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MATH 784: Recursion
Theory (Fall 2004)
Instructor:
Richard Shore
Meeting
Time & Room
MATH 784 will be a first course in the theory of computability.
We will assume some background in logic. MATH 681 or Computer Science
682 should be more than sufficient. There will be two possibilities for
the emphasis of the course.
We will begin with a brief discussion of the basic properties of a reasonable
model of computability: universal machines, the enumeration, s-m-n and
recursion theorems, r.e. (effectively or computably enumerable) sets and
the halting problem. Next will come the notions of relative computability,
the Turing jump operator and the arithmetical hierarchy.
In either version of the course there will be some development of construction
procedures for non-r.e. sets including the Kleene-Post finite extension
method (really Cohen forcing in arithmetic) and minimal degree constrictions
by forcing with trees (perfect set forcing).
From that point on, the two alternatives diverge. One is to concentrate
on the recursively (computably) enumerable sets and degrees. The text
would then be Recursively Enumerable Sets and Degrees by R. I.
Soare (Springer-Verlag).The heart of the course, in this case will be
the development of various kinds of priority arguments for the construction
of r.e. sets including finite and infinite injury as well as tree arguments.
We will use these methods to analyze the structure of the (Turing) degrees
of r.e. sets and something of their set theoretic structure as well. Connections
between degree theoretic and other properties such as types of approximations,
rates of growth and complexity of definition will be considered.
The second alternative (especially likely if some who have taken the first
version already show up) is to concentrate on the global structure of
the degrees and of important substructures other than the r.e. degrees
such as the degrees below 0' and the degrees of the arithmetic sets. The
primary techniques will be forcing arguments. Relations with rates of
growth and the jump hierarchy will be explored. We will get to some results
about the complexity of theories of these structures such as that the
theories of the degrees and the degrees below 0' are of the same complexity
as second order arithmetic and first order arithmetic, respectively. For
this alternative the text would probably be Degrees of Unsolvability
by M. Lerman.
Last modified:
March 25, 2004
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