Difference between revisions of "MAT3213"

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(Added content to the table(2.3 - 3.1))
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[[Sequences and their Limits]]
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[[Sequences and Their Limits]]
  
 
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|Week 11 
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|Week 
  
 
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<div style="text-align: center;">4.10</div>
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<div style="text-align: center;">3.2</div>
  
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[[Antiderivatives]]
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[[The Limit Theorems]]
  
 
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* [[Inverse Functions]] <!-- 1073-7 -->
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* [[Suprema, Infima, and the Completeness Property|Bounded sets]] <!-- 3213-2.3 -->
* [[The Derivative as a Function]] <!-- 1214-3.2 -->
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* [[Sequences and Their Limits]] <!-- 3213-3.1 -->
* [[Differentiation Rule]] <!-- 1214-3.3 -->
 
* [[Derivatives of the Trigonometric Functions]] <!-- 1214-3.5 -->
 
  
 
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* Find the general antiderivative of a given function.
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* Bounded Sequences
* Explain the terms and notation used for an indefinite integral.
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* Summation, difference, products, and quotients of sequences
* State the power rule for integrals.
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* The squeeze theorem for sequences
* Use anti-differentiation to solve simple initial-value problems.
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* Divergent Sequences
  
  
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|Week&nbsp;11/12    
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|Week&nbsp;4/5    
  
 
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<div style="text-align: center;">5.1</div>
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<div style="text-align: center;">3.3</div>
  
 
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[[Approximating Areas]]
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[[Monotone Sequences]]
  
 
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* '''[[Sigma notation]]''' <!-- DNE (recommend 1093) -->
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* [[Mathematical Induction]] <!-- 3213-1.2 -->
* '''[[Area of a rectangle]]''' <!-- Grades 6-12 -->
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* [[Suprema, Infima, and the Completeness Property|Bounded sets]] <!-- 3213-2.3 -->
* [[Continuity]] <!-- 1214-3.5 -->
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* [[The Limit Theorems|Bounded Sequences]] <!-- 3213-3.2 -->
* [[Toolkit Function]] <!-- 1073-Mod 1.2 -->
 
  
 
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* Calculate sums and powers of integers.
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* Increasing and Decreasing sequences
* Use the sum of rectangular areas to approximate the area under a curve.
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* The Monotone Convergence theorem
* Use Riemann sums to approximate area.
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* Inductively defined sequences
 
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* The existence of Euler's Number
  
  
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|Week&nbsp;12    
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|Week&nbsp;5    
  
 
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<div style="text-align: center;">5.2</div>
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<div style="text-align: center;">3.4</div>
  
 
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[[The Definite Integral]]
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[[Subsequences]]
  
 
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* [[Solving Inequalities|Interval notation]] <!-- 1073-Mod.R -->
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* [[Monotone Sequences]] <!-- 3213-3.3 -->
* [[Antiderivatives]] <!-- 1214-4.10 -->
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* [[The Limit Laws]] <!-- 3213-3.2 -->
* [[The Limit of a Functions|Limits of Riemann Sums]] <!-- 1214-2.2 -->
 
* [[Continuity]] <!-- 1214-3.5 -->
 
  
 
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* State the definition of the definite integral.
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* Definition of a Subsequence
* Explain the terms integrand, limits of integration, and variable of integration.
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* If a sequence converges to limit L, then every subsequence of that sequence also converges to L.
* Explain when a function is integrable.
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* Definition of a divergent Sequence
* Rules for the Definite Integral.
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* Divergence criteria of a sequence
* Describe the relationship between the definite integral and net area.
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* Monotone subsequence theorem
* Use geometry and the properties of definite integrals to evaluate them.
 
* Calculate the average value of a function.
 
