Difference between revisions of "MAT3213"

Revision as of 18:08, 13 August 2020

The textbook for this course is Introduction to Real Analysis by Bartle and Sherbert

A comprehensive list of all undergraduate math courses at UTSA can be found here.

The Wikipedia summary of Real Analysis.

Topics List

Date	Sections	Topics	Prerequisite Skills
Week 1	1.1	Basic Terminology	Sets of Objects
Week 1	1.1	Set Operations	Basic Terminology De Morgans Laws in Logic
Week 1	1.1	Functions (The Cartesian product definition)	Domain and Range of a Function Basic Terminology Set Operations
Week 1/2	1.1	Direct and Inverse Images	Functions(The Cartesian Product Definition) Inverse Functions Set Operations
Week 1/2	1.1	Injective and Surjective Functions	Functions(The Cartesian Product Definition) Direct and Inverse Images Set Operations
Week 1/2	1.1	Inverse Functions	Injective and Surjective Functions Direct and Inverse Images
Week 1/2	1.1	Composition of Functions	Functions(The Cartesian Product Definition) Direct and Inverse Images
Week 1/2	1.1	Restrictions on Functions	Domain and Range
Week 2	1.2	Mathematical Induction	Basic Terminology Set Operations
Week 2	1.3	Finite and Infinite Sets	Set Operations Injective and Surjective Functions
Week 2	1.3	Countable Sets	Injective and Surjective Functions Finite and Infinite Sets
Week 3	2.1	Algebraic Properties of the Real Numbers	Field Properties
Week 3	2.1	Rational and Irrational Numbers	The square root function Functions(The Cartesian Product Definition) Definition of Even and Odd Numbers
Week 2	2.1	The Ordering Properties of the Real Numbers	Inequalities Algebraic properties of the Real Numbers
Week 2	2.1	Inequalities	The Ordering Properties of the Real Numbers The Algebraic Properties of the Real Numbers
Week 2/3	2.2	Absolute Value and the Real Line	The Algebraic Properties of the Real Numbers Inequalities
Week 3	2.3	Suprema, Infima, and the Completeness Property	Inequalities Absolute Value and the Real Line
Week 3	2.4	Applications of the Supremum Property	Inequalities Absolute Value and the Real Line Suprema, Infima, and the Completeness Property
Week 3/4	2.5	Intervals	Inequalities Suprema, Infima, and the Completeness Property
Week 4	3.1	Sequences and Their Limits	Absolute Value and the Real Line Countable Sets Applications of the Supremum Property
Week 4	3.2	The Limit Laws for Sequences	Bounded sets Sequences and Their Limits
Week 4/5	3.3	Monotone Sequences	Mathematical Induction Bounded sets Bounded Sequences
Week 5	3.4	Subsequences	Monotone Sequences The Limit Laws for Sequences
Week 5	3.4	The Bolzano Weierstrass Theorem	Bounded Sequences Subsequences
Week 5/6	3.4	The Limit Superior and Limit Inferior	Bounded sets Bounded Sequences
Week 6	3.5	The Cauchy Criterion for Convergence	The Limit of a Sequence The Limit Laws for Sequences
Week 6	3.6	Properly Divergent Sequences	Monotone Sequences Divergence criteria of a sequence
Week 6/7	3.7	Introduction to Infinite Series	The Limit of a Sequence The Cauchy Criterion for Convergence
Week 12	4.1	Cluster Points	Epsilon neighborhoods The Limit of a Sequence
Week 12	4.1	The Definition of the Limit of a Function	Cluster Point Intervals
Week 12/13	4.1	The Sequential Criterion and Divergence Criteria	The Limit of a Sequence The Definition of the Limit of a Function
Week 13	4.2	The Limit Theorems for Functions	The Definition of the Limit of a Function The Sequential Criterion and Divergence Criteria
Week 14	4.3	One Sided Limits	The Definition of the Limit of a Function The Sequential Criterion and Divergence Criteria
Week 14/15	4.3	Infinite Limits and Limits at Infinity	The Definition of the Limit of a Function The Sequential Criterion and Divergence Criteria One Sided Limits

Difference between revisions of "MAT3213"

