Laurent expansion of $frac{1}{z^2+i}$ at $z=i$












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$begingroup$


I want to find the Laurent series of $1over(z^2+i)$at $z=i$. How do I start and go on from there? Do I start with either of these?



$$1 over{(z+isqrt i)(z-isqrt i)}$$



$$frac{1}{i} frac{1}{1+(z^2/i)}$$



answer for this question










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$endgroup$








  • 1




    $begingroup$
    First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 4:55












  • $begingroup$
    given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
    $endgroup$
    – 서민규
    Dec 7 '18 at 5:38










  • $begingroup$
    given answer is not belong to this question I think
    $endgroup$
    – Nosrati
    Dec 7 '18 at 7:13










  • $begingroup$
    A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 12:51
















0












$begingroup$


I want to find the Laurent series of $1over(z^2+i)$at $z=i$. How do I start and go on from there? Do I start with either of these?



$$1 over{(z+isqrt i)(z-isqrt i)}$$



$$frac{1}{i} frac{1}{1+(z^2/i)}$$



answer for this question










share|cite|improve this question











$endgroup$








  • 1




    $begingroup$
    First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 4:55












  • $begingroup$
    given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
    $endgroup$
    – 서민규
    Dec 7 '18 at 5:38










  • $begingroup$
    given answer is not belong to this question I think
    $endgroup$
    – Nosrati
    Dec 7 '18 at 7:13










  • $begingroup$
    A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 12:51














0












0








0





$begingroup$


I want to find the Laurent series of $1over(z^2+i)$at $z=i$. How do I start and go on from there? Do I start with either of these?



$$1 over{(z+isqrt i)(z-isqrt i)}$$



$$frac{1}{i} frac{1}{1+(z^2/i)}$$



answer for this question










share|cite|improve this question











$endgroup$




I want to find the Laurent series of $1over(z^2+i)$at $z=i$. How do I start and go on from there? Do I start with either of these?



$$1 over{(z+isqrt i)(z-isqrt i)}$$



$$frac{1}{i} frac{1}{1+(z^2/i)}$$



answer for this question







laurent-series






share|cite|improve this question















share|cite|improve this question













share|cite|improve this question




share|cite|improve this question








edited Dec 7 '18 at 5:23







서민규

















asked Dec 7 '18 at 4:23









서민규서민규

11




11








  • 1




    $begingroup$
    First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 4:55












  • $begingroup$
    given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
    $endgroup$
    – 서민규
    Dec 7 '18 at 5:38










  • $begingroup$
    given answer is not belong to this question I think
    $endgroup$
    – Nosrati
    Dec 7 '18 at 7:13










  • $begingroup$
    A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 12:51














  • 1




    $begingroup$
    First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 4:55












  • $begingroup$
    given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
    $endgroup$
    – 서민규
    Dec 7 '18 at 5:38










  • $begingroup$
    given answer is not belong to this question I think
    $endgroup$
    – Nosrati
    Dec 7 '18 at 7:13










  • $begingroup$
    A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
    $endgroup$
    – Jyrki Lahtonen
    Dec 7 '18 at 12:51








1




1




$begingroup$
First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
$endgroup$
– Jyrki Lahtonen
Dec 7 '18 at 4:55






$begingroup$
First do partial fractions. If we abbreviate $w=(1-isqrt2)/2$, then the zeros of $z^2+i$ are $w$ and $-w$. Then you can find constants $A$ and $B$ such that $$frac1{z^2+i}=frac A{z-w}+frac B{z+w}.$$ Then you can write the denominators in the form $C+D(z-i)$ (different values of $C,D$ for the two terms), and manipulate that to a form where you can use the geometric series sum formula.
$endgroup$
– Jyrki Lahtonen
Dec 7 '18 at 4:55














$begingroup$
given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
$endgroup$
– 서민규
Dec 7 '18 at 5:38




$begingroup$
given answer is i.stack.imgur.com/ElPI7.jpg and For my solution that is laurent expansion of 1/z^2 at z=i so I think this is wrong question but im doing partial fraction for this question and i think it can be solved thx
$endgroup$
– 서민규
Dec 7 '18 at 5:38












$begingroup$
given answer is not belong to this question I think
$endgroup$
– Nosrati
Dec 7 '18 at 7:13




$begingroup$
given answer is not belong to this question I think
$endgroup$
– Nosrati
Dec 7 '18 at 7:13












$begingroup$
A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
$endgroup$
– Jyrki Lahtonen
Dec 7 '18 at 12:51




$begingroup$
A typo in my formula for $w$. It should read $w=(1-i)/sqrt2$ (or some other equivalent form).
$endgroup$
– Jyrki Lahtonen
Dec 7 '18 at 12:51










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