Difference between revisions of "MAT4213"

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(Added content to the table(5.5-5.6))
(Added content to the table(6.1-6.3))
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|Week 3
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|Week 6/7
  
 
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<div style="text-align: center;">2.1</div>
+
<div style="text-align: center;">6.1</div>
  
 
||
 
||
 
    
 
    
  
[[Algebraic Properties of the Real Numbers]]
+
[[The Derivative]]
  
 
||
 
||
  
* '''[[Field Properties]]''' <!-- DNE (recommend Modern Algebra) -->
+
* [[Continuous Functions on Intervals]] <!-- 4213-5.3 -->
 +
* [[The Definition of the Limit of a Function]] <!-- 3213-4.1 -->
  
 
||
 
||
  
* Algebraic properties of the Real Numbers
+
* Definition of the derivative of a function at a point
 +
* Continuity is required for a function to be differentiable
 +
* The constant, sum, product and quotient rules for derivatives
 +
* Caratheodory's theorem
 +
* The chain rule
  
  
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|Week&nbsp;3
+
|Week&nbsp;7
  
 
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<div style="text-align: center;">2.1</div>
+
<div style="text-align: center;"6.1</div>
  
 
||
 
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[[Rational and Irrational Numbers]]
+
[[Derivatives of Functions with Inverses]]
  
 
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* [[Restrictions on Functions| The square root function]] <!-- 3213-1.1 -->
+
* [[Inverse Functions]] <!-- 4213-5.6 -->
* [[Functions(The Cartesian Product Definition)]] <!-- 3213-1.1 -->
+
* [[The Derivative]] <!-- 4213-6.1 -->
* '''[[Definition of Even and Odd Numbers]]''' <!-- DNe (recommend Modern Algebra or MAT3013 -->
+
* [[Combinations of Continuous Functions]] <!-- 4213-5.2 -->
  
 
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* The Rational Numbers
+
* Relation between continuous, strictly monotone functions and their inverses
* Proof that the Square Root of 2 does not exist in the rational numbers
+
 
* The Irrational Numbers
 
  
  
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|Week&nbsp;2    
+
|Week&nbsp;7/8    
  
 
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<div style="text-align: center;">2.1</div>
+
<div style="text-align: center;">6.2</div>
  
 
||   
 
||   
  
[[The Ordering Properties of the Real Numbers]]
+
[[The Mean Value Theorem]]
  
 
||
 
||
  
* [[Solving Inequalities| Inequalities]] <!-- 1073- Mod R -->
+
* [[The Derivative]] <!-- 4213-6.1 -->
* [[Algebraic properties of the Real Numbers]] <!-- 3213-2.1 -->
+
* [[Continuous Functions on Intervals]] <!-- 4213-5.3 -->
  
 
||
 
||
  
* The ordering properties of the real numbers
+
* Relative maximum and relative minimum of a function
* Tricotomy property
+
* Interior extremum theorem
* If 0 <= a < x for each x in the positive real numbers, then a = 0.
+
* Rolle's Theorem
 +
* The Mean Value theorem
 +
 
  
  
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|Week&nbsp;2      
+
|Week&nbsp;8      
  
 
||
 
||
  
<div style="text-align: center;">2.1</div>
+
<div style="text-align: center;">6.2</div>
  
 
||
 
||
 
    
 
    
[[Inequalities]]
+
[[Extrema of a Function]]
  
 
||
 
||
  
* [[The Ordering Properties of the Real Numbers]] <!-- 3213-2.1 -->
+
* [[Continuous Functions on Intervals]] <!-- 4213-5.3 -->
* [[The Algebraic Properties of the Real Numbers]] <!-- 3213-2.1 -->
+
* [[The Mean Value Theorem]] <!-- 4213-6.2 -->
  
 
||
 
||
  
* Using the order properties to solve equations
+
* Increasing and Decreasing functions
* Arithmetic-geometric mean
+
* First Derivative test for extrema
* Bernoulli's Inequality
+
* Applications of the Mean Value Theorem
 +
* The Intermediate Value Property of Derivatives
  
  
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|Week&nbsp;2/3    
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|Week&nbsp;8/9    
  
 
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||
  
<div style="text-align: center;">2.2</div>
+
<div style="text-align: center;">6.3</div>
  
 
||  
 
||  
  
[[Absolute Value and the Real Line]]
+
[[L'Hospital's Rules]]
  
 
||
 
||
  
* [[The Algebraic Properties of the Real Numbers]] <!-- 3213-2.1 -->
+
* [[The Mean Value Theorem]] <!-- 4213-6.2 -->
* [[Inequalities]] <!-- 3213-2.1 -->
+
* [[The Limit Theorems for Functions]] <!-- 3213-4.2 -->
  
 
||
 
||
  
* The absolute value function
+
* Intermediate forms
* The Triangle Inequality
+
* The Cauchy mean value theorem
* Distance between elements of the real numbers
+
* L'Hospital's Rule for limits of the 0/0 form
* Definition of an epsilon neighborhood
+
* L'Hospital's Rule for limits with infinity in the denominator
 
