C-R of Laurent Series

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SUMMARY

The discussion centers on the application of the Cauchy-Riemann equations and Laurent series in complex contour integration. Participants clarify that the first coefficient of the principal part in the Laurent expansion corresponds to the residue at a pole, denoted as z^{-1}. The consensus is that using the residue method is preferable for evaluating integrals over direct integration, especially when dealing with complex functions. This approach simplifies the process and leverages the properties of residues effectively.

PREREQUISITES
  • Understanding of complex analysis concepts, specifically contour integration.
  • Familiarity with the Cauchy-Riemann equations.
  • Knowledge of Laurent series and their application in complex functions.
  • Ability to compute residues at poles in complex functions.
NEXT STEPS
  • Study the application of the Cauchy Integral Theorem in complex analysis.
  • Learn how to compute residues using the residue theorem.
  • Explore advanced topics in Laurent series, including convergence and applications.
  • Investigate practical examples of contour integration in physics and engineering.
USEFUL FOR

Mathematicians, physics students, and anyone involved in complex analysis or contour integration techniques will benefit from this discussion.

hob
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When doing complex contour integration one can use the C-R formula or the Laurent series and find the first coefficient of the principle part. What are the selection criteria for choosing these methods?

Regards,

Hob
 
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What do you mean by "use the Cauchy-Riemann equations to do a contour integral"? Are you referring to actually integrating around the contour as opposed to summing the residues inside the contour?
 
Hi, I mean summing within the contour.

2 \pi x \sum residues = Integral around the contour.

You can also use the Laurent Expansion and finding the first principle coefficient.

I am unsure what method you would use when presented with a complex integration,

Regards,
 
Last edited:
??The "first principle coefficient" of the Laurent expansion, around pole z_0, by which I think you mean the coefficient of z^{-1}, is the residue at that z_0. They are the same method.
 
Correct me if I'm wrong, but I think you mean should you try to evaluate the integral directly, or do the residue by other means? Almost certainly the residue method. After all, if you could muscle your way through integrals, you wouldn't need contour integration.
 

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