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       -Choice 5 by '''4.3.10 Definition'''
 
       -Choice 5 by '''4.3.10 Definition'''
 
1.d.  Let <math>A \subset \Re</math>, let <math>f: A \mapsto \Re</math>, and let <math>c \in A</math>.  We say that f is continuous at c if
 
1.d.  Let <math>A \subset \Re</math>, let <math>f: A \mapsto \Re</math>, and let <math>c \in A</math>.  We say that f is continuous at c if
       -Choice 4 by '''5.5.1 Definition'''.
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       -Choice 4 by '''5.5.1 Definition'''
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'''PROBLEM 2'''
 
'''PROBLEM 2'''
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Let <math>x_1 := 8</math> and <math>x_{n+1} := \frac{1}{2}x_n + 2</math> for <math>n \in N</math>
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a) Use induction to show that (<math>x_n</math>) is bounded below by 4.
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    -Base case <math>x_1 = 8</math>, so <math>x_1 > 4</math>
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    -Assume <math>x_n > 4</math>; is <math>x_{n+1} > 4</math>?
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    <math>x_n > 4  \Rightarrow  \frac{1}{2}x_n > 2</math> 
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    -<math>x_n</math> is greater than 4, so half of <math>x_n</math> is greater than 2
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    <math>\frac{1}{2}x_n > 2    \Rightarrow    \frac{1}{2}x_n + 2> 2 + 2    \Rightarrow  \frac{1}{2}x_n + 2 > 4</math> 
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    -Half of <math>x_n</math> is greater than 2, so adding 2 to both sides, the left hand side is greater than 4.
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    <math>\frac{1}{2}x_n + 2 = x_{n+1}</math>, therefore <math>x_{n+1}</math> > 4, so the series (<math>x_n</math>) is bounded below by 4
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    -More specifically, 4 is the infimum of the sequence
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b) Show that sequence (<math>x_n</math>) is monotone
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    -The sequence is bounded below by 4, from above
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    <math>\forall y > 4 \in \Re, (y - \frac{1}{2}y) > 2</math> 
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    -For all real y greater than 4, the distance, or length, between y and half of y is greater than 2 units
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    <math>\forall y > 4 \in \Re, y > \frac{1}{2}y + 2</math>
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    -Then for all real y greater than 4, adding 2 units to half of y is always less than the original y
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    <math>x_n > \frac{1}{2}x_n + 2 \Rightarrow x_n > x_{n+1}</math>
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    -Therefore, <math>x_n</math> always being greater than 4, <math>x_n</math> is always greater than <math>x_{n+1}</math>
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    -The sequence is therefore decreasing, and by '''3.3.1 Definition''', the sequence is monotone
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c) What conclusions can you draw from parts a) and b) about the convergence of (<math>x_n</math>)?
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    -The sequence (<math>x_n</math>) is monotone and bounded on (4,8], so it is convergent by '''3.3.2 Monotone Convergence Theorem'''
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d) If the sequence (<math>x_n</math>) is convergent, what is the limit of the sequence? 
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    <math>\lim_{x\to\infty}(x_n) = 4</math>
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    -By part '''(b)''' of '''3.3.2 Monotone Convergence Theorem''', for (<math>x_n</math>) being a bounded decreasing sequence, the limit
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      of the sequence is equal to its infimum
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'''PROBLEM 3'''

Latest revision as of 12:01, 18 April 2010

Use this page to submit solutions for the test 2. Extra credit will be given to those who will submit solutions, notice and help correct mistakes in the solutions submitted by other students, develop alternative solutions, participate actively in the discussion.

Please, if you made any contributions to the content of this page, also notify the professor by sending a short e-mail.


go back to the Discussion Page


PROBLEM 1

1.a. A sequence ($ x_n $) is said to be a Cauchy sequence if

     -Choice 2 by 3.5.1 Definition

1.b. The statement of the Bolzano-Weierstrass theorem is:

     -Choice 3 by 3.4.8 Theorem

1.c. Let $ f: A \mapsto \Re $. Suppose that $ (a,\infty) \subset A $ for some $ a \in \Re $. We say the limit of f as $ x \rightarrow \infty $ and write $ \lim_{x\to\infty}f = L $

     -Choice 5 by 4.3.10 Definition

1.d. Let $ A \subset \Re $, let $ f: A \mapsto \Re $, and let $ c \in A $. We say that f is continuous at c if

     -Choice 4 by 5.5.1 Definition


PROBLEM 2

Let $ x_1 := 8 $ and $ x_{n+1} := \frac{1}{2}x_n + 2 $ for $ n \in N $

a) Use induction to show that ($ x_n $) is bounded below by 4.

    -Base case $ x_1 = 8 $, so $ x_1 > 4 $
    -Assume $ x_n > 4 $; is $ x_{n+1} > 4 $?
    $ x_n > 4  \Rightarrow  \frac{1}{2}x_n > 2 $  
    -$ x_n $ is greater than 4, so half of $ x_n $ is greater than 2
    
    $ \frac{1}{2}x_n > 2    \Rightarrow    \frac{1}{2}x_n + 2> 2 + 2    \Rightarrow   \frac{1}{2}x_n + 2 > 4 $  
    -Half of $ x_n $ is greater than 2, so adding 2 to both sides, the left hand side is greater than 4.
    $ \frac{1}{2}x_n + 2 = x_{n+1} $, therefore $ x_{n+1} $ > 4, so the series ($ x_n $) is bounded below by 4
    
    -More specifically, 4 is the infimum of the sequence

b) Show that sequence ($ x_n $) is monotone

    -The sequence is bounded below by 4, from above
    
    $ \forall y > 4 \in \Re, (y - \frac{1}{2}y) > 2 $  
    -For all real y greater than 4, the distance, or length, between y and half of y is greater than 2 units
    $ \forall y > 4 \in \Re, y > \frac{1}{2}y + 2 $
    -Then for all real y greater than 4, adding 2 units to half of y is always less than the original y
    $ x_n > \frac{1}{2}x_n + 2 \Rightarrow x_n > x_{n+1} $
    -Therefore, $ x_n $ always being greater than 4, $ x_n $ is always greater than $ x_{n+1} $
    -The sequence is therefore decreasing, and by 3.3.1 Definition, the sequence is monotone

c) What conclusions can you draw from parts a) and b) about the convergence of ($ x_n $)?

    -The sequence ($ x_n $) is monotone and bounded on (4,8], so it is convergent by 3.3.2 Monotone Convergence Theorem

d) If the sequence ($ x_n $) is convergent, what is the limit of the sequence?

    $ \lim_{x\to\infty}(x_n) = 4 $
    -By part (b) of 3.3.2 Monotone Convergence Theorem, for ($ x_n $) being a bounded decreasing sequence, the limit 
     of the sequence is equal to its infimum


PROBLEM 3

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Abstract algebra continues the conceptual developments of linear algebra, on an even grander scale.

Dr. Paul Garrett