Holomorphic integrals
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I am struggling to understand how the center and radius effect a certain circular contour.
e.g. $ int _{gamma} frac {z^{2}+1} {e^{z}(z-1)(z+1)^{2}} dz $
can anyone explain this?
integration complex-analysis complex-numbers cauchy-integral-formula
asked Nov 21 at 12:04
frankfields
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up vote
0
down vote
favorite
I am struggling to understand how the center and radius effect a certain circular contour.
e.g. $ int _{gamma} frac {z^{2}+1} {e^{z}(z-1)(z+1)^{2}} dz $
can anyone explain this?
integration complex-analysis complex-numbers cauchy-integral-formula
asked Nov 21 at 12:04
frankfields
113
add a comment |
up vote
0
down vote
favorite
up vote
0
down vote
favorite
I am struggling to understand how the center and radius effect a certain circular contour.
e.g. $ int _{gamma} frac {z^{2}+1} {e^{z}(z-1)(z+1)^{2}} dz $
can anyone explain this?
integration complex-analysis complex-numbers cauchy-integral-formula
asked Nov 21 at 12:04
frankfields
113
I am struggling to understand how the center and radius effect a certain circular contour.
e.g. $ int _{gamma} frac {z^{2}+1} {e^{z}(z-1)(z+1)^{2}} dz $
can anyone explain this?
integration complex-analysis complex-numbers cauchy-integral-formula
integration complex-analysis complex-numbers cauchy-integral-formula
asked Nov 21 at 12:04
frankfields
113
asked Nov 21 at 12:04
frankfields
113
asked Nov 21 at 12:04
frankfields
113
asked Nov 21 at 12:04
frankfields
113
asked Nov 21 at 12:04
frankfields
113
113
add a comment |
add a comment |
1 Answer
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In general, if $gamma$ is a closed contour, then the Residue Theorem tells us that
$$int_gamma f(z),dz = 2pi isum_{z_i}text{Res}left(f(z),z_iright)$$
where $z_i$ are the poles of the meromorphic function $f(z)$ that are enclosed within the contour of integration $gamma$.
In particular, the value of the integral does not actually depend on, say, the radius of the circle or its center as long as the poles enclosed by the contour of integration do not change.
In your example, we have
$$f(z) = frac{z^2+1}{e^z(z-1)(z+1)^2}$$
which has a simple pole at $z_1 = 1$ and a pole of order $2$ at $z_2 = -1$.
If we choose a circular contour $gamma$ that enclosed both of these poles, like the circle with radius $2$ centered at the origin for example, then we obtain
begin{align}
int_gamma f(z),dz &= 2pi ileft[text{Res}left(f(z), 1right) + text{Res}left(f(z), -1right)right]\
&= 2pi ileft[limlimits_{zrightarrow 1} frac{z^2+1}{e^{z}(z+1)^2} + limlimits_{zto -1}frac{d}{dz}frac{z^2+1}{e^{z}(z-1)}right]\
&=2pi ileft[frac{1}{2e} + limlimits_{zto -1}frac{x(x^2-2x+3}{e^x(x-1)^2}right]\
&=2pi ileft[frac{1}{2e} + frac{3e}{2}right]\
&=frac{pi i}{e}left(1+3e^2right)
end{align}
As specified earlier, any other circular, or indeed closed contour that contains both of the poles of $f(z)$ in its interior will yield the same result.
answered Nov 21 at 13:45
Tom
2,711315
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
add a comment |
1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
up vote
0
down vote
In general, if $gamma$ is a closed contour, then the Residue Theorem tells us that
$$int_gamma f(z),dz = 2pi isum_{z_i}text{Res}left(f(z),z_iright)$$
where $z_i$ are the poles of the meromorphic function $f(z)$ that are enclosed within the contour of integration $gamma$.
In particular, the value of the integral does not actually depend on, say, the radius of the circle or its center as long as the poles enclosed by the contour of integration do not change.
In your example, we have
$$f(z) = frac{z^2+1}{e^z(z-1)(z+1)^2}$$
which has a simple pole at $z_1 = 1$ and a pole of order $2$ at $z_2 = -1$.
If we choose a circular contour $gamma$ that enclosed both of these poles, like the circle with radius $2$ centered at the origin for example, then we obtain
begin{align}
int_gamma f(z),dz &= 2pi ileft[text{Res}left(f(z), 1right) + text{Res}left(f(z), -1right)right]\
&= 2pi ileft[limlimits_{zrightarrow 1} frac{z^2+1}{e^{z}(z+1)^2} + limlimits_{zto -1}frac{d}{dz}frac{z^2+1}{e^{z}(z-1)}right]\
&=2pi ileft[frac{1}{2e} + limlimits_{zto -1}frac{x(x^2-2x+3}{e^x(x-1)^2}right]\
&=2pi ileft[frac{1}{2e} + frac{3e}{2}right]\
&=frac{pi i}{e}left(1+3e^2right)
end{align}
As specified earlier, any other circular, or indeed closed contour that contains both of the poles of $f(z)$ in its interior will yield the same result.
answered Nov 21 at 13:45
Tom
2,711315
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
add a comment |
up vote
0
down vote
In general, if $gamma$ is a closed contour, then the Residue Theorem tells us that
$$int_gamma f(z),dz = 2pi isum_{z_i}text{Res}left(f(z),z_iright)$$
where $z_i$ are the poles of the meromorphic function $f(z)$ that are enclosed within the contour of integration $gamma$.
