Difference between revisions of "Math 541: Real Analysis"

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(Minimal learning outcomes)
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#** Compatibility with Riemann integration
 
#** Compatibility with Riemann integration
 
# Fubini's Theorem for <b>R</b><sup>n</sup>
 
# Fubini's Theorem for <b>R</b><sup>n</sup>
# L<sup>1</sup>, L<sup>2</sup>, and L<sup>&#8734;</sup> and normed linear spaces
+
# L<sup>1</sup>, L<sup>2</sup>, and L<sup>&#8734;</sup>
 
#* Completeness
 
#* Completeness
 
#* Approximation by smooth functions
 
#* Approximation by smooth functions
 +
#* Continuity of translation
 +
# Fourier transform on <b>R</b><sup>n</sup>
 +
#* Convolutions
 +
#* Basic properties of Fourier transforms
 +
#** Composition with translation, dilation, inversion, differentiation, convolution, etc.
 +
#** Regularity of transformed functions
 +
#** Riemann-Lebesgue Lemma
 +
#* Inversion Theorem for L<sup>1</sup>
 +
#* Schwartz class
 +
#* Fourier-Plancherel Transform on L<sup>2</sup>
 +
#** Its inversion
 +
#** Isomorphism
 +
 
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Revision as of 09:58, 13 August 2008

Catalog Information

Title

Real Analysis.

Credit Hours

3

Prerequisite

Math 315, 343; 214 or 316.

Description

Rigorous treatment of differentiation and integration theory; Lebesque measure; Banach spaces.

Desired Learning Outcomes

Prerequisites

Minimal learning outcomes

  1. Lebesgue measure on Rn
    • Inner and outer measures
    • Construction of Lebesgue measure
    • Properties of Lebesgue measure
      • Effect of basic set operations
      • Limiting properties
      • Its domain
      • Approximation properties
      • Sets of outer measure zero
      • Invariance w.r.t. isometries
      • Effect of dilations
    • Existence of nonmeasurable sets
  2. Lebesgue integration on Rn
    • Measurable functions
    • Simple functions
    • Approximation of measurable functions with simple functions
    • The extended reals
    • Integrating nonnegative functions
    • Integrating absolutely-integrable functions
    • Integrating on measurable sets
    • Basic properties of the Lebesgue integral
      • Linearity
      • Monotonicity
      • Effects of sets of measure zero
      • Absolute continuty of integration
      • Fatou's Lemma
      • Monotone Convergence Theorem
      • Dominated Convergence Theorem
      • Differentiation w.r.t. a parameter
      • Linear changes of variable
      • Compatibility with Riemann integration
  3. Fubini's Theorem for Rn
  4. L1, L2, and L
    • Completeness
    • Approximation by smooth functions
    • Continuity of translation
  5. Fourier transform on Rn
    • Convolutions
    • Basic properties of Fourier transforms
      • Composition with translation, dilation, inversion, differentiation, convolution, etc.
      • Regularity of transformed functions
      • Riemann-Lebesgue Lemma
    • Inversion Theorem for L1
    • Schwartz class
    • Fourier-Plancherel Transform on L2
      • Its inversion
      • Isomorphism

Additional topics

Courses for which this course is prerequisite