Find the complex integral
I have
$$int_{gamma} {frac{z}{overline z}}dz$$
where $gamma$ is the edge of ${1 < |z| < 2 $and $Im (z) > 0}$.
I think the way to solve this is to calculate the integral for $|z|=1$ and then $|z|=2$, then subtract the first result from the second one.
For $|z|=1$, the integral is $ipi$. For $|z|=1$, the integral is $4i$. So my answer is $4i-ipi$. But the answer in book is ${frac{4}{3}}$
.
complex-integration
asked Nov 29 at 18:46
user3132457
1336
add a comment |
I have
$$int_{gamma} {frac{z}{overline z}}dz$$
where $gamma$ is the edge of ${1 < |z| < 2 $and $Im (z) > 0}$.
I think the way to solve this is to calculate the integral for $|z|=1$ and then $|z|=2$, then subtract the first result from the second one.
For $|z|=1$, the integral is $ipi$. For $|z|=1$, the integral is $4i$. So my answer is $4i-ipi$. But the answer in book is ${frac{4}{3}}$
.
complex-integration
asked Nov 29 at 18:46
user3132457
1336
Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51
add a comment |
I have
$$int_{gamma} {frac{z}{overline z}}dz$$
where $gamma$ is the edge of ${1 < |z| < 2 $and $Im (z) > 0}$.
I think the way to solve this is to calculate the integral for $|z|=1$ and then $|z|=2$, then subtract the first result from the second one.
For $|z|=1$, the integral is $ipi$. For $|z|=1$, the integral is $4i$. So my answer is $4i-ipi$. But the answer in book is ${frac{4}{3}}$
.
complex-integration
asked Nov 29 at 18:46
user3132457
1336
I have
$$int_{gamma} {frac{z}{overline z}}dz$$
where $gamma$ is the edge of ${1 < |z| < 2 $and $Im (z) > 0}$.
I think the way to solve this is to calculate the integral for $|z|=1$ and then $|z|=2$, then subtract the first result from the second one.
For $|z|=1$, the integral is $ipi$. For $|z|=1$, the integral is $4i$. So my answer is $4i-ipi$. But the answer in book is ${frac{4}{3}}$
.
complex-integration
complex-integration
asked Nov 29 at 18:46
user3132457
1336
asked Nov 29 at 18:46
user3132457
1336
asked Nov 29 at 18:46
user3132457
1336
asked Nov 29 at 18:46
user3132457
1336
asked Nov 29 at 18:46
user3132457
1336
1336
Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51
add a comment |
Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51
Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51
Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51
add a comment |
1 Answer
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Actually, in the upper semi-circle $lvert zrvert=1$, you have$$frac z{overline z}=frac{z^2}{lvert zrvert^2}=z^2$$and therefore the integral (if you move along the semi-circle from the left to the right) is equal to $dfrac23$. By the same argument, the integral along the larger semicircle (this time moving from the right to left) is $-dfrac43$.
Can you take it from here?
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
|
show 2 more comments
Your Answer
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1 Answer
1
active
oldest
votes
1 Answer
1
active
oldest
votes
active
oldest
votes
active
oldest
votes
Actually, in the upper semi-circle $lvert zrvert=1$, you have$$frac z{overline z}=frac{z^2}{lvert zrvert^2}=z^2$$and therefore the integral (if you move along the semi-circle from the left to the right) is equal to $dfrac23$. By the same argument, the integral along the larger semicircle (this time moving from the right to left) is $-dfrac43$.
Can you take it from here?
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
|
show 2 more comments
Actually, in the upper semi-circle $lvert zrvert=1$, you have$$frac z{overline z}=frac{z^2}{lvert zrvert^2}=z^2$$and therefore the integral (if you move along the semi-circle from the left to the right) is equal to $dfrac23$. By the same argument, the integral along the larger semicircle (this time moving from the right to left) is $-dfrac43$.
Can you take it from here?
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
|
show 2 more comments
Actually, in the upper semi-circle $lvert zrvert=1$, you have$$frac z{overline z}=frac{z^2}{lvert zrvert^2}=z^2$$and therefore the integral (if you move along the semi-circle from the left to the right) is equal to $dfrac23$. By the same argument, the integral along the larger semicircle (this time moving from the right to left) is $-dfrac43$.
Can you take it from here?
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
Actually, in the upper semi-circle $lvert zrvert=1$, you have$$frac z{overline z}=frac{z^2}{lvert zrvert^2}=z^2$$and therefore the integral (if you move along the semi-circle from the left to the right) is equal to $dfrac23$. By the same argument, the integral along the larger semicircle (this time moving from the right to left) is $-dfrac43$.
Can you take it from here?
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
edited Nov 29 at 19:21
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
answered Nov 29 at 18:55
José Carlos Santos
149k22117219
149k22117219
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
|
show 2 more comments
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I don't understand how you got the 2/3 and -1/6. Is this the domain mentioned in question? ibb.co/RYY7qBp
– user3132457
Nov 29 at 19:06
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
I used the fact that a primitive of $z^2$ is $frac{z^3}3$. So, the first of those integrals is $frac{1^3}3-frac{(-1)^3}3=frac23$. The other one is similar.
– José Carlos Santos
Nov 29 at 19:08
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
For |z|=2, I get $$int {frac{z}{overline z}}dz = int {frac{z^2}{|z|^2}} = int {frac{z^2}{4}} = {frac{z^3}{3}} times {frac{1}{4}} = {frac{1}{12}}(8+8) = {frac{16}{12}} = {frac{4}{3}}$$ which looks like the final answer.
– user3132457
Nov 29 at 19:19
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
@user3132457 Yes, I made a mistake. I've edited my answer.
– José Carlos Santos
Nov 29 at 19:22
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
Is it -4/3 or 4/3?
– user3132457
Nov 30 at 5:18
|
show 2 more comments
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Note that $frac{z}{bar{z}} =frac{z^2}{|z|^2}$.
– CyclotomicField
Nov 29 at 18:51