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[[Category:homework]]
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== Homework 6 collaboration area  ==
 
== Homework 6 collaboration area  ==
  
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Question from [[User:apiggott|A. Piggott]]
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Section 6.1, problem 1 and 2, I solved with Integration by Parts.
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Question from [[User:Apiggott|A. Piggott]]
  
Is this the least time consuming way to solve them? What is the best way?
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Section 6.1, problem 1 and 2, I solved with Integration by Parts.
  
Also, 6.1, #5, when I solve with integration by parts, I get a solution that always requires another integration by Parts so I am not getting anywhere. Can anyone help on this?
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Is this the least time consuming way to solve them? What is the best way?  
  
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Also, 6.1, #5, when I solve with integration by parts, I get a solution that always requires another integration by Parts so I am not getting anywhere. Can anyone help on this?
  
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'''Response from Mickey Rhoades [[User:Mrhoade|Mrhoade]]'''
  
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I used integration by parts for 1,2, and 5. &nbsp;They weren't too terrible. &nbsp;Obviously, these transforms are covered in the table but going through the motions to transform them was the point. &nbsp;You can check your answers using the table. &nbsp;For #5, I broke sinh(t) into its exponential components and then you get two seperate integrals. you should have one transform of e^(3t) and then a transform of e^t. &nbsp;You should get F(s) = .5/(s-3) - .5/(s-1). You get common denominators and this becomes:
  
I am sort of stuck on Lesson 19 #26:
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1/(s-3)(s-1) &nbsp;= 1/(S^2-4S+3) &nbsp;you then add 1 and subtract 1 on the denominator to complete the square. &nbsp;
  
First of all, are the instructions correct when they say "...if L(F) equals:" --- Is it F or f(t)?
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----
  
Secondly, I am not sure how to proceed with this. Thm 3 says the inverse Laplace is 1/s times the F(s) function. Therefore I can factor out a 1/s^3 to get :
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<br> I am sort of stuck on Lesson 19 #26:  
(1/s^3)*(1/(s^2-1)) ...Not sure where to go from here, or if my approach is wrong...
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Thanks - Mac
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First of all, are the instructions correct when they say "...if L(F) equals:" --- Is it F or f(t)?
  
I think you need to factor out s^2 to get (1/(s^2)*(s^2-1)), also question says inverse transform by integral which is done in example 3. If you will integrate inverse transform of (1/(s^2-1)) i.e., sinh t twice you will get inverse transform of (1/(s^4-s^2)) i.e., sinh t - t. (I am not sure, if I am right)
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Secondly, I am not sure how to proceed with this. Thm 3 says the inverse Laplace is 1/s times the F(s) function. Therefore I can factor out a 1/s^3 to get&nbsp;: (1/s^3)*(1/(s^2-1)) ...Not sure where to go from here, or if my approach is wrong...  
  
-- Kunal
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Thanks - Mac
  
Response from Mickey Rhoades (mrhoade~~)
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I think you need to factor out s^2 to get (1/(s^2)*(s^2-1)), also question says inverse transform by integral which is done in example 3. If you will integrate inverse transform of (1/(s^2-1)) i.e., sinh t twice you will get inverse transform of (1/(s^4-s^2)) i.e., sinh t - t. (I am not sure, if I am right)  
  
I did the same thing and got the same answer.  After the first integration of sinh(t) you get cosh(t) -1 and integrate that to find the solution of sinh(t )- t.
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-- Kunal
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Question from [[User:Roe5|T. Roe]] 21:28, 6 October 2013 (UTC):
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I have a question on Lesson 19 #19.  I have set up the equations as follows:
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Response from Mickey Rhoades (mrhoade~~)
  
<math>\mathcal{L}(f')=s\mathcal{L}(f)-f(0)</math>
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I did the same thing and got the same answer. After the first integration of sinh(t) you get cosh(t) -1 and integrate that to find the solution of sinh(t )- t.
  
