Determine if $f(z) = log(e^z+1)$ is analytic and where
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I tried to substitute $z$ with $x+iy$ and then write it down as $f(z) = log(e^xcis(iy)+1) $ but it looks worse than the starting point. on original branch
complex-analysis analyticity
asked Jan 2 at 20:07
no0obno0ob
788
$endgroup$
|
show 5 more comments
$begingroup$
I tried to substitute $z$ with $x+iy$ and then write it down as $f(z) = log(e^xcis(iy)+1) $ but it looks worse than the starting point. on original branch
complex-analysis analyticity
asked Jan 2 at 20:07
no0obno0ob
788
$endgroup$
1
$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
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– Robert Israel
Jan 2 at 20:16
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@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
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– no0ob
Jan 2 at 20:20
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@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
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– no0ob
Jan 2 at 20:29
1
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Look at previous comment. $u=ln(r), v=theta$.
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– herb steinberg
Jan 3 at 2:20
1
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31
|
show 5 more comments
$begingroup$
I tried to substitute $z$ with $x+iy$ and then write it down as $f(z) = log(e^xcis(iy)+1) $ but it looks worse than the starting point. on original branch
complex-analysis analyticity
asked Jan 2 at 20:07
no0obno0ob
788
$endgroup$
I tried to substitute $z$ with $x+iy$ and then write it down as $f(z) = log(e^xcis(iy)+1) $ but it looks worse than the starting point. on original branch
complex-analysis analyticity
complex-analysis analyticity
asked Jan 2 at 20:07
no0obno0ob
788
asked Jan 2 at 20:07
no0obno0ob
788
edited Jan 2 at 21:33
no0ob
asked Jan 2 at 20:07
no0obno0ob
788
asked Jan 2 at 20:07
no0obno0ob
788
asked Jan 2 at 20:07
no0obno0ob
788
788
1
$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
$endgroup$
– Robert Israel
Jan 2 at 20:16
$begingroup$
@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
$endgroup$
– no0ob
Jan 2 at 20:20
$begingroup$
@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
$endgroup$
– no0ob
Jan 2 at 20:29
1
$begingroup$
Look at previous comment. $u=ln(r), v=theta$.
$endgroup$
– herb steinberg
Jan 3 at 2:20
1
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31
|
show 5 more comments
1
$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
$endgroup$
– Robert Israel
Jan 2 at 20:16
$begingroup$
@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
$endgroup$
– no0ob
Jan 2 at 20:20
$begingroup$
@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
$endgroup$
– no0ob
Jan 2 at 20:29
1
$begingroup$
Look at previous comment. $u=ln(r), v=theta$.
$endgroup$
– herb steinberg
Jan 3 at 2:20
1
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31
1
1
$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
$endgroup$
– Robert Israel
Jan 2 at 20:16
$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
$endgroup$
– Robert Israel
Jan 2 at 20:16
$begingroup$
@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
$endgroup$
– no0ob
Jan 2 at 20:20
$begingroup$
@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
$endgroup$
– no0ob
Jan 2 at 20:20
$begingroup$
@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
$endgroup$
– no0ob
Jan 2 at 20:29
$begingroup$
@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
$endgroup$
– no0ob
Jan 2 at 20:29
1
1
$begingroup$
Look at previous comment. $u=ln(r), v=theta$.
$endgroup$
– herb steinberg
Jan 3 at 2:20
$begingroup$
Look at previous comment. $u=ln(r), v=theta$.
$endgroup$
– herb steinberg
Jan 3 at 2:20
1
1
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31
|
show 5 more comments
3 Answers
3
active
oldest
votes
$begingroup$
You're using the branch of logarithm that is analytic on the complement of the left half-line $B = (-infty, 0]$. So your function is analytic at $z$ as long as $e^z+1 notin B$, i.e. $e^z notin (-infty, -1]$.
Now if $z = x + i y$ with $x, y$ real, $e^z = e^x e^{i y}$. For this to be in $B$, you need $y = (2n+1) pi$ with for integer $n$ (so that $e^{iy} = -1$) and $x ge 0$ (so $|e^z| = e^x ge 1$). Thus your function is analytic on the complement of
the half-lines $y = (2n+1) pi$, $x ge 0$.
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
$endgroup$
add a comment |
$begingroup$
Summary of previous comments plus.
Convert $e^z+1$ to a form $re^{itheta}$ Then $ln$ will be $ln(r)+itheta=u+iv$ for Cauchy-Riemann equations to check analytics. $e^z+1=e^xcosy+1+ie^xsiny$. Therefore $r^2=(e^xcosy+1)^2+(e^xsiny)^2$, $theta=arctan(frac{siny}{cosy+e^{−x}})$.
For Cauchy-Riemann you could use $u=frac{ln(r^2)}{2}$. Also note that although $theta$ has two possible values, they differ by a constant ($pi$), so it doesn't effect the analysis.
