Lectures and exercise class on Thursday 15.10. and Friday 1610. cancelled (lecturer still ill). Also the exam is postponed - see your mail for details.
Teacher: Åsa Hirvonen
Scope: 5 cr
Type: Advanced studies
Teaching: Period I, lectures Mon 10-12, Thu 14-16, exercise class Fri 10-12.
Topics: We look at methods from logic useful in other areas of mathematics, such as basic cardinal arithmetic, transfinite induction, ultraproducts and, time permitting, Martins Axiom.
Prerequisites: The course does not require previous knowledge of logic, but some 'mathematical routine' is assumed. (the course is primarily aimed at master's and graduate students)
Weeks 36-42, Monday 10-12 and Thursday 14-16 in room B120. In addition, two hours of exercise classes per week.
There will be a final exam of the course on Wednesday 21.10. at 12-14.30 in the large auditorium (A111).
The deadline for the project is 1.11.2015.
The course is evaluated based on the exam (max. 24p), a project work (max 12p) and the exercises (max 6p). The project can be rather freely chosen as long as it relates to the theme of using logical tools in mathematics. It should be around 3-4 typed pages long. Examples of suitable projects are
Ordinals (corrected 3.9.)
Transfinite induction and recursion
Appendix: ZFC axioms
Lecture notes will appear here during the course. For a more thorough treatment (or a sneak preview of the subjects) you can consult e.g.
H. Enderton: Elements of set theory, Academic press. (intro to set theory; thorough intro to ordinals and cardinals)
K. Kunen: Set Theory An Introduction to Independence Proofs, Elsevier. (more set theory; cardinal arithmetic and Martin's axiom)
C. C. Chang, H. J. Keisler: Model Theory, Elsevier. (model theory; ultraproducts, also has an intro to ordinals and cardinals in the appendix)
Did you forget to register? What to do?
3.9. Transfinite induction
7.9. Transfinite recursion, cardinality
10.9. Cardinal arithmetic
14.9. more on cardinal arithmetic; use in induction
21.9. stuctures and filters
28.9. Los's theorem
1.10. Applications of Los's theorem (compactness, non-axiomatizability)
5.10. Martin's Axiom
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