Difference between revisions of "BSc: Differential Equations.f23"
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! Section !! Topics within the section |
! Section !! Topics within the section |
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+ | | Differential equations of the first order|| |
| + | # Introduction into differential equations. Origins and examples of the differential equations. |
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| − | # Separable equation |
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| + | # A geometrical interpretation of the differential equations of the first order. A field of directions and solutions of the differential equations as trajectories |
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| − | # Initial value problem |
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| + | # Theorem about existence of the solution of the differential equations. Proof of the theorem. |
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| − | # Homogeneous nonlinear equations |
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| + | # Equations with separable variables and linear equations of the first order. |
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| − | # Substitutions |
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| + | # Homogeneous equations and exact equations and integration factors. |
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| − | # Linear ordinary equations |
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| − | # Bernoulli & Riccati equations |
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| − | # Examples of applications to modeling the real world problems |
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| + | | Differential equations of the second order|| |
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| − | | Introduction to Numerical Methods|| |
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| + | # Linear equations of the second order. Phase portraits, trajectories and conservation laws. Singular points of the second order equations. |
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| − | # Method of sections (Newton method) |
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| ⚫ | |||
| − | # Method of tangent lines (Euler method) |
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| + | # Variations parameters for the second order equations. |
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| + | # Boundary value problems for the second-order equations and Green's function. |
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| − | | |
+ | | Nonlinear equations and Lyapunov's stability || |
| + | # Nonlinear equations of the second order. Conservation laws and trajectories. |
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| − | # Homogeneous linear equations |
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| + | # Lyapunov's stability. Lyapunov's function and Lyapunov stability theorems. |
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| − | # Constant coefficient equations |
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| + | # Chetaev's instability theorem and examples of chaotic systems. |
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| ⚫ | |||
| + | # Partial differential equations of the first order and method of characteristics. |
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| − | # A method of variation of parameters |
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| + | |- |
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| − | # A method of the reduction of order |
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| ⚫ | |||
| ⚫ | |||
| + | # Linear systems of differential equations of the first order and matrix of fundamental solutions. |
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| − | # Application of the Laplace transform to solving differential equations. |
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| + | # Method of variations parameters for the non-homogeneous linear systems. |
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| − | # Series solution of differential equations. |
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| + | |- |
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| − | # Homogeneous linear systems |
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| + | | Numerical methods || |
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| − | # Non-homogeneous systems |
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| ⚫ | |||
| − | # Matrices, eigenvalues and matrix form of the systems of ODE |
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| ⚫ | |||
| + | # Stability and accuracy of numerical methods. |
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| + | |||
== Intended Learning Outcomes (ILOs) == |
== Intended Learning Outcomes (ILOs) == |
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| + | === Course objectives === |
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| + | |||
| + | Upon completion of this course, students should be able to: |
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| + | * Realize conditions of existence for the equations of the first order and solve first-order ordinary differential equations using various techniques such as separation of variables, integration factors. |
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| + | * Solve second-order linear differential equations with constant coefficients using techniques such as the characteristic equation and the method of undetermined coefficients and applications of Laplace transform for the linear equations. |
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| + | * Define the resonant conditions for the linear and nonlinear equations of the second order equation. |
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| + | * Apply the Lyapunov's stability theory for the linear and nonlinear systems. |
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| + | * Know the properties of the solutions of first-order partial differential equations. |
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| + | * Apply numerical methods to approximate solutions to differential equations. |
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| + | * Understand the concept of eigenvalues and eigenvectors and use them to solve systems of linear differential equations. |
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| + | <!-- |
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=== What is the main purpose of this course? === |
=== What is the main purpose of this course? === |
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* predict the number of terms in series solution of the equation depending on the given accuracy, |
* predict the number of terms in series solution of the equation depending on the given accuracy, |
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* implement a certain numerical method in self-developed computer software. |
* implement a certain numerical method in self-developed computer software. |
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| + | --> |
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== Grading == |
== Grading == |
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| Midterm || 20 |
| Midterm || 20 |
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| − | | Interim Assessment|| 20 |
+ | | Interim Assessment|| 20 pts (2 tests by 10 pts) |
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| Final exam || 30 |
| Final exam || 30 |
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| − | | Computational assignment || |
+ | | Computational assignment || 30 |
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| − | | In-class participation || |
+ | | Attendance and In-class participation || 7 |
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| + | <!-- |
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| − | |||
=== Recommendations for students on how to