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
$endgroup$
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
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– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
add a comment |
$begingroup$
According to the determination of logarythm you saw, you should know on which domain the complex logarithm is holomorphic.
The question would be : can the function exp(z) + 1 go outside of this domain ?
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
$endgroup$
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
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Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
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– no0ob
Jan 2 at 20:31
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
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– Cauchy is my master
Jan 2 at 20:44
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so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
|
show 1 more comment
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3 Answers
3
active
oldest
votes
3 Answers
3
active
oldest
votes
active
oldest
votes
active
oldest
votes
$begingroup$
You're using the branch of logarithm that is analytic on the complement of the left half-line $B = (-infty, 0]$. So your function is analytic at $z$ as long as $e^z+1 notin B$, i.e. $e^z notin (-infty, -1]$.
Now if $z = x + i y$ with $x, y$ real, $e^z = e^x e^{i y}$. For this to be in $B$, you need $y = (2n+1) pi$ with for integer $n$ (so that $e^{iy} = -1$) and $x ge 0$ (so $|e^z| = e^x ge 1$). Thus your function is analytic on the complement of
the half-lines $y = (2n+1) pi$, $x ge 0$.
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
$endgroup$
add a comment |
$begingroup$
You're using the branch of logarithm that is analytic on the complement of the left half-line $B = (-infty, 0]$. So your function is analytic at $z$ as long as $e^z+1 notin B$, i.e. $e^z notin (-infty, -1]$.
Now if $z = x + i y$ with $x, y$ real, $e^z = e^x e^{i y}$. For this to be in $B$, you need $y = (2n+1) pi$ with for integer $n$ (so that $e^{iy} = -1$) and $x ge 0$ (so $|e^z| = e^x ge 1$). Thus your function is analytic on the complement of
the half-lines $y = (2n+1) pi$, $x ge 0$.
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
$endgroup$
add a comment |
$begingroup$
You're using the branch of logarithm that is analytic on the complement of the left half-line $B = (-infty, 0]$. So your function is analytic at $z$ as long as $e^z+1 notin B$, i.e. $e^z notin (-infty, -1]$.
Now if $z = x + i y$ with $x, y$ real, $e^z = e^x e^{i y}$. For this to be in $B$, you need $y = (2n+1) pi$ with for integer $n$ (so that $e^{iy} = -1$) and $x ge 0$ (so $|e^z| = e^x ge 1$). Thus your function is analytic on the complement of
the half-lines $y = (2n+1) pi$, $x ge 0$.
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
$endgroup$
You're using the branch of logarithm that is analytic on the complement of the left half-line $B = (-infty, 0]$. So your function is analytic at $z$ as long as $e^z+1 notin B$, i.e. $e^z notin (-infty, -1]$.
Now if $z = x + i y$ with $x, y$ real, $e^z = e^x e^{i y}$. For this to be in $B$, you need $y = (2n+1) pi$ with for integer $n$ (so that $e^{iy} = -1$) and $x ge 0$ (so $|e^z| = e^x ge 1$). Thus your function is analytic on the complement of
the half-lines $y = (2n+1) pi$, $x ge 0$.
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
answered Jan 3 at 4:42
Robert IsraelRobert Israel
330k23218473
330k23218473
add a comment |
add a comment |
$begingroup$
Summary of previous comments plus.
Convert $e^z+1$ to a form $re^{itheta}$ Then $ln$ will be $ln(r)+itheta=u+iv$ for Cauchy-Riemann equations to check analytics. $e^z+1=e^xcosy+1+ie^xsiny$. Therefore $r^2=(e^xcosy+1)^2+(e^xsiny)^2$, $theta=arctan(frac{siny}{cosy+e^{−x}})$.
For Cauchy-Riemann you could use $u=frac{ln(r^2)}{2}$. Also note that although $theta$ has two possible values, they differ by a constant ($pi$), so it doesn't effect the analysis.
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
$endgroup$
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
add a comment |
$begingroup$
Summary of previous comments plus.
Convert $e^z+1$ to a form $re^{itheta}$ Then $ln$ will be $ln(r)+itheta=u+iv$ for Cauchy-Riemann equations to check analytics. $e^z+1=e^xcosy+1+ie^xsiny$. Therefore $r^2=(e^xcosy+1)^2+(e^xsiny)^2$, $theta=arctan(frac{siny}{cosy+e^{−x}})$.
For Cauchy-Riemann you could use $u=frac{ln(r^2)}{2}$. Also note that although $theta$ has two possible values, they differ by a constant ($pi$), so it doesn't effect the analysis.
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
$endgroup$
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
add a comment |
$begingroup$
Summary of previous comments plus.
Convert $e^z+1$ to a form $re^{itheta}$ Then $ln$ will be $ln(r)+itheta=u+iv$ for Cauchy-Riemann equations to check analytics. $e^z+1=e^xcosy+1+ie^xsiny$. Therefore $r^2=(e^xcosy+1)^2+(e^xsiny)^2$, $theta=arctan(frac{siny}{cosy+e^{−x}})$.
