12 Game playing.- 12.1 Game trees.- 12.2 The Samuel checker player.- 12.3 Chess playing.- Exercises.- 13 Theorem proving.- 13.1 Logic systems.- 13.2 The Logic Theorist.- 13.3 Resolution theorem proving.- Exercises.- 14 Problem solving.- 14.1 Problem representations.- 14.2 The General Problem Solver.- 14.3 Other problem solving programs.- Exercises.- 15 Natural language processing.- 15.1 Linguistics.- 15.2 The work of Quillian.- 15.3 The work of Winograd.- 15.4 The work of Schank.- Exercises.