Revision as of 18:08, 13 August 2020

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-* Subsets
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-* The definition of equality between two sets
-* Commonly used sets
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-* Union, intersection and complements of sets
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-* De Morgans Laws for sets
-* Infinite Unions and intersections of sets
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-* The Cartesian Product
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-* Definition of a function
-* Domain and Range in terms of the Cartesian product
-* Transformations and Machines
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-* Definition of the Direct Image
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-* Definition of the Inverse Image
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-* Injective functions
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-* Surjective functions
-* Bijective functions
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-* Definition of Inverse functions
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-* Criteria for an Inverse of a function to exist
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-* Definition of a composition function
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-* When function composition is defined
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-* Define the restriction of a function
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-* Positive Square Root function
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-* Well-ordering principal
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-* Principal of Mathematical induction
-* The principal of Strong Induction
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-* Definition of finite and infinite sets
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-* Uniqueness Theorem
-* If T is a subset of S and T is infinite, then S is also infinite.
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-* Countable and Uncountable sets
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-* The set of rational numbers is countable
-* Cantor's Theorem
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-* Algebraic properties of the Real Numbers
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-* The Rational Numbers
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-* Proof that the Square Root of 2 does not exist in the rational numbers
-* The Irrational Numbers
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-* The ordering properties of the real numbers
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-* Tricotomy property
-* If 0 <= a < x for each x in the positive real numbers, then a = 0.
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-* Using the order properties to solve equations
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-* Arithmetic-geometric mean
-* Bernoulli's Inequality
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-* The absolute value function
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-* The Triangle Inequality
-* Distance between elements of the real numbers
-* Definition of an epsilon neighborhood
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-* Upper and lower bounds of sets
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-* Definition of the suprema and infima of a set
-* Thed completeness property of the real numbers
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-* Bounded Functions
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-* The Archimedean Property
-* The existence of the square root of 2
-* Density of the rational numbers in the real numbers
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-* Types of Intervals
+<!-- ------------------------------------------------------------ -->
-* Characterization of Intervals
-* Nested intervals
-* The Nested Intervals Property
-* Demonstrate that the real numbers are not countable
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-* Definition of the limit of a sequence
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-* The uniqueness of limits in the real numbers
-* Tails of sequences
-* Examples of common sequences
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-* Bounded Sequences
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-* Summation, difference, products, and quotients of sequences
-* The squeeze theorem for sequences
-* Divergent Sequences
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-* Increasing and Decreasing sequences
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-* The Monotone Convergence theorem
-* Inductively defined sequences
-* The existence of Euler's Number
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-* Definition of a Subsequence
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-* If a sequence converges to limit L, then every subsequence of that sequence also converges to L.
-* Definition of a divergent Sequence
-* Divergence criteria of a sequence
-* Monotone subsequence theorem
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-* The Bolzano Weierstrass Theorem
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-* Examples using the Bolzano Weierstrass Theorem
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-* Definition of the limit superior and limit inferior
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-* Equivalent statements defining the limit superior and limit inferior
-* A bounded sequence converges if and only if its limit superior equals its limit inferior
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-* Definition of a Cauchy sequence
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-* A sequence converges if and only if it is a Cauchy sequence
-* Contractive sequences
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-* Limits that tend to infinity
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-* Properly divergent sequences
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-* Sequences of partial sums
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-* If a series converges, then the sequence of coefficients for that series  must converge to zero.
-* Examples of common series
-* Comparison tests for series
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-* Definition of a cluster point
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-* The cluster point as the limit of a sequence
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-* The definition of the limit of a function at a point
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-* The uniqueness of limits at cluster points
-* Examples of limits of functions
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-* The sequential criterion for limits of functions at a point
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-* Divergence criteria for limits
-* The signum function
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-* Functions bounded on a neighborhood of a cluster point
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-* Sums, differences, products, and quotients of limits
-* The squeeze theorem for limits of functions
-* Examples of Limits using the limit theorems
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-* The definition of the right and left hand limits of a function at a point
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-* The sequential criterion for the left and right hand limits
-* The limit of a function at a point exists if and only if its left and right hand limits are equal
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-* The definition of an infinite limit
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-* If the function f is less than the function g on a specified domain and f tends to infinity, then g tends to infinity on this domain as well.
-* The definition of a limit has its independent variable approaches infinity
-* The sequential criterion for limits at infinity
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