 
  
 
|-
 
|-

Revision as of 08:31, 22 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
5.1

Continuous Functions

  • The definition of a continuous function
  • Sequential criterion for continuity
  • Discontinuity criterion


Week 1/2
5.2

Combinations of Continuous Functions

  • Sums, differences, products and quotients of continuous functions on the same domain
  • Composition of continuous functions
Week 2
5.3

Continuous Functions on Intervals

  • Bounded Functions
  • The boundedness theorem on closed and bounded intervals
  • Definitions of absolute maximum and absolute minimum of a function
  • The maximum-minimum theorem


Week 2/3
5.3

The Intermediate Value Theorem

  • The Location of Roots theorem
  • The Intermediate Value Theorem
  • The image of a continuous functions on a closed and bounded interval is a closed and bounded interval


Week 3
5.4

Uniform Continuity

  • The definition of uniform continuity
  • Nonuniform continuity criteria
  • Uniform continuity theorem


Week 3/4
5.4

Lipschitz Functions

  • Definition of a Lipschitz function
  • If a function is Lipschtiz, then it is uniformly continuous


Week 4
5.4

The Continuous Extension Theorem

  • Uniform continuity and Cauchy sequences
  • The Continuous Extension Theorem


Week 4/5
5.4

Approximations of Continuous Functions

  • Definition of a step function
  • On closed and bounded intervals, continuous functions can be approximated by piecewise linear functions
  • Weierstrass approximation theorem


Week 5
5.5

Continuity and Gauges

  • Definition of a partition of an interval
  • Definition of a tagged partition of an interval
  • Definition of a gauge of an interval
  • The existence of delta-fine partitions


Week 5/6
5.6

Monotone Functions

  • Monotone functions
  • The left and right hand limits for interior points of monotone functions
  • Defining the jump pf a function at a point
  • For a monotone function on an interval, the set of points at which the function is discontinuous is countable


Week 6
5.6

Inverse Functions

  • The continuous inverse theorem
  • The nth root function


Week 6/7
6.1


The Derivative

  • Definition of the derivative of a function at a point
  • Continuity is required for a function to be differentiable
  • The constant, sum, product and quotient rules for derivatives
  • Caratheodory's theorem
  • The chain rule


Week 7 <div style="text-align: center;"6.1

Derivatives of Functions with Inverses

  • Relation between continuous, strictly monotone functions and their inverses


Week 7/8
6.2

The Mean Value Theorem

  • Relative maximum and relative minimum of a function
  • Interior extremum theorem
  • Rolle's Theorem
  • The Mean Value theorem


Week 8
6.2

Extrema of a Function

  • Increasing and Decreasing functions
  • First Derivative test for extrema
  • Applications of the Mean Value Theorem
  • The Intermediate Value Property of Derivatives


Week 8/9
6.3

L'Hospital's Rules

  • Intermediate forms
  • The Cauchy mean value theorem
  • L'Hospital's Rule for limits of the 0/0 form
  • L'Hospital's Rule for limits with infinity in the denominator
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 Laws for Sequences

  • 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 5
3.4

The Bolzano Weierstrass Theorem

  • The Bolzano Weierstrass Theorem
  • Examples using the Bolzano Weierstrass Theorem


Week 5/6
3.4

The Limit Superior and Limit Inferior

  • Definition of the limit superior and limit inferior
  • Equivalent statements defining the limit superior and limit inferior
  • A bounded sequence converges if and only if its limit superior equals its limit inferior


Week 6
3.5

The Cauchy Criterion for Convergence

  • Definition of a Cauchy sequence
  • A sequence converges if and only if it is a Cauchy sequence
  • Contractive sequences


Week 6
3.6

Properly Divergent Sequences

  • Limits that tend to infinity
  • Properly divergent sequences


Week 6/7
3.7

Introduction to Infinite Series

  • Sequences of partial sums
  • If a series converges, then the sequence of coefficients for that series must converge to zero.
  • Examples of common series
  • Comparison tests for series
Week 12
4.1

Cluster Points

  • Definition of a cluster point
  • The cluster point as the limit of a sequence


Week 12
4.1

The Definition of the Limit of a Function

  • The definition of the limit of a function at a point
  • The uniqueness of limits at cluster points
  • Examples of limits of functions
Week 12/13
4.1

The Sequential Criterion and Divergence Criteria

  • The sequential criterion for limits of functions at a point
  • Divergence criteria for limits
  • The signum function


Week 13
4.2

The Limit Theorems for Functions

  • Functions bounded on a neighborhood of a cluster point
  • Sums, differences, products, and quotients of limits
  • The squeeze theorem for limits of functions
  • Examples of Limits using the limit theorems


Week 14
4.3

One Sided Limits

  • The definition of the right and left hand limits of a function at a point
  • 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


Week 14/15
4.3

Infinite Limits and Limits at Infinity

  • The definition of an infinite limit
  • 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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