MM305 : Complex Analysis 1

Department

Department of Mathematics

Academic Program

Bachelor in mathematics

Type

Compulsory

Credits

03

Prerequisite

MM211

Overview

This course introduces students to the basic concepts of complex numbers. It also deals with the trigonometric inequality and its generalization to (n) numbers, equality conditions, and complex level topology. This course aims at developing the student's ability to identify functions in a complex variable, elementary functions, and transformations.

Intended learning outcomes

At the end of the course, the student should be able to

1- Explain the algebraic concepts and operations of complex numbers

2- Explain how to find the roots of complex numbers

3- Define groups in the complex plane

4- Distinguish the geometric concept of the complex function

5- Mention the concepts, principles and laws of limits and continuity of complex functions

6- Recognize complex differentiation, Cauchy-Riemann equations, and analytical functions

7- Analyze the exercises related to algebraic operations with complex numbers

8-Analyze and explain how to find the roots of complex numbers

9- Distinguish the drawing of groups in the complex plane (level) .

10- Discover the geometric concept of the complex function

11- Deduce the continuity of complex functions

12- Analyze and evaluate his knowledge of Cauchy-Riemann terms

13- Explain the concepts and properties of simple complex functions and simple transformations

14- Know the concepts and properties of simple complex functions and simple transformations .

15- Use algebraic concepts and operations to solve single- and multiple-idea problems

16- There are tables of complex numbers, the students should know.

17- Graph the groups in the complex plane (level).

18- Apply the geometric concept of the complex function

19- There is an end, continuity, and derivative of complex functions, the students should know.

20- Use the Cauchy-Riemann equations to find out whether the functions are analytic or not

21- Employ the concepts of complex functions in order to carry out the simple complex transformations.

Teaching and learning methods

1- Practical and theoretical lectures .

2- Discussion and dialogue .

3- Brain storming .

4- Working papers, case study .

5- Presentations .

6- Videos and e-learning

7- Use of software and computer applications such as (MATLAB, GeoGebra, Geometer,)

8- Intensifying applications, solving problems, and linking ideas with reality and life situations

Methods of assessments

1- A written exam (essay + objective) = 25 marks, or its assessment is left to the course instructor

2- Short tests (written or oral), demonstration tasks, applications, exercises, and presentation = 15 marks, or the assessment is left to the course instructor .

3- Written final exam (essay + objective) = 60 marks

Course content:

Week

Scientific subject

Number of Hours

Lecture

exercises

discussion

1-2

Complex numbers and complex plane

6

ü

ü

ü

2-3

Absolute value of a complex number and operations on it / trigonometric inequality and its generalization

6

ü

ü

ü

4

The polar form of a complex number

4

ü

ü

ü

5

First Midterm 2 hours

5-6

De Moivre's Formula / Root of a Complex Number / Euler's Formula

4

ü

ü

ü

6-7

The regions in the complex plane and the point of infinity

4

ü

ü

ü

7-8

The compound function/end and connection of the compound function

6

ü

ü

ü

9-10

Complex differentiation and the two Cauchy-Riemann equations / analytical functions / harmonic functions

6

ü

ü

ü

10

Second Midterm 2 hours

11-12-13

Simple complex functions (polynomials, exponential functions, trigonometric functions, hyperbolic functions, logarithmic functions, inverse trigonometric functions, and inverse hyperbolic functions) and their properties

12

ü

ü

ü

14

Some simple compound conversions

4

ü

ü

ü

Final Exam

Total

56

Reference

References Title

publisher

Release Copy

Author

Composite analysis

New Book

Almotaheda

First Copy

2013

Dr.. Ramadan Mohamed Juhayma

Dr.. Salem Ibrahim Al-Qawi

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computer 1 (CS100)
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