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[1] Gordon Pace, ''Mathematics of Discrete Structures foe Computer Science'', Springer, 2012 | [1] Gordon Pace, ''Mathematics of Discrete Structures foe Computer Science'', Springer, 2012 | ||
[2] Vladlen Koltun, ''Discrete Structures Lecture Notes, Stanford University'', 2008.[https://web.stanford.edu/class/cs103x/cs103x-notes.pdf link] | [2] Vladlen Koltun, ''Discrete Structures Lecture Notes, Stanford University'', 2008.[https://web.stanford.edu/class/cs103x/cs103x-notes.pdf link] | ||
| + | |||
| + | |||
| + | Catalog entry | ||
| + | |||
| + | Prerequisite: Algebra and Number Systems (MAT 1313), or Discrete Mathematical Structures (CS 2233/2231), or instructor consent. | ||
| + | |||
| + | Contents: | ||
| + | Propositional logic: Axioms and Rules of Inference. Boolean Algebras. Limitations of propositional logic: Informal introduction to quantifiers and syllogisms. | ||
| + | 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. | ||
| + | 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. | ||
| + | Relations: Properties of relations. Special relations: Equivalence relations, partially ordered sets, totally ordered sets. | ||
| + | Functions: Operations of functions, direct image and inverse image. | ||
| + | Well-ordered sets: Correspondence between well-ordering relations and induction. Correspondence between well-ordering relations and choice functions. | ||
| + | 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. | ||
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==Topics List== | ==Topics List== | ||
{| class="wikitable sortable" | {| class="wikitable sortable" | ||
| − | ! Week !! Topic !! Sections from Pace's book !! | + | ! Week !! Topic !! Sections from Pace's book !! Calculus 2 |
|- | |- | ||
| − | | 1 | + | | 1 |
|| [[Propositional logic]] | || [[Propositional logic]] | ||
|| 2.1-2.4 | || 2.1-2.4 | ||
| Line 22: | Line 40: | ||
|- | |- | ||
| 4-5 | | 4-5 | ||
| − | || [[ | + | || [[Predicate calculus]] |
| − | || | + | || 3.1-3.5 |
|| | || | ||
|- | |- | ||
| − | | 7 | + | | 6-7 |
| − | || [[ | + | || [[Sets and boolean algebras]] |
| − | || | + | || 4.1-4.8 |
|| | || | ||
|- | |- | ||
| − | | | + | | 8 |
| − | || [[ | + | || [[Relations]] |
| − | || | + | || 5.1-6.3 |
|| | || | ||
| + | |- | ||
| + | | 9-10 | ||
| + | || [[Discrete structures]] | ||
| + | || Graphs, trees, networks, and data | ||
| + | || 7.1-8.4 | ||
| + | |- | ||
| + | | 10-16 | ||
| + | || [[Models of computation]] | ||
| + | || Graphs, trees, networks, and data | ||
| + | || 7.1-8.4 | ||
|} | |} | ||
Revision as of 14:43, 18 March 2023
Introduction to basic discrete structures.
Sample textbooks:
[1] Gordon Pace, Mathematics of Discrete Structures foe Computer Science, Springer, 2012 [2] Vladlen Koltun, Discrete Structures Lecture Notes, Stanford University, 2008.link
Catalog entry
Prerequisite: Algebra and Number Systems (MAT 1313), or Discrete Mathematical Structures (CS 2233/2231), or instructor consent.
Contents: Propositional logic: Axioms and Rules of Inference. Boolean Algebras. Limitations of propositional logic: Informal introduction to quantifiers and syllogisms. 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. 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. Relations: Properties of relations. Special relations: Equivalence relations, partially ordered sets, totally ordered sets. Functions: Operations of functions, direct image and inverse image. Well-ordered sets: Correspondence between well-ordering relations and induction. Correspondence between well-ordering relations and choice functions. 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.
Topics List
| Week | Topic | Sections from Pace's book | Calculus 2 |
|---|---|---|---|
| 1 | Propositional logic | 2.1-2.4 | Undergraduate real analysis. |
| 3-4 | Completeness and soundness | 2.5-2.7. | |
| 4-5 | Predicate calculus | 3.1-3.5 | |
| 6-7 | Sets and boolean algebras | 4.1-4.8 | |
| 8 | Relations | 5.1-6.3 | |
| 9-10 | Discrete structures | Graphs, trees, networks, and data | 7.1-8.4 |
| 10-16 | Models of computation | Graphs, trees, networks, and data | 7.1-8.4 |
