mathfied
Aug24-08, 06:42 PM
Hi just a bit of help needed here as I don;t know where to start:
Part (A)
----------------------------
Suppose f(z) = u(x,y) + iv(x,y)\;and\;g(z) = v(x,y) + iu(x,y) are analytic in some domain D. Show that both u and v are constant functions..?
I guess we have to use the CRE here but not really sure how to approach this..?
Part (B)
----------------------------
Let f be a holomorphic function on the punctured disk D'(0,R) = \left\{ {z \in C:0 < |z| < R} \right\} where R>0 is fixed. What is the formulae for c_n in the Laurent expansion:
f(z) = \sum\limits_{n = - \infty }^\infty {c_n z_n }.
Using these formulae, prove that if f is bounded on D'(0,R), it has a removable singularity at 0.
- Well I know that:
c_n = \frac{1}
{{2\pi i}}\int\limits_{\gamma _r }^{} {\frac{{f(s)}}
{{(s - z_0 )^{n + 1} }}} ds = \frac{{f^{(n)} (z_0 )}}
{{n!}}.
Any suggestions from here?
PART (C)
-------------------
Find the maximal radius R>0 for which the function
f(z) = (\sin z)^{ - 1} is holomorphic in D'(0,R) and find the principal part of its Laurent expansion about z_0=0
??
Any help would be greatly appreciated.
Thanks a lot
1. The problem statement, all variables and given/known data
2. Relevant equations
3. The attempt at a solution
Part (A)
----------------------------
Suppose f(z) = u(x,y) + iv(x,y)\;and\;g(z) = v(x,y) + iu(x,y) are analytic in some domain D. Show that both u and v are constant functions..?
I guess we have to use the CRE here but not really sure how to approach this..?
Part (B)
----------------------------
Let f be a holomorphic function on the punctured disk D'(0,R) = \left\{ {z \in C:0 < |z| < R} \right\} where R>0 is fixed. What is the formulae for c_n in the Laurent expansion:
f(z) = \sum\limits_{n = - \infty }^\infty {c_n z_n }.
Using these formulae, prove that if f is bounded on D'(0,R), it has a removable singularity at 0.
- Well I know that:
c_n = \frac{1}
{{2\pi i}}\int\limits_{\gamma _r }^{} {\frac{{f(s)}}
{{(s - z_0 )^{n + 1} }}} ds = \frac{{f^{(n)} (z_0 )}}
{{n!}}.
Any suggestions from here?
PART (C)
-------------------
Find the maximal radius R>0 for which the function
f(z) = (\sin z)^{ - 1} is holomorphic in D'(0,R) and find the principal part of its Laurent expansion about z_0=0
??
Any help would be greatly appreciated.
Thanks a lot
1. The problem statement, all variables and given/known data
2. Relevant equations
3. The attempt at a solution