News

• A preliminary version of the 6. and 7. chapter of the lecture notes is now available. We will inform you as soon as a final version is available.

Schedule

Type	Date				Location		Organizer
V4	Mon 10:00 – 11:30				AH II	Start: October, 17	E. Grädel
	Thu 10:00 – 11:30				AH V	Start: October, 20	E. Grädel
Ü2	Wed 14:00 – 15:30				4116	Start: October, 26	W. Pakusa, F. Abu Zaid

Coursework

• Homework 1 [pdf]
• Homework 2 [pdf]
• Homework 3 [pdf]
• Homework 4 [pdf]
• Homework 5 [pdf]
• Homework 6 [pdf]
• Homework 7 [pdf]
• Homework 8 [pdf]
• Homework 9 [pdf]
• Homework 10 [pdf]
• Homework 11 [pdf]
• Homework 12 [pdf]
• Homework 13 [pdf]

Lecture Notes

• Chapter 1: The Classical Decision Problem for FO [pdf] [pdf-2up]
• Chapter 2: Finite Model Property [pdf] [pdf-2up]
• Chapter 3: Descriptive Complexity [pdf] [pdf-2up]
• Chapter 4: LFP and Infinitary Logics [pdf] [pdf-2up]
• Chapter 5: Modal, Inflationary and Partial Fixed Points [pdf] [pdf-2up]
• Chapter 6: Fixed-point logic with counting [pdf] [pdf-2up]
• Chapter 7: Zero-one laws [pdf] [pdf-2up]

Content

• Decidable and undecidable theories
• Finite model property
• Descriptive complexity: logical characterisation of complexity classes
• Locality of first order logic, 0-1 laws
• Logics with transitive closure, fixed-point logics

Learning Objectives

• Understanding the relation between logical definability and algorithmic complexity (decidability of theories, evaluation algorithms, logical characterisations of complexity classes).
• Learning the methods from model theory and algorithmic complexity theory to analyse the expressive power and complexity of logical specifications on finite or finitely representable structures.
• Learning to work with fundamental logics of algorithmic model theory and in their application in concrete scenarios.

Literature

[1]	S. Abiteboul, R. Hull, and V. Vianu. Foundations of Databases. Addison-Wesley, 1995.
[2]	E. Börger, E. Grädel, and Y. Gurevich. The Classical Decision Problem. Springer-Verlag, 1997.
[3]	H. Ebbinghaus and J. Flum. Finite Model Theory. Springer, 1999.
[4]	E. Grädel, P. G. Kolaitis, L. Libkin, M. Marx, J. Spencer, M. Y. Vardi, Y. Venema, and S.Weinstein. Finite Model Theory and Its Applications. Springer-Verlag, 2007.
[5]	E. Grädel. Finite Model Theory and Descriptive Complexity. In Finite Model Theory and Its Applications, pp. 125–230. Springer-Verlag, 2007.
[6]	N. Immerman. Descriptive Complexity. Springer, 1999.
[7]	L. Libkin. Elements of Finite Model Theory. Springer, 2004.

Prerequisites

• Mathematical Logic

Classification

• Computermathematik (D)/Hauptstudium/Hauptfach Computermathematik
• Informatik (D)/Hauptstudium/Theoretische Informatik
• Informatik (D)/Anwendungsfächer/Mathematik
• Mathematik (D)/Hauptstudium/Reine Mathematik
• Informatik (M.A.)/Hauptstudium
• Mathematik (M.A.)
• Technik-Kommunikation (M.A.)/2. Hauptfach (Technisches Fach)/Grundlagen der Informatik/Hauptstudium/Spezialisierung Informatik
• Informatik (GYM+GS,SII)/Hauptstudium/C. Mathematische Methoden der Informatik
• Mathematik (B.Sc.)/Mathematik (WS)/5. Semester
• Mathematik (B.Sc.)/Mathematik (SS)/6. Semester
• Informatik (M.Sc.)/Theoretische Informatik
• Mathematik (M.Sc.)/Mathematik/Reine Mathematik
• Software Systems Engineering (M.Sc.)/Theoretical Foundations of Software Systems Engineering
• Software Systems Engineering (M.Sc.)/[MPO2010] Theoretical Computer Science

Assessment

• Bachelor- und Masterstudiengänge: solving 50% of the exercises and passing the oral exam (30 min)
• Diplomstudiengänge: exercise certificate upon solving 50% of the exercises and active participation at the exercises

Contact

Erich Grädel, Faried Abu Zaid, Wied Pakusa