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== Homework 8 Collaboration Area ==
 
== Homework 8 Collaboration Area ==
  
Question on problem 15 in Sec 6.6.
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Question on problem 15 in Sec 6.6:
  
 
I tried to obtain the expression for
 
I tried to obtain the expression for
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s/(s + 1)  *  1/(s+1)
 
s/(s + 1)  *  1/(s+1)
  
you'll need to compute the convolution integral:
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via convolution, you'll need to compute the convolution integral:
  
 
<math>\int_0^t \cos(\tau)\sin(t-\tau)\ d\tau.</math>
 
<math>\int_0^t \cos(\tau)\sin(t-\tau)\ d\tau.</math>
  
 
You'll have to use a formula for the sine of the
 
You'll have to use a formula for the sine of the
difference of two angles and be very careful.
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product of cosine and sine.  Here it is:
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(cos A)(sin B) = (1/2)sin(A+B) + (1/2)sin(B-A).
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You'll need to be very careful.
 
Remember,  t  acts like a constant in the integrals.
 
Remember,  t  acts like a constant in the integrals.
  
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of the book, a trig identity might be at fault.)
 
of the book, a trig identity might be at fault.)
  
* Another way to solve this problem is to recognize that the given expression is the derivative of
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Another, and perhaps better, way to solve this problem is to recognize that the given expression is the derivative of
  
 
1 / [(s+2)^2 + 1]]
 
1 / [(s+2)^2 + 1]]
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to get the inverse transform.)   
 
to get the inverse transform.)   
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P.257 #8: I'm a bit confused on how to get this problem started... Based on other problems in this section, we can factor out a t such that the function inside the transform is  t  times f(t) where f(t)=t^(n-1)e^(kt), but I don't see how that helps us much.
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Answer from Bell:  You'll need to use mathematical induction for this problem.  Start with n=1.  Then use the formula
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L[ t f(t) ] = -F'(s)
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to reduce the n=2 case to the n=1 case, etc.
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(AJ) Also, there's a better table of Laplace transforms at the end of chapter 6 that has the transform for f(t) = t^(n-1)e^(kt)
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Yes, but if you wanted to compute the transform the easy way instead of using the differentiation formula from the section, you would probably use
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L[ f(t)e^{at} ] = F(s-a)
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to get
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L[ t^n e^{kt} ] = n!/ (s-k)^{n+1}
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because
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L[ t^n ] = n!/s^{n+1}.
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(That's how they got that formula in the table in an earlier section.)
  
 
[[2010 MA 527 Bell|Back to the MA 527 start page]]  
 
[[2010 MA 527 Bell|Back to the MA 527 start page]]  

Latest revision as of 14:21, 19 October 2010

Homework 8 Collaboration Area

Question on problem 15 in Sec 6.6:

I tried to obtain the expression for

s/(s + 1) * 1/(s+1)

but am not getting the correct result in the Laplace table of

t sin t.

I am using the convolution of cos(tau)*sin(t-tau). There is no t term in sight. Is it okay to read off the table? Even if it is, shouldn't the result be the same?

Answer:

To find the inverse Laplace transform of

s/(s + 1) * 1/(s+1)

via convolution, you'll need to compute the convolution integral:

$ \int_0^t \cos(\tau)\sin(t-\tau)\ d\tau. $

You'll have to use a formula for the sine of the product of cosine and sine. Here it is:

(cos A)(sin B) = (1/2)sin(A+B) + (1/2)sin(B-A).

You'll need to be very careful. Remember, t acts like a constant in the integrals.

There is only one correct answer, so you should get it that way. (If it looks different than the back of the book, a trig identity might be at fault.)

Another, and perhaps better, way to solve this problem is to recognize that the given expression is the derivative of

1 / [(s+2)^2 + 1]]

...therefore greatly simplifying the solution (no trig identities required).

(You'll need to use the formula

L[ t f(t) ] = -F'(s)

to get the inverse transform.)

P.257 #8: I'm a bit confused on how to get this problem started... Based on other problems in this section, we can factor out a t such that the function inside the transform is t times f(t) where f(t)=t^(n-1)e^(kt), but I don't see how that helps us much.

Answer from Bell: You'll need to use mathematical induction for this problem. Start with n=1. Then use the formula

L[ t f(t) ] = -F'(s)

to reduce the n=2 case to the n=1 case, etc.

(AJ) Also, there's a better table of Laplace transforms at the end of chapter 6 that has the transform for f(t) = t^(n-1)e^(kt)

Yes, but if you wanted to compute the transform the easy way instead of using the differentiation formula from the section, you would probably use

L[ f(t)e^{at} ] = F(s-a)

to get

L[ t^n e^{kt} ] = n!/ (s-k)^{n+1}

because

L[ t^n ] = n!/s^{n+1}.

(That's how they got that formula in the table in an earlier section.)

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

Dr. Paul Garrett