For Cauchy-Riemann you could use $u=frac{ln(r^2)}{2}$. Also note that although $theta$ has two possible values, they differ by a constant ($pi$), so it doesn't effect the analysis.
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
$endgroup$
Summary of previous comments plus.
Convert $e^z+1$ to a form $re^{itheta}$ Then $ln$ will be $ln(r)+itheta=u+iv$ for Cauchy-Riemann equations to check analytics. $e^z+1=e^xcosy+1+ie^xsiny$. Therefore $r^2=(e^xcosy+1)^2+(e^xsiny)^2$, $theta=arctan(frac{siny}{cosy+e^{−x}})$.
For Cauchy-Riemann you could use $u=frac{ln(r^2)}{2}$. Also note that although $theta$ has two possible values, they differ by a constant ($pi$), so it doesn't effect the analysis.
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
edited Jan 3 at 17:06
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
answered Jan 3 at 4:35
herb steinbergherb steinberg
3,0782311
3,0782311
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
add a comment |
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
I can't find relation between $r$ and $theta$ so i could write function as $u(r,theta) + iv(r,theta)$
$endgroup$
– no0ob
Jan 3 at 12:41
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
$ln(e^z+1)=ln(r)+itheta$. Therefore $u=ln(r)=frac{ln(r^2)}{2}$ and $v=theta$
$endgroup$
– herb steinberg
Jan 3 at 17:02
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
Aha Cauchy-Reimann is always correct for the $ln(r)+itheta$ now we have to check where does $ln(r)$ available for $r^2 = (e^xcos y+1)^2+(e^xsin y)^2$ and check domain of $arctan(frac{sin(y)}{cos(y)+e^{-x}}) $ and we are OK right?
$endgroup$
– no0ob
Jan 3 at 19:58
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
I mean $ln(r)+itheta$ is analytic everywhere except $0$ and negative $x$ axis
$endgroup$
– no0ob
Jan 3 at 20:05
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
$begingroup$
This ends up as $z=x+ipi$ with $xle 0$.
$endgroup$
– herb steinberg
Jan 3 at 21:12
add a comment |
$begingroup$
According to the determination of logarythm you saw, you should know on which domain the complex logarithm is holomorphic.
The question would be : can the function exp(z) + 1 go outside of this domain ?
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
$endgroup$
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
|
show 1 more comment
$begingroup$
According to the determination of logarythm you saw, you should know on which domain the complex logarithm is holomorphic.
The question would be : can the function exp(z) + 1 go outside of this domain ?
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
$endgroup$
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
|
show 1 more comment
$begingroup$
According to the determination of logarythm you saw, you should know on which domain the complex logarithm is holomorphic.
The question would be : can the function exp(z) + 1 go outside of this domain ?
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
$endgroup$
According to the determination of logarythm you saw, you should know on which domain the complex logarithm is holomorphic.
The question would be : can the function exp(z) + 1 go outside of this domain ?
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
answered Jan 2 at 20:19
Cauchy is my masterCauchy is my master
413
413
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
|
show 1 more comment
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
1
1
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
actually i better asked determine analytical area.
$endgroup$
– no0ob
Jan 2 at 20:22
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
Then the question would be the following: for which z does exp(z) + 1 belong to the analytical area of the logarithm?
$endgroup$
– Cauchy is my master
Jan 2 at 20:24
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
$begingroup$
I think that's correct, and ln(z) is analytic in all of the plane but $xle0$ right? for the original branch
$endgroup$
– no0ob
Jan 2 at 20:31
1
1
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
That depends on the determination of argument you chose, but I think you chose the usual one, so it's correct.
$endgroup$
– Cauchy is my master
Jan 2 at 20:44
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
$begingroup$
so now i should use function composition or sth? or is it possible to do it with the Cauchy-Reimann equation?
$endgroup$
– no0ob
Jan 2 at 20:51
|
show 1 more comment
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$begingroup$
Analytic where? The composition of analytic functions is analytic. But you have to be careful with $ln$: what branch are you using?
$endgroup$
– Robert Israel
Jan 2 at 20:16
$begingroup$
@RobertIsrael Actually it's a warmup problem for my next week exam, and i'm hell of a newbie to this section, so i think the point is to determine where is analytical area of this function.
$endgroup$
– no0ob
Jan 2 at 20:20
$begingroup$
@RobertIsrael after reading my note i think your answer is $-pi lt theta le pi$
$endgroup$
– no0ob
Jan 2 at 20:29
1
$begingroup$
Look at previous comment. $u=ln(r), v=theta$.
$endgroup$
– herb steinberg
Jan 3 at 2:20
1
$begingroup$
$theta$ has two possible values. To get the correct one, use $sintheta = frac{e^xsiny}{r}$ and $costheta=frac{e^xcosy+1}{r}$..
$endgroup$
– herb steinberg
Jan 3 at 2:31