In particular, the value of the integral does not actually depend on, say, the radius of the circle or its center as long as the poles enclosed by the contour of integration do not change.
In your example, we have
$$f(z) = frac{z^2+1}{e^z(z-1)(z+1)^2}$$
which has a simple pole at $z_1 = 1$ and a pole of order $2$ at $z_2 = -1$.
If we choose a circular contour $gamma$ that enclosed both of these poles, like the circle with radius $2$ centered at the origin for example, then we obtain
begin{align}
int_gamma f(z),dz &= 2pi ileft[text{Res}left(f(z), 1right) + text{Res}left(f(z), -1right)right]\
&= 2pi ileft[limlimits_{zrightarrow 1} frac{z^2+1}{e^{z}(z+1)^2} + limlimits_{zto -1}frac{d}{dz}frac{z^2+1}{e^{z}(z-1)}right]\
&=2pi ileft[frac{1}{2e} + limlimits_{zto -1}frac{x(x^2-2x+3}{e^x(x-1)^2}right]\
&=2pi ileft[frac{1}{2e} + frac{3e}{2}right]\
&=frac{pi i}{e}left(1+3e^2right)
end{align}
As specified earlier, any other circular, or indeed closed contour that contains both of the poles of $f(z)$ in its interior will yield the same result.
answered Nov 21 at 13:45
Tom
2,711315
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
add a comment |
up vote
0
down vote
up vote
0
down vote
In general, if $gamma$ is a closed contour, then the Residue Theorem tells us that
$$int_gamma f(z),dz = 2pi isum_{z_i}text{Res}left(f(z),z_iright)$$
where $z_i$ are the poles of the meromorphic function $f(z)$ that are enclosed within the contour of integration $gamma$.
In particular, the value of the integral does not actually depend on, say, the radius of the circle or its center as long as the poles enclosed by the contour of integration do not change.
In your example, we have
$$f(z) = frac{z^2+1}{e^z(z-1)(z+1)^2}$$
which has a simple pole at $z_1 = 1$ and a pole of order $2$ at $z_2 = -1$.
If we choose a circular contour $gamma$ that enclosed both of these poles, like the circle with radius $2$ centered at the origin for example, then we obtain
begin{align}
int_gamma f(z),dz &= 2pi ileft[text{Res}left(f(z), 1right) + text{Res}left(f(z), -1right)right]\
&= 2pi ileft[limlimits_{zrightarrow 1} frac{z^2+1}{e^{z}(z+1)^2} + limlimits_{zto -1}frac{d}{dz}frac{z^2+1}{e^{z}(z-1)}right]\
&=2pi ileft[frac{1}{2e} + limlimits_{zto -1}frac{x(x^2-2x+3}{e^x(x-1)^2}right]\
&=2pi ileft[frac{1}{2e} + frac{3e}{2}right]\
&=frac{pi i}{e}left(1+3e^2right)
end{align}
As specified earlier, any other circular, or indeed closed contour that contains both of the poles of $f(z)$ in its interior will yield the same result.
answered Nov 21 at 13:45
Tom
2,711315
In general, if $gamma$ is a closed contour, then the Residue Theorem tells us that
$$int_gamma f(z),dz = 2pi isum_{z_i}text{Res}left(f(z),z_iright)$$
where $z_i$ are the poles of the meromorphic function $f(z)$ that are enclosed within the contour of integration $gamma$.
In particular, the value of the integral does not actually depend on, say, the radius of the circle or its center as long as the poles enclosed by the contour of integration do not change.
In your example, we have
$$f(z) = frac{z^2+1}{e^z(z-1)(z+1)^2}$$
which has a simple pole at $z_1 = 1$ and a pole of order $2$ at $z_2 = -1$.
If we choose a circular contour $gamma$ that enclosed both of these poles, like the circle with radius $2$ centered at the origin for example, then we obtain
begin{align}
int_gamma f(z),dz &= 2pi ileft[text{Res}left(f(z), 1right) + text{Res}left(f(z), -1right)right]\
&= 2pi ileft[limlimits_{zrightarrow 1} frac{z^2+1}{e^{z}(z+1)^2} + limlimits_{zto -1}frac{d}{dz}frac{z^2+1}{e^{z}(z-1)}right]\
&=2pi ileft[frac{1}{2e} + limlimits_{zto -1}frac{x(x^2-2x+3}{e^x(x-1)^2}right]\
&=2pi ileft[frac{1}{2e} + frac{3e}{2}right]\
&=frac{pi i}{e}left(1+3e^2right)
end{align}
As specified earlier, any other circular, or indeed closed contour that contains both of the poles of $f(z)$ in its interior will yield the same result.
answered Nov 21 at 13:45
Tom
2,711315
answered Nov 21 at 13:45
Tom
2,711315
answered Nov 21 at 13:45
Tom
2,711315
answered Nov 21 at 13:45
Tom
2,711315
2,711315
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
add a comment |
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
Thank you, what if only one of the poles of f(z) is within the interior?
– frankfields
Nov 23 at 9:57
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
In that case, you only consider the contribution of that pole. For example, if you were to consider a contour that only contains the pole at $z=1$ in your example, like a circle centred at $z = 1$ with radius $r = 1$, then the value of the integral is simply $frac{pi i}{e}$, because we only consider the first of the terms in the residue sum.
– Tom
Nov 23 at 12:27
add a comment |
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