  
  

Revision as of 21:14, 16 July 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 Student Learning Outcomes
Week 1
1.1

Basic Terminology

  • Subsets
  • The definition of equality between two sets
  • Commonly used sets


Week 1
1.1


Set Operations

  • Union, intersection and complements of sets
  • De Morgans Laws for sets
  • Infinite Unions and intersections of sets
Week 1
1.1

Functions (The Cartesian product definition)

  • The Cartesian Product
  • Definition of a function
  • Domain and Range in terms of the Cartesian product
  • Transformations and Machines


Week 1/2
1.1

Direct and Inverse Images

  • Definition of the Direct Image
  • Definition of the Inverse Image


Week 1/2
1.1


Injective and Surjective Functions

  • Injective functions
  • Surjective functions
  • Bijective functions


Week 1/2
1.1


Inverse Functions

  • Definition of Inverse functions
  • Criteria for an Inverse of a function to exist


Week 1/2
1.1

Composition of Functions

  • Definition of a composition function
  • When function composition is defined


Week 1/2
1.1


Restrictions on Functions

  • Define the restriction of a function
  • Positive Square Root function


Week 2
1.2

Mathematical Induction

  • Well-ordering principal
  • Principal of Mathematical induction
  • The principal of Strong Induction


Week 2
1.3


Finite and Infinite Sets

  • Definition of finite and infinite sets
  • Uniqueness Theorem
  • If T is a subset of S and T is infinite, then S is also infinite.


Week 2
1.3

Countable Sets

  • Countable and Uncountable sets
  • The set of rational numbers is countable
  • Cantor's Theorem


Week 3
2.1


Algebraic Properties of the Real Numbers

  • Algebraic properties of the Real Numbers


Week 3
2.1

Rational and Irrational Numbers

  • The Rational Numbers
  • Proof that the Square Root of 2 does not exist in the rational numbers
  • The Irrational Numbers


Week 2
2.1

The Ordering Properties of the Real Numbers

  • The ordering properties of the real numbers
  • Tricotomy property
  • If 0 <= a < x for each x in the positive real numbers, then a = 0.


Week 2
2.1

Inequalities

  • Using the order properties to solve equations
  • Arithmetic-geometric mean
  • Bernoulli's Inequality


Week 2/3
2.2

Absolute Value and the Real Line

  • The absolute value function
  • The Triangle Inequality
  • Distance between elements of the real numbers
  • Definition of an epsilon neighborhood


Week 3
2.3

Suprema, Infima, and the Completeness Property

  • Upper and lower bounds of sets
  • Definition of the suprema and infima of a set
  • Thed completeness property of the real numbers


Week 3
2.4

Applications of the Supremum Property

  • Bounded Functions
  • The Archimedean Property
  • The existence of the square root of 2
  • Density of the rational numbers in the real numbers


Week 3/4
2.5

Intervals

  • Types of Intervals
  • Characterization of Intervals
  • Nested intervals
  • The Nested Intervals Property
  • Demonstrate that the real numbers are not countable


Week 4
3.1

Sequences and Their Limits

  • Definition of the limit of a sequence
  • The uniqueness of limits in the real numbers
  • Tails of sequences
  • Examples of common sequences


Week 4
3.2

The Limit Theorems

  • Bounded Sequences
  • Summation, difference, products, and quotients of sequences
  • The squeeze theorem for sequences
  • Divergent Sequences


Week 4/5
3.3

Monotone Sequences

  • Increasing and Decreasing sequences
  • The Monotone Convergence theorem
  • Inductively defined sequences
  • The existence of Euler's Number


Week 5
3.4

Subsequences

  • Definition of a Subsequence
  • 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


Week 12/13
5.3

The Fundamental Theorem of Calculus

  • Describe the meaning of the Mean Value Theorem for Integrals.
  • State the meaning of the Fundamental Theorem of Calculus, Part 1.
  • Use the Fundamental Theorem of Calculus, Part 1, to evaluate derivatives of integrals.
  • State the meaning of the Fundamental Theorem of Calculus, Part 2.
  • Use the Fundamental Theorem of Calculus, Part 2, to evaluate definite integrals.
  • Explain the relationship between differentiation and integration.


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