Try substitution
x=8u
dx=8du
x^2=64u^2
I=dx/(64+x^2)=8du/[64(64+64u^2)]
=(1/8)du/(1+u^2)
which is a standard integral.
Evaluate the indefinite integral:
INT dx/(64+x^2)^2
Please help with this one.
3 answers
You can use the method exlained in this posting
http://www.jiskha.com/display.cgi?id=1316565092#1316565092.1316570036
So, we have:
f(x) = 1/(64+x^2)^2
We can factor the denominator as:
(64+x^2)^2 = (x-8 i)^2 (x+8 i)^2
Expand around x = 8 i, by putting:
x = 8 i + t:
f(8i + t) = 1/t^2 1/(16 i + t)^2
We need to expand 1/(16 i + t)^2 to first order in t to get all the singular terms:
1/(16 i + t)^2 =
1/(16 i)^2 1/[1+t/(16i)]^2 =
-1/256 [1 + 8 i t + terms of order t^2 and higher]
So, we have:
f(8i + t) =
-1/256 1/t^2 - i/2048 1/t + non-singular terms
In terms of x, this is:
f(x) = -1/256 1/(x-8 i)^2 -
i/2048 1/(x-8 i) + non-singular terms
Let's call the singular part of thsis expansion s(x):
s(x) = -1/256 1/(x-8 i)^2 -
i/2048 1/(x-8 i)
The singularpart of the expansion around -8i can be found in a similar way, let's call this r(x). Before computing this, consider the ficntion:
g(x) = f(x) - s(x) - r(x)
This is a rational function, but because we've subtracted te singularitoes from f(x) it doesn't have any singularities anymore, therefore it is a polynomial. At infinity, it tends to zero, therefore g(x) is identically zero and we have:
f(x) = s(x) + r(x)
Because f(x) for real x assumes real values, it follows that for real x,
r(x) is the complex conjugate of
s(x). We thus have:
r(x) = -1/256 1/(x+8 i)^2 +
i/2048 1/(x+8 i)
And thus:
f(x) = -1/256 1/(x-8i)^2
-1/256 1/(x+8i)^2 + i/2048 1/(x+8 i) - i/2048 1/(x-8 i)
The first two terms can be directly integrated:
Integral of[ -1/256 1/(x-8i)^2
-1/256 1/(x+8i)^2 ] dx =
1/256 [1/(x-8i) + 1/(x+8i)] =
1/128 x/(x^2 + 64)
The last to terms can be added together before we integrtate to avoid having to deal with complex logarithms:
i/2048 1/(x+8 i) - i/2048 1/(x-8 i) =
i/2048 * (-16 i)/(x^2 + 64) =
1/28 1/(x^2 + 64)
The integral of this is
1/1024 arctan(x/8)
If instead you integrate the last two terms, term by term you get:
i/2048 Log[(x+8 i)/(x-8i)]
Since x is real, the numerator is the complex conjugate of the denominator. The argument of the logarithm thus has a modulus of 1. This means that:
(x+8 i)/(x-8i) = exp(i theta)
for some real theta. You can also see this by writing:
x + 8 i = r exp(i alpha)
Then
x - 8 i = r exp(-i alpha)
The ratio is this
(x+8 i)/(x-8i) = exp(i 2 alpha)
But alpha is, of course, given by:
alpha = arctan(8/x)
So, we have:
Log[(x+8 i)/(x-8i)] =
2 i arctan (8/x)
Multiplying by i/2048 gives the integral:
-1/1024 arctan (8/x) =
1/1024 [arctan(x/8) - pi/2]
The term pi/2 in the brackets can be absorbed into the integration constant.
http://www.jiskha.com/display.cgi?id=1316565092#1316565092.1316570036
So, we have:
f(x) = 1/(64+x^2)^2
We can factor the denominator as:
(64+x^2)^2 = (x-8 i)^2 (x+8 i)^2
Expand around x = 8 i, by putting:
x = 8 i + t:
f(8i + t) = 1/t^2 1/(16 i + t)^2
We need to expand 1/(16 i + t)^2 to first order in t to get all the singular terms:
1/(16 i + t)^2 =
1/(16 i)^2 1/[1+t/(16i)]^2 =
-1/256 [1 + 8 i t + terms of order t^2 and higher]
So, we have:
f(8i + t) =
-1/256 1/t^2 - i/2048 1/t + non-singular terms
In terms of x, this is:
f(x) = -1/256 1/(x-8 i)^2 -
i/2048 1/(x-8 i) + non-singular terms
Let's call the singular part of thsis expansion s(x):
s(x) = -1/256 1/(x-8 i)^2 -
i/2048 1/(x-8 i)
The singularpart of the expansion around -8i can be found in a similar way, let's call this r(x). Before computing this, consider the ficntion:
g(x) = f(x) - s(x) - r(x)
This is a rational function, but because we've subtracted te singularitoes from f(x) it doesn't have any singularities anymore, therefore it is a polynomial. At infinity, it tends to zero, therefore g(x) is identically zero and we have:
f(x) = s(x) + r(x)
Because f(x) for real x assumes real values, it follows that for real x,
r(x) is the complex conjugate of
s(x). We thus have:
r(x) = -1/256 1/(x+8 i)^2 +
i/2048 1/(x+8 i)
And thus:
f(x) = -1/256 1/(x-8i)^2
-1/256 1/(x+8i)^2 + i/2048 1/(x+8 i) - i/2048 1/(x-8 i)
The first two terms can be directly integrated:
Integral of[ -1/256 1/(x-8i)^2
-1/256 1/(x+8i)^2 ] dx =
1/256 [1/(x-8i) + 1/(x+8i)] =
1/128 x/(x^2 + 64)
The last to terms can be added together before we integrtate to avoid having to deal with complex logarithms:
i/2048 1/(x+8 i) - i/2048 1/(x-8 i) =
i/2048 * (-16 i)/(x^2 + 64) =
1/28 1/(x^2 + 64)
The integral of this is
1/1024 arctan(x/8)
If instead you integrate the last two terms, term by term you get:
i/2048 Log[(x+8 i)/(x-8i)]
Since x is real, the numerator is the complex conjugate of the denominator. The argument of the logarithm thus has a modulus of 1. This means that:
(x+8 i)/(x-8i) = exp(i theta)
for some real theta. You can also see this by writing:
x + 8 i = r exp(i alpha)
Then
x - 8 i = r exp(-i alpha)
The ratio is this
(x+8 i)/(x-8i) = exp(i 2 alpha)
But alpha is, of course, given by:
alpha = arctan(8/x)
So, we have:
Log[(x+8 i)/(x-8i)] =
2 i arctan (8/x)
Multiplying by i/2048 gives the integral:
-1/1024 arctan (8/x) =
1/1024 [arctan(x/8) - pi/2]
The term pi/2 in the brackets can be absorbed into the integration constant.
Thank you Count-Iblis, I did not notice the square in the denominator.
So Carmen, please do not take into account my solution above.
So Carmen, please do not take into account my solution above.
1 answer