Complex Anal. Problems: Need Help!

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Discussion Overview

The discussion revolves around two problems in complex analysis: the convergence of the series ∑z^n for |z|<1 and the nature of the singularity at z=1 for the function f(z)=1/√(z-1). Participants express confusion regarding the definitions and properties related to uniform convergence and types of singularities.

Discussion Character

  • Debate/contested
  • Technical explanation
  • Conceptual clarification

Main Points Raised

  • Some participants argue that the series ∑z^n is not uniformly convergent, suggesting that applying the definition of uniform convergence clarifies this point.
  • Others assert that the singularity at z=1 for f(z)=1/√(z-1) is a pole, citing the definition that a pole exists if the function can be expressed as f(z) = g(z)/(z-a)^n for some holomorphic g.
  • A participant questions the classification of the singularity, noting that if g(1)≠0 is required for a pole, then the function cannot be expressed in that form, leading to confusion.
  • Another participant challenges the earlier claims by stating that both poles and essential singularities require the function to be holomorphic on a deleted neighborhood of the singularity, which f(z)=1/√(z-1) does not satisfy.

Areas of Agreement / Disagreement

Participants express differing views on both problems, with no consensus reached regarding the uniform convergence of the series or the nature of the singularity at z=1.

Contextual Notes

Participants reference definitions and properties from complex analysis, but there are unresolved questions about the application of these definitions to the specific cases discussed.

matheater
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I have the following problems
(1)Consider the series ∑z^n,|z|<1 z is in C
I thik this series is absolutely and uniformly comvergent since the series ∑|z|^n is con vergent for |z|<1,but I have a book saying that it is absolutely convergent,not uniformly...i am confused...
(2)for the function f(z)=1/√(z-1),z=1 is a (a)pole (b)an essential singularity ?
I think it is an essential singularity since if it is a pole,say of order m then m is a positive integer and we can write f(z)=g(z)/(z-1)^m, where g(z) is analytic at z=1 and g(1)≠0,
but the given function cannot be written in this way,but the answer is given pole,i am again confused...
Can anybody help me?
 
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1) It is indeed not uniformly convergent. You really just have to apply the definition of uniform convergence to see it.
2) It is a fact that a singularity is only an essential singularity if and only if the limit does not exist and it is not infinity. The definition of a pole is we can write f(z) = g(z) / (z-a)^n, for some holomorphic g, and the order of the pole is the smallest n for which this is true. If f(z) = z^-1/2, then this is satisfied by taking g(z) = z^1/2 and n = 1.
 
nicksauce said:
1) It is indeed not uniformly convergent. You really just have to apply the definition of uniform convergence to see it.
2) It is a fact that a singularity is only an essential singularity if and only if the limit does not exist and it is not infinity. The definition of a pole is we can write f(z) = g(z) / (z-a)^n, for some holomorphic g, and the order of the pole is the smallest n for which this is true. If f(z) = z^-1/2, then this is satisfied by taking g(z) = z^1/2 and n = 1.
Thank u very much for your kind help,but I couldn't understand the second answer,will u please explain it a bit more ?
 
I don't know what more I can do but restate what I wrote before. I don't have my complex analysis book with me right now, but wikipedia define a pole as follows:

Suppose f has a singularity at x = a... If there exists a holomorphic function g(z) so that we can write
f(z) = \frac{g(z)}{(x-a)^n}, then a is a pole of order n, where n is the smallest number for which f can be written like this.

Now consider f(z) = z^{-\frac{1}{2}}, which has a singularity at z = 0. We can write
f(z) = \frac{z^ {\frac{1}{2}}}{z}
Therefore z=0 is a pole of order 1.
 
nicksauce said:
I don't know what more I can do but restate what I wrote before. I don't have my complex analysis book with me right now, but wikipedia define a pole as follows:

Suppose f has a singularity at x = a... If there exists a holomorphic function g(z) so that we can write
f(z) = \frac{g(z)}{(x-a)^n}, then a is a pole of order n, where n is the smallest number for which f can be written like this.

Now consider f(z) = z^{-\frac{1}{2}}, which has a singularity at z = 0. We can write
f(z) = \frac{z^ {\frac{1}{2}}}{z}
Therefore z=0 is a pole of order 1.
but g(0)=0,how is this satisfying the criteria for being a pole?
 
Hmm this is true... I retract my answer, and hope someone else can help you.
 
Neither. Both poles and essential singularities require the relevant function to be holomorphic on a deleted neighborhood of the singularity. z^{-\frac{1}{2}} isn't even continuous on one of these neighborhoods. In descriptive terms, however, it would look like half of a simple pole stretched around.
 

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