Difference between revisions of "MATxxx"

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(Created page with "1. Propositional logic: Axioms and Rules of Inference. Boolean Algebras. Limitations of propositional logic: Informal introduction to quantifiers and syllogisms. 2. Predicate...")
 
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1. Propositional logic: Axioms and Rules of Inference. Boolean Algebras. Limitations of propositional logic: Informal introduction to quantifiers and syllogisms.
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(1) Relations: Cartesian products, relations, properties of relations, equivalence relations and partitions. (2) Order relations: Partially ordered sets, totally ordered sets, extreme elements (maximum, minimum, maximal and minimal elements), well-ordered sets, maximality principles, Zorn's Lemma, lattices, boolean algebras, circuit design. (3) Graphs: Euler and Hamiltonian paths and circuits, matching, graph coloring, Ramsey’s theorem, trees and searching. (4) Binary operations: Groups and semigroups, products and quotients of groups, other algebraic structures.
2. Predicate Logic: Existential and universal quantification, free variables and substitutions. Discussion of the various axiomatic systems for first-order logic (including axioms and rules of inference). The power and the limitations of axiomatic systems for logic: Informal discussion of the completeness and incompleteness theorems.
 
3. Sets: Operations on sets. Correspondence between finitary set operations and propositional logic. Correspondence between infinitary operations and quantifiers. The power and limitations of the language of set theory: Informal discussion of the set-theoretic paradoxes and the need for axiomatic systems for set theory.
 
4. Relations: Properties of relations. Special relations: Equivalence relations, partially ordered sets, totally ordered sets.
 
5. Functions: Operations of functions, direct image and inverse image.
 
6. Well-ordered sets: Correspondence between well-ordering relations and induction. Correspondence between well-ordering relations and choice functions.
 
7. Introduction to computability. Classical models of computation (recursive functions, and Turing models). Limitations of computation (the Halting Problem, the busy beaver problem, fast-growing functions). Contemporary models of computation: Digital vs analog vs quantum computing.
 

Revision as of 14:30, 9 March 2023

(1) Relations: Cartesian products, relations, properties of relations, equivalence relations and partitions. (2) Order relations: Partially ordered sets, totally ordered sets, extreme elements (maximum, minimum, maximal and minimal elements), well-ordered sets, maximality principles, Zorn's Lemma, lattices, boolean algebras, circuit design. (3) Graphs: Euler and Hamiltonian paths and circuits, matching, graph coloring, Ramsey’s theorem, trees and searching. (4) Binary operations: Groups and semigroups, products and quotients of groups, other algebraic structures.