Difference between revisions of "MAT4223"

From Department of Mathematics at UTSA
Jump to navigation Jump to search
(Added content for the prerequisites (9.1-11.1))
(Completed updated list of prerequisites)
Line 64: Line 64:
  
 
||
 
||
 
  
 
* [[Power Series and Functions ]] <!-- 1224-6.1 -->
 
* [[Power Series and Functions ]] <!-- 1224-6.1 -->
 
* [[Ratio and Root Tests ]]  <!-- 1224-5.6 -->
 
* [[Ratio and Root Tests ]]  <!-- 1224-5.6 -->
 
* [[Comparison Tests ]]  <!-- 1224-5.4 -->
 
* [[Comparison Tests ]]  <!-- 1224-5.4 -->
 +
* [[Taylor's Theorem ]]  <!-- 4213-6.3 -->
 
* [[Uniform Convergence of Series of Functions]] <!-- 4223-7.2 -->  
 
* [[Uniform Convergence of Series of Functions]] <!-- 4223-7.2 -->  
  
Line 160: Line 160:
  
 
|-
 
|-
 
 
  
  
Line 223: Line 221:
 
<div style="text-align: center;">9.2</div>
 
<div style="text-align: center;">9.2</div>
  
||
+
||  
 
 
  
 
[[ The Heine-Borel Theorem]]  
 
[[ The Heine-Borel Theorem]]  
Line 333: Line 330:
 
<div style="text-align: center;">11.2</div>
 
<div style="text-align: center;">11.2</div>
  
||
+
||  
 
 
  
 
[[Differentiation of Vector-valued Functions]]
 
[[Differentiation of Vector-valued Functions]]
Line 349: Line 345:
 
* The total derivative  of a differentiable function
 
* The total derivative  of a differentiable function
 
* Determine whether a function if differentiable or not
 
* Determine whether a function if differentiable or not
 
||
 
  
  
Line 365: Line 359:
 
||
 
||
 
    
 
    
[[Rules for Differentiation and tangent planes]]
+
[[Rules for Differentiation and Tangent Planes]]
  
 
||
 
||
  
* Rules for Differentiation of real-valued functions
+
* [[Differentiation of Vector-valued Functions]]  <!-- 4223-11.2 -->
 +
* [[The Derivative ]]  <!-- 4213-6.1 -->
 +
* [[Euclidean Spaces: Algebraic Structure and Inner Product]] <!-- 4223-8.1 -->
  
 
||
 
||
Line 390: Line 386:
 
||
 
||
 
    
 
    
[[Mean-Value Theorems]]
+
[[Mean-Value Theorems for Vector Valued Functions]]
  
 
||
 
||
  
* Mean-value theorems for real-valued functions
+
* [[The Mean Value Theorem ]]  <!-- 4213-6.1 -->
 +
* [[Partial Derivatives and Integrals]]  <!-- 4223-11.1 -->
 +
* [[Differentiation of Vector-valued Functions]]  <!-- 4223-11.2 -->
  
 
||
 
||
Line 413: Line 411:
 
||
 
||
  
[[Taylor's Formula in several variables]]
+
[[Taylor's Formula in Several Variables]]
  
 
||
 
||
  
Taylor's formula for real-valued functions
+
* [[Taylor's Theorem ]]  <!-- 4213-6.3 -->
 +
* [[Power Series and Analytic Functions]] <!-- 4223-7.3 -->
 +
* [[Mean-Value Theorems for Vector Valued Functions]] <!-- 4223-11.5 -->
  
 
||
 
||
Line 439: Line 439:
  
 
||
 
||
 
+
* The inverse function theorem for real-valued functions
+
* [[Inverse Functions  ]] <!-- 4213-5.6 -->
* Cramer's rule for solving linear systems of equations
+
* [[The Geometric Interpretation of the Determinant|Cramer's Rule  ]] <!-- 2233-6.3 -->
 +
* [[Mean-Value Theorems for Vector Valued Functions]] <!-- 4223-11.5 -->
  
 
||
 
||
Line 460: Line 461:
 
||
 
||
 
    
 
    
[[Lebesque theorem for Riemann Integrability on the Real Line]]
+
[[Lebesque Theorem for Riemann Integrability on the Real Line]]
  
 
||
 
||
  
* Riemann integrability on real-valued functions
+
* [[Continuous Functions]]  <!-- 4213-5.1 -->
 +
* [[Riemann Integrable Functions ]] <!-- 4213-7.2 -->
  
 
||
 
||
  
 +
* Define an almost everywhere continuous function
 
* The Riemann integrable functions are those almost everywhere continuous
 
* The Riemann integrable functions are those almost everywhere continuous
  
Line 482: Line 485:
 
||
 
||
 
    
 
