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Complex Function Theory 3 (MATH 33000)

Contents of this document:

• Administrative information
• Unit aims,   General Description, and Relation to Other Units
• Teaching methods and Learning objectives
• Assessment methods and Award of credit points
• Transferable skills
• Texts and Syllabus

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Administrative Information

1. Unit number and title: MATH 33000 Complex Function Theory 3
2. Level: H/6
3. Credit point value: 20 credit points
4. Year: 12/13
5. First Given in this form: 2002/2003
6. Unit Organiser: Yuri Netrusov
7. Lecturer: Yuri Netrusov
8. Teaching block: 1
9. Prerequisites: MATH 20200 Metric Spaces.

Unit aims

To impart an understanding of Complex Function Theory, and facility in its application. 

General Description of the Unit

Complex function theory is a remarkably beautiful piece of pure mathematics, and at the same time an indispensable tool in number theory and in many fields of applied mathematics and mathematical methods.

Of central interest are mappings of the complex plane into itself which are differentiable. The property of differentiability alone is enough to guarantee that the function can be represented locally in a power series, in stark contrast to the real-variable theory. This shows that complex analysis is in some ways simpler than real analysis.

The integration theory for complex differentiable functions is highly geometric in nature. Moreover, it provides powerful tools for evaluating real integrals and series. The logarithm and square-root functions on the complex plane are multiple-valued; we shall briefly indicate how they can be seen as single-valued when considered to live on the associated Riemann surface.

The theory of conformal transformations is of great importance in the geometrical theory of differential equations, and has interesting applications in potential theory and fluid dynamics; we shall outline the beginnings of these.

Relation to Other Units

This unit aims for rigorous development  and extension of material which has been introduced in the complex function theory part of Calculus 2.  Students should have a good knowledge of first year analysis and second year calculus courses.

From 2002-3 Complex Function Theory will not be required for Methods 3 or Fluid Dynamics, because Calculus 2 from 2001-2 onwards will contain enough complex function theory to support those units.

Teaching Methods

Lecture course of 30 lectures, with weekly exercise sheets to be done by students. 

Learning Objectives

At the end of the unit students should:

• be able to recall all definitions and main results,
• be able to give an outline proof of all results,
• be able to give detailed proofs of less involved results,
• be able to apply the theory in standard situations,
• be able to use the ideas of the unit in unseen situations.

Assessment Methods

The assessment mark for Complex Function Theory 3 is calculated from a 2 ½-hour written examination in April consisting consisting of FIVE questions. A candidate's best FOUR answers will be used for assessment. Calculators are NOT permitted.

Award of Credit Points

Credit points are gained by:

• either passing the unit,
• or getting an examination mark of 30 or over, and also handing in satisfactory attempts at four specified homework questions, to be given out at various times over the teaching block.

Transferable Skills

Problem solving and logical analysis. 

Texts

Many books dealing with complex analysis may be found in section QA331 of the Queen's Library. The books:

1. I. Stewart and D. Tall, Complex Analysis, Cambridge University Press
2. J. E. Marsden, Basic Complex Analysis, W. H. Freeman
3. J. B. Conway, Functions of one complex variable, Springer

may be found particularly useful. The bulk of the course will follow [1] quite closely. The Schaum Outline Series Complex Variables by M. R. Spiegel is a good additional source of problems. 

Syllabus

• Differentiation and integration of complex functions: Cauchy-Riemann equations, contour integrals, the fundamental theorem of contour integration - a quick survey.
• Cauchy's theorems: Cauchy's theorem for a triangle, Cauchy's theorem for a starshaped domain; homotopy, simply connected domains, Deformation theorem (without proof), Cauchy's theorem for simply connected domains.
• Cauchy's integral formula: Cauchy's formula, Morera's and Liouville's Theorem, fundamental theorem of algebra.
• Local properties of analytic functions: Taylor series, Laurent series.
• Zeros and singularities of analytic functions: classification of zeros and isolated singularities, Casorati-Weierstrass's theorem, behaviour of analytic functions at infinity.
• The residue theorem: the topological index, the residue theorem, Rouche's and the local mapping theorem.
• Global properties of analytic functions: the identity theorem, maximum modulus theorems.
• Harmonic functions: harmonic functions and harmonic conjugates, the Poisson formula, the Dirichlet problem.
• Conformal mappings: basic properties of conformal mappings, the Riemann mapping's theorem (without proof), fractional linear transformations and other standard transformations, application of conformal mappings to Laplace's equation.