FPF:UINK118 Computability and Complexity T - Course Information

UINK118 Computability and Complexity Theory

Extent and Intensity

2/2/0. 6 credit(s). Type of Completion: zk (examination).

Teacher(s)

doc. Ing. Petr Sosík, Dr. (lecturer)
RNDr. Miroslav Langer, Ph.D. (seminar tutor)

Guaranteed by

doc. Ing. Petr Sosík, Dr.
Institute of Computer Science – Faculty of Philosophy and Science in Opava

Prerequisites (in Czech)

UIAI019 Základy teoretické informatiky II || UIAI219 Základy teoretické informatiky II || UIBUC09 Theory of languages and automa || UINK106 Theory of languages and automa || UIN1006 Theory of Languages and Automa

Course Enrolment Limitations

The course is also offered to the students of the fields other than those the course is directly associated with.

fields of study / plans the course is directly associated with

• Computer Science and Technology (programme FPF, B1801 Inf)

Course objectives

Abstract machine models of computation - the Turing Machine and the RAM - are introduced. The concept of machine computability is built on their basis. The existence of non-computable problems is proven and their examples given. In the second part of the course, asymptotical time and space complexity of algorithms is introduced. This allows to describe the consumption of time and space of algorithms without fixing to any particular computing machine. Elementary complexity classes and their properties are studied, with special emphasis on the classes P and NP.

Syllabus

• 1. Characterization of mechanical computing, the Turing - Church thesis.
  2. Turing Machine and its variants, universal Turing machine.
  3. Recursive and recursively enumerate sets, the diagonalization method.
  4. Decidable and undecidable problems, the reduction method.
  5. Rice Theorem, practical applications of the computability theory.
  6. Evaluation of time an space consumption of computer algorithms.
  7. Classes DTIME and DSPACE. Non-deterministic Turing machine, classes NTIME and NSPACE.
  8. The RAM machine and its computing power. Relations of the Turing Machine and RAM.
  9. Linear sped-up theorem and tape compression theorem, elementary complexity classes.
  10. Time and space hierarchy.
  11. Relations of time and space complexity classes.
  12. Reducibility and completeness, NP-complete problems.
  13. Complexity of probabilistic algorithms.

Literature

recommended literature
• Arora, S., Barak, B. Complexity Theory: A Modern Approach. Cambridge University Press, 2009. info
• Kozen, D. Theory of Computation. Berlin: Springer-Verlag, 2006. info
• Hopcroft, J. E., Motwani, R., Ullman, J. D. Introduction to Automata Theory, Languages and Computation. Upper Saddle River: Pearson Education Inc.,, 2003. info
• Wiedermann, J. Teorie složitosti sekvenčních a paralelních výpočtů. Online studijní text. ÚI AV ČR, Praha, 2003. info
• Sosík, P. Teorie vyčíslitelnosti. Online studijní text. Opava: FPF SU, 1996. info
• Černá, I. Úvod do teórie zložitosti. Brno: FI MU, 1993. info

Assessment methods

Grade

Language of instruction

Czech

Further comments (probably available only in Czech)

The course can also be completed outside the examination period.

Teacher's information

Course-credit:
- construction of a Turing machine due to an individual assignment
- at least 50% evaluation of written tests in the seminar classes
Exam:
- at least 50% evaluation of the written final test including the whole course topics

• Enrolment Statistics (Winter 2013, recent)
  
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