    
[[Integration in the Euclidean space: Jordan regions and Volume]]
+
[[Integration in the Euclidean space: Jordan Regions and Volume]]
  
 
||
 
||
  
* Darboux integration for real-valued functions
+
* [[Riemann Integrable Functions ]] <!-- 4213-7.2 -->
 +
* [[The Darboux Integral]] <!-- 4213-7.4 -->
  
 
||
 
||
  
 
* Jordan regions: volume and properties
 
* Jordan regions: volume and properties
 +
  
  
Line 508: Line 513:
 
||
 
||
  
* Riemann and Darboux integration for real-valued functions
+
* [[Integration in the Euclidean space: Jordan Regions and Volume]] <!-- 4223-12.1 -->
  
 
||
 
||
  
 
* Definition of a Riemann integrable function, characterization, properties
 
* Definition of a Riemann integrable function, characterization, properties
* Any continuous function on a closed Jordan region is integrable
+
* Any continuous function on a closed Jordan region is integrable
 
* Mean-valued theorems for multiple integrals
 
* Mean-valued theorems for multiple integrals
  
Line 531: Line 536:
 
||
 
||
  
* Basic integration theory from the previous section
+
* [[Riemann Integration on Jordan Regions in Higher Dimensions]] <!-- 4223-12.2 -->
  
 
||
 
||

Revision as of 18:53, 5 August 2020

Topics List

Date Sections Topics Prerequisite Skills Student Learning Outcomes
Week 1
7.1

Uniform Convergence of Sequences of Functions

  • Understand the difference between pointwise convergence and uniform convergence
  • Understand how the continuity, diferrentiablity and integrability behave under uniform convergence
Week 1
7.2

Uniform Convergence of Series of Functions

  • Learn the term-by-term differentiation (resp. integration) theorem
  • Weierstrass M-test
Week 2
7.3 and 7.4

Power Series and Analytic Functions

  • Determine the set of convergence for a power series
  • Apply the results of the previous sections to power series.
  • Apply the results to the elementary functions
Week 2
7.5

Weierstrass Example

  • Learn to construct a continuous function everywhere which is not differentiable anywhere


Week 3
8.1

Euclidean Spaces: Algebraic Structure and Inner Product

  • Norms in the Euclidean space, comparison
  • Cauchy-Schwartz inequality, triangle inequality


Week 3
8.2

Linear Tranformations

  • The matrix of a linear transformation
  • The norm of a linear transformation
  • Write equations of hyperplanes in the Euclidean space


Week 3
8.3 and 8.4

The Topology of Higher Dimensions: interior, closure and boundary

  • Learn basic notions of topology in the Euclidean space


Week 4
9.1

Limits of Sequences in the Euclidean space and the Bolzano-Weierstrass Theorem

  • Convergence theorems
  • Bolzano-Weierstrass Theorem


Week 4
9.2

The Heine-Borel Theorem

  • Understand the structure of compact sets
  • Applications


Week 5
9.3

Limits of Vector Functions

  • Limit theorems, sequential criterion
  • Iterated limits
  • Commutation of iterated limits


Week 5
9.4

Continuous Vector Functions

  • Characterizations of continuity
  • Properties of continuous functions
  • Extreme value theorem


Week 6
11.1

Partial Derivatives and Integrals

  • Commutation of partial derivatives
  • Commutation of the limit with the the integral
  • Differentiating under the integral sign


Week 7
11.2

Differentiation of Vector-valued Functions

  • Necessary and sufficient conditions for differentiation
  • The total derivative of a differentiable function
  • Determine whether a function if differentiable or not


Week 7
11.3 and 11.4

Rules for Differentiation and Tangent Planes

  • Basic rules for differentiation and applications
  • Tangent hyperplanes to surfaces
  • Chain rule


Week 8
11.5

Mean-Value Theorems for Vector Valued Functions

  • Mean-value theorems for vector-valued functions
  • Lipschitz functions


Week 8
11.5 and 11.6

Taylor's Formula in Several Variables

  • Taylor's Formula in several variables, applications


Weeks 8 and 9
11.6

The Inverse Function Theorem and the Implicit Function Theorem

  • The inverse function theorem and the implicit function theorem for vector-valued functions
  • Applications


Week 10
9.6

Lebesque Theorem for Riemann Integrability on the Real Line

  • Define an almost everywhere continuous function
  • The Riemann integrable functions are those almost everywhere continuous


Weeks 11 and 12
12.1

Integration in the Euclidean space: Jordan Regions and Volume

  • Jordan regions: volume and properties


Weeks 13 and  14
12.2

Riemann Integration on Jordan Regions in Higher Dimensions

  • Definition of a Riemann integrable function, characterization, properties
  • Any continuous function on a closed Jordan region is integrable
  • Mean-valued theorems for multiple integrals
Week 15
12.3

Iterated Integrals and Fubini's Theorem

  • Fubini's theorem and applications