<math>f(0)=0</math>
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so
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Question from [[User:Roe5|T. Roe]] 21:28, 6 October 2013 (UTC):
  
<math>\mathcal{L}(f)=\mathcal{L}(f')/s.</math>
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I have a question on Lesson 19 #19. I have set up the equations as follows:
  
Using the information from class I get:
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<math>\mathcal{L}(f')=s\mathcal{L}(f)-f(0)</math>
  
<math>\mathcal{L}(f')=\frac{2\omega}{(s^2+4\omega^2)}</math>
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<span class="texhtml">''f''(0) = 0</span>  
  
and
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so
  
<math>\mathcal{L}(f)=\frac{2\omega}{s(s^2+4\omega^2)},</math>
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<math>\mathcal{L}(f)=\mathcal{L}(f')/s.</math>  
  
but the book as well as mathematica output a solution of
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Using the information from class I get:
  
<math>\mathcal{L}(f)=\frac{2\omega^2}{s(s^2+4\omega^2)}.</math>
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<math>\mathcal{L}(f')=\frac{2\omega}{(s^2+4\omega^2)}</math>
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 +
and
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 +
<math>\mathcal{L}(f)=\frac{2\omega}{s(s^2+4\omega^2)},</math>
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 +
but the book as well as mathematica output a solution of
 +
 
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<math>\mathcal{L}(f)=\frac{2\omega^2}{s(s^2+4\omega^2)}.</math>  
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Can someone explain to me where the extra <span class="texhtml">ω</span> is coming from?
  
Can someone explain to me where the extra <math>\omega</math> is coming from?
 
 
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[[2013_Fall_MA_527_Bell|Back to MA527, Fall 2013]]
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[[2013 Fall MA 527 Bell|Back to MA527, Fall 2013]]
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[[Category:MA527Fall2013Bell]] [[Category:MA527]] [[Category:Math]] [[Category:Homework]]

Revision as of 17:21, 6 October 2013


Homework 6 collaboration area


Question from A. Piggott

Section 6.1, problem 1 and 2, I solved with Integration by Parts.

Is this the least time consuming way to solve them? What is the best way?

Also, 6.1, #5, when I solve with integration by parts, I get a solution that always requires another integration by Parts so I am not getting anywhere. Can anyone help on this?

Response from Mickey Rhoades Mrhoade

I used integration by parts for 1,2, and 5.  They weren't too terrible.  Obviously, these transforms are covered in the table but going through the motions to transform them was the point.  You can check your answers using the table.  For #5, I broke sinh(t) into its exponential components and then you get two seperate integrals. you should have one transform of e^(3t) and then a transform of e^t.  You should get F(s) = .5/(s-3) - .5/(s-1). You get common denominators and this becomes:

1/(s-3)(s-1)  = 1/(S^2-4S+3)  you then add 1 and subtract 1 on the denominator to complete the square.  



I am sort of stuck on Lesson 19 #26:

First of all, are the instructions correct when they say "...if L(F) equals:" --- Is it F or f(t)?

Secondly, I am not sure how to proceed with this. Thm 3 says the inverse Laplace is 1/s times the F(s) function. Therefore I can factor out a 1/s^3 to get : (1/s^3)*(1/(s^2-1)) ...Not sure where to go from here, or if my approach is wrong...

Thanks - Mac

I think you need to factor out s^2 to get (1/(s^2)*(s^2-1)), also question says inverse transform by integral which is done in example 3. If you will integrate inverse transform of (1/(s^2-1)) i.e., sinh t twice you will get inverse transform of (1/(s^4-s^2)) i.e., sinh t - t. (I am not sure, if I am right)

-- Kunal

Response from Mickey Rhoades (mrhoade~~)

I did the same thing and got the same answer. After the first integration of sinh(t) you get cosh(t) -1 and integrate that to find the solution of sinh(t )- t.


Question from T. Roe 21:28, 6 October 2013 (UTC):

I have a question on Lesson 19 #19. I have set up the equations as follows:

$ \mathcal{L}(f')=s\mathcal{L}(f)-f(0) $

f(0) = 0

so

$ \mathcal{L}(f)=\mathcal{L}(f')/s. $

Using the information from class I get:

$ \mathcal{L}(f')=\frac{2\omega}{(s^2+4\omega^2)} $

and

$ \mathcal{L}(f)=\frac{2\omega}{s(s^2+4\omega^2)}, $

but the book as well as mathematica output a solution of

$ \mathcal{L}(f)=\frac{2\omega^2}{s(s^2+4\omega^2)}. $

Can someone explain to me where the extra ω is coming from?


Back to MA527, Fall 2013

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