MAT3013

From Department of Mathematics at UTSA
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Foundations of Mathematics (3-0) 3 Credit Hours

Course Catalog

MAT 3013. Foundations of Mathematics. (3-0) 3 Credit Hours.

Prerequisite: MAT 1214. Development of theoretical tools for rigorous mathematics. Topics may include mathematical logic, propositional and predicate calculus, set theory, functions and relations, cardinal and ordinal numbers, Boolean algebras, and construction of the natural numbers, integers, and rational numbers. Emphasis on theorem proving. (Formerly MAT 2243. Credit cannot be earned for MAT 3013 and MAT 2243.) Generally offered: Fall, Spring, Summer. Differential Tuition: $150.

Description

Foundations of Mathematics is a pivotal course for mathematics majors. It serves as the first major step towards modern mathematics of rigorous proofs and a true pre-requisite to real analysis and abstract algebra. Up to this point students are asked to do few proofs (notably geometry and perhaps some epsilon-delta in calculus). The course particularly emphasizes set-theoretical constructions, such as functions, composition, inversion, forward and inverse images, relations, equivalence relations, partial orders, quotient sets and products and unions of sets, vital to further work in mathematics.

Evaluation

  • No makeup exams are offered.
  • An absence may be excused if sufficient evidence of extenuating circumstances is provided. In this case, the final exam grade

could be used as the grade for the missed exam.

  • Students will have access to several past exams for practice.

Text

D. Smith, M. Eggen, R. St. Andre, A Transition to Advanced Mathematics (7e), Brooks/Cole

Topics List A

Date Sections Topics Prerequisite Skills Student Learning Outcomes
1.0
  • 1.1
  • Historical remarks
  • Overview of the course and its goals
  • Ideas of proofs and logic
  • Axioms and propositions
  • Motivation for rigorous mathematics from a historical perspective
  • An understanding of where and why this course is going
2.0
  • 1.2-3
  • Logical operators
  • Truth values
  • Truth tables
  • Quantifiers
  • Gain the prerequisites for writing and evaluating proofs.
3.0
  • 1.4-6
  • Methods for proofs
  • Propositional logic
  • Start proving elementary results.
4.0
  • 2.1-3
  • Basic concepts
  • Operations and constructions with sets
  • Basic concepts of set theory
  • How to start working with sets
5.0
  • 2.4-6
  • Mathematical induction
  • Counting principles
  • Natural numbers
  • Learn constructive proofs and reasoning.
  • Learn basic counting principles of discrete mathematics.
6.0
7.0
  • 3.1-3
  • Cartesian products and their subsets
  • Equivalence relations
  • Set theory
  • Gain basic concepts about relations.
8.0
  • 3.4-5
  • Partial orders
  • Graphs
  • Relations 1
  • Familiarize with ordering.
  • Learn how to use graph representations of relations.
9.0
  • 4.1-2
  • Functions
  • Constructions with functions
  • Relations
  • Function sense (precalculus)
  • Gain basic rigorous knowledge of functions.
10.0
  • 4.3-4
  • One-to-one
  • Onto
  • Compositional inverse
  • Functions 1
  • Determine whether a function is one-to-one of onto, with proofs.
  • Finding inverses
11.0
  • 4.5-6
  • Images of subsets
  • Preimages of subsets
  • Sequences
  • Functions 2
  • Find images and preimages of subsets under functions, with proofs.
12.0
13.0
  • 5.1-2
  • Finite and infinite sets
  • Equivalent sets
  • Sets and functions
  • Learn classification of sets by size.
  • Generalizing the concept of size to infinite sets
14.0
  • 5.3-5
  • Countable and uncountable sets
  • Cardinality 1
  • Learn properties of countable sets.
15.0

Topics List B

Week Session Topics Section Prerequisite skills Learning outcomes Examples
1 Introduction
  • Historical remarks
  • Overview of the course and its goals
  • Ideas of proofs and logic
  • Axioms and propositions
1.1
  • Motivation for rigorous

mathematics from a historical perspective

  • An understanding of where

and why this course is going

2 Propositional logic
  • Logical operators
  • Truth values
  • Truth tables
  • Quantifiers
1.2-3 Gain the prerequisites for

writing and evaluating proofs.

  • connectives
  • conditionals
  • biconditionals
3 Proof methods Methods for proofs 1.4-6 Propositional logic Start proving elementary results.
  • direct proofs
  • modus ponens
  • proofs by contradiction
4 Set theory
  • Basic concepts
  • Operations and constructions with sets
2.1-3 Basic concepts of set theory How to start working with sets
  • notation
  • subsets
  • proving sets are equal
  • unions, intersections, complements
5 Induction and counting
  • Mathematical induction
  • Counting principles
2.4-6 Natural numbers
  • Learn constructive proofs and reasoning.
  • Learn basic counting principles of discrete mathematics.
  • sums of consecutive powers
  • other induction proofs
  • well ordering principle
  • inclusion-exclusion principle
6
  • Catch up and review
  • Midterm 1
7 Relations 1
  • Cartesian products and their subsets
  • Equivalence relations
3.1-3 Set theory Gain basic concepts about relations.
  • modular congruence
  • gluing sets
8 Relations 2
  • Partial orders
  • Graphs
3.4-5 Relations 1
  • Familiarize with ordering.
  • Learn how to use graph representations of relations.
partial ordering of the power set under inclusion
9 Functions 1
  • Functions
  • Constructions with functions
4.1-2
  • Relations
  • Function sense (precalculus)
Gain basic rigorous knowledge of functions.

functional composition

10 Functions 2
  • One-to-one
  • Onto
  • Compositional inverse
4.3-4 Functions 1
  • Determine whether a function is one-to-one of onto, with proofs.
  • Finding inverses
  • examples with finite sets
  • many precalculus examples
11 Functions 3
  • Images of subsets
  • Preimages of subsets
  • Sequences
4.5-6 Functions 2 Find images and preimages of subsets under functions, with proofs.
  • examples with finite sets
  • many precalculus examples
12
  • Catch up and review
  • Midterm 2
13 Cardinality 1
  • Finite and infinite sets
  • Equivalent sets
5.1-2 Sets and functions
  • Learn classification of sets by size.
  • Generalizing the concept of size to infinite sets
14 Cardinality 2 Countable and uncountable sets 5.3-5 Cardinality 1 Learn properties of countable sets.
15
  • Catch up and review for final
  • Study days

See also