Pole (complex analysis): Difference between revisions
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:<math>\lim_{z \rightarrow a} f(z) (z-a)^k = r . \,</math>. | :<math>\lim_{z \rightarrow a} f(z) (z-a)^k = r . \,</math>. | ||
The pole is an ''isolated singularity'' if there is a neighbourhood of ''a'' in which ''f'' is [[holomorphic function|holomorphic]] except at ''a''. In this case the function has a [[Laurent series]] in a neighbourhood of ''a'', so that ''f'' is expressible as a power series | The pole is an ''[[isolated singularity]]'' if there is a neighbourhood of ''a'' in which ''f'' is [[holomorphic function|holomorphic]] except at ''a''. In this case the function has a [[Laurent series]] in a neighbourhood of ''a'', so that ''f'' is expressible as a power series | ||
:<math> f(z) = \sum_{n=-k}^\infty c_n (z-a)^n , \,</math> | :<math> f(z) = \sum_{n=-k}^\infty c_n (z-a)^n , \,</math> | ||
Revision as of 13:46, 11 November 2008
In complex analysis, a pole is a type of singularity of a function of a complex variable. In the neighbourhood of a pole, the function behave like a negative power.
A function f has a pole of order k, where k is a positive integer, with (non-zero) residue r at a point a if the limit
- .
The pole is an isolated singularity if there is a neighbourhood of a in which f is holomorphic except at a. In this case the function has a Laurent series in a neighbourhood of a, so that f is expressible as a power series
where the leading coefficient .
An isolated singularity may be either removable, a pole, or an essential singularity.
References
- Tom M. Apostol (1974). Mathematical Analysis, 2nd ed. Addison-Wesley, 458.