BSM Set Theory — SET 2016F.
Instructor: Dr. Lajos SOUKUP
Classes: Monday 12
15-13, 13
15-14,
Wednesday 12
15-13, 13
15-14,
Website of the course:
http://www.renyi.hu/~soukup/set_16f.php
Text: The course is based on printed handouts
Books:
A. Shen, and N. K. Vereshchagin,
Basic Set Theory, AMS Student Mathematical Library 17,
P. Halmos: Naive Set Theory
P. Hamburger, A. Hajnal: Set Theory
K. Ciesielski: Set Theory for the Working Mathematician
Prerequisite: Some familiarity with "higher" mathematics.
No specific knowledge is expected.
Grading:
Homework assignments: 40%, midterm exam: 20%, final exam: 40%.
12 homework assigments, the best 10 count.
Extra hw problems for extra credits.
A: 80-100%, B: 60-79%, C: 50-59%, D: 40-49%
Course description
Set Theory is the study of infinity.
- we learn how to use set theory as a powerful tool in algebra,
analysis, combinatorics, and even in geometry;
- we study how to build up a rich mathematical theory from simple axioms;
- we get an insight how set theory can serve as the foundation of mathematics.
Topics:
- Classical set theory: "By a set we are to understand any collection onto a whole of definite and separate objects of out intuition or our thought." (Cantor)
Basic principles:
- Extensionality : Two sets are equal if and only if they have the same elements.
-
General principle of comprehension of Frege :
If \(P(x)\) is a property, then there is a set \(Y=\{x:P(x)\}\) of all elements
having property P.
- Countable and uncountable sets. A sample problem: any family of disjoint letters T on the plain is countable.
- Inductive constructions.
A sample problem: "A flea is moving on the integer points of the real line
by making identical jumps every seconds.
You can check one integer every seconds.
Catch the flea!"
- Ramsey Theory. How to prove the finite Ramsey theorem from the infinite one? König lemma: an infinite, locally finite tree should contain infinite paths.
Applications: a countable graph is n-colorable if and only if its every finite subgraph is n-colorable.
-
Cardinalities. Comparing the sizes of infinite sets.
Cardinalities. Basic operation on cardinalities.
Elementary properties of cardinal numbers.
Cantor-Bernstein 'Sandwich' Theorem and its consequences, \(|A| < |P(A)|\).
- More on cardinal numbers: Calculations with cardinals, \(2^{\aleph_0}= \mathfrak c\) (the
cardinality of the real line), there are \(\mathfrak c\) many continuous functions. Infinite operations on cardinals: \(1\cdot 2
\cdot 3 \cdots = \mathfrak c\). Konig's Inequality.
- The crucial notion of "well-ordering", ordinal numbers: Definition, properties, calculations with
ordinals.
- The heart of the matter: Zorn lemma and the Well Ordering Theorem of Zermelo: we can enumerate
everything, the Theorem of Transfinite
Induction and Recursion, the Fundamental Theorem of Cardinal Arithmetic: \(\kappa^2=\kappa\) for every cardinal
\(\kappa\).
- Applications (as many as time permits):
Contradictions in mathematics?
The comprehension principle of Frege leads to contradictions.
- Russel's Paradox:
Does the set of all those sets that do not contain
themselves contain itself?
- Berry's Paradox:
"The least integer not nameable in fewer than nineteen syllables" is itself a name consisting of eighteen syllables.
The solution: Axiomatic approach (without tears):
Mathematical logic in a nutshell. Variables, terms and formulas.
The language of set-theory. Zermelo-Fraenkel Axioms.
Basic Set Theory from the Axioms: Ordered pairs. Basic operations on
sets. Relations and functions. Cartesian product. Partial- and
linear-order relations. Natural numbers. Ordinals
A glimpse of independence proofs: How can you prove that you can not prove something?
Contemporary Axiomatic Set Theory: extensions of the classical Zermelo-Fraenkel Set Theory with new axioms