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Course Information

Course Name
Turkish Diferansiyel Denklemler
English Differential Equations
Course Code
EEF 210E Credit Lecture
(hour/week)
Recitation
(hour/week)
Laboratory
(hour/week)
Semester 1
3 3 - -
Course Language English
Course Coordinator Kamil Karaçuha
Course Objectives 1 Introduction. First Order Differential Equations (Basic Concepts, A Simple DE Example,
Clasification of DEs)
I - II
2 First Order Differential Equations (Linear Eqns, Separable Eqns, Existence and Uniqueness
Thm)
II-III
3 First Order Differential Equations (Exact Eqns, Homogeneous Eqns, Riccati Eqn) II - III
4 Second Order Differential Equations (Constant Coefficient, Homogeneous,Linear DE, Basic
Theorems and the Wronskian, Complex Roots of the Characteristic Eqn)
III - IV
5
Second Order Differential Equations (Repeated Roots of the Characteristic Eqn, Reduction of
Order, Nonhomogeneous Eqns, Method of Undetermined Coefficients, Variation of
Parameters)
IV
6
Second Order Differential Equations (Mechanical and Electrical Vibrations, Forced
Vibrations), Higher Order Differential Equations (General Theory of nth Order Linear
Equations)
III - IV
7 Higher Order Differential Equations (Homogeneous Eqns with Constant Coefficients, Method
of Undetermined Coefficients, Method of Variation of Parameters)
IV
8 The Laplace Transform (Definition of Laplace Transform, Initial Value Problems, Step
Functions)
V
9 The Laplace Transform (DE with Discontinuous Forcing Functions, Impulse Function,
Convolution Integral)
V
10 Systems of First Order Linear Equations (Introduction, Basic Theory of Systems of
First Order Linear Equations)
VI
11 Systems of First Order Linear Equations (Homogeneous Linear Systems with Constant
Coefficients, Complex Eigenvalues, Fundamental Matrices)
VI
12 Systems of First Order Linear Equations (Repeated Eigenvalues, Nonhomogeneous Linear
Systems)
VI
13 Series Solutions of Second Order Linear Equations (Series Solutions Near an Ordinary Point,
Euler Equations, Regular Singular Points)
VII
14 Series Solutions of Second Order Linear Equations (Series Solutions Near a Regular Singular
Point)
VII
Course Description 1 Introduction. First Order Differential Equations (Basic Concepts, A Simple DE Example,
Clasification of DEs)
I - II
2 First Order Differential Equations (Linear Eqns, Separable Eqns, Existence and Uniqueness
Thm)
II-III
3 First Order Differential Equations (Exact Eqns, Homogeneous Eqns, Riccati Eqn) II - III
4 Second Order Differential Equations (Constant Coefficient, Homogeneous,Linear DE, Basic
Theorems and the Wronskian, Complex Roots of the Characteristic Eqn)
III - IV
5
Second Order Differential Equations (Repeated Roots of the Characteristic Eqn, Reduction of
Order, Nonhomogeneous Eqns, Method of Undetermined Coefficients, Variation of
Parameters)
IV
6
Second Order Differential Equations (Mechanical and Electrical Vibrations, Forced
Vibrations), Higher Order Differential Equations (General Theory of nth Order Linear
Equations)
III - IV
7 Higher Order Differential Equations (Homogeneous Eqns with Constant Coefficients, Method
of Undetermined Coefficients, Method of Variation of Parameters)
IV
8 The Laplace Transform (Definition of Laplace Transform, Initial Value Problems, Step
Functions)
V
9 The Laplace Transform (DE with Discontinuous Forcing Functions, Impulse Function,
Convolution Integral)
V
10 Systems of First Order Linear Equations (Introduction, Basic Theory of Systems of
First Order Linear Equations)
VI
11 Systems of First Order Linear Equations (Homogeneous Linear Systems with Constant
Coefficients, Complex Eigenvalues, Fundamental Matrices)
VI
12 Systems of First Order Linear Equations (Repeated Eigenvalues, Nonhomogeneous Linear
Systems)
VI
13 Series Solutions of Second Order Linear Equations (Series Solutions Near an Ordinary Point,
Euler Equations, Regular Singular Points)
VII
14 Series Solutions of Second Order Linear Equations (Series Solutions Near a Regular Singular
Point)
VII
Course Outcomes Student, who passed the course satisfactorily can:
1. Classify differential equations according to certain features.
2. Solve first order linear equations and nonlinear equations of certain types and interpret the
solutions.
3. Understand the conditions for the existence and uniqueness of solutions for linear
differential equations.
4. Solve second and higher order linear differential equations with constant coefficients and
construct all solutions from the linearly independent solutions.
5. Solve initial value problems using the Laplace transform .
6. Solve systems of linear differential equations with methods from linear algebra.
7. Find series solutions about ordinary and regular singular points for second order linear
differential equations.
Pre-requisite(s)
Required Facilities
Other
Textbook Elementary Differential Equations and Boundary Value Problems

William E. Boyce
Edward P. Hamilton Professor Emeritus
Richard C. DiPrima
formerly Eliza Ricketts Foundation Professor
Department of Mathematical Sciences
Rensselaer Polytechnic Institute
Other References
 
 
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