Course pages 2019–20

**Subsections**

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Computation Theory

*Lecturer: Professor A.M. Pitts*

*No. of lectures:* 12

*Suggested hours of supervisions:* 3

*Prerequisite course: Discrete Mathematics*

*This course is a prerequisite for Complexity Theory (Part IB).*

### Aims

The aim of this course is to introduce several apparently different formalisations of the informal notion of algorithm; to show that they are equivalent; and to use them to demonstrate that there are uncomputable functions and algorithmically undecidable problems.

### Lectures

**Introduction: algorithmically undecidable problems.**Decision problems. The informal notion of algorithm, or effective procedure. Examples of algorithmically undecidable problems. [1 lecture]**Register machines.**Definition and examples; graphical notation. Register machine computable functions. Doing arithmetic with register machines. [1 lecture]**Universal register machine.**Natural number encoding of pairs and lists. Coding register machine programs as numbers. Specification and implementation of a universal register machine. [2 lectures]**Undecidability of the halting problem.**Statement and proof. Example of an uncomputable partial function. Decidable sets of numbers; examples of undecidable sets of numbers. [1 lecture]**Turing machines.**Informal description. Definition and examples. Turing computable functions. Equivalence of register machine computability and Turing computability. The Church-Turing Thesis. [2 lectures]**Primitive and partial recursive functions.**Definition and examples. Existence of a recursive, but not primitive recursive function. A partial function is partial recursive if and only if it is computable. [2 lectures]**Lambda-Calculus.**Alpha and beta conversion. Normalization. Encoding data. Writing recursive functions in the lambda-calculus. The relationship between computable functions and lambda-definable functions. [3 lectures]

### Objectives

At the end of the course students should

- be familiar with the register machine, Turing machine and lambda-calculus models of computability;
- understand the notion of coding programs as data, and of a universal machine;
- be able to use diagonalisation to prove the undecidability of the Halting Problem;
- understand the mathematical notion of partial recursive function and its relationship to computability.

### Recommended reading

* Hopcroft, J.E., Motwani, R. & Ullman, J.D. (2001). *Introduction to automata theory, languages, and computation*. Addison-Wesley (2nd ed.).

* Hindley, J.R. & Seldin, J.P. (2008). *Lambda-calculus and combinators, an introduction*. Cambridge University Press (2nd ed.).

Cutland, N.J. (1980). *Computability: an introduction to recursive function theory*. Cambridge University Press.

Davis, M.D., Sigal, R. & Weyuker, E.J. (1994). *Computability, complexity and languages*. Academic Press (2nd ed.).

Sudkamp, T.A. (2005). *Languages and machines*. Addison-Wesley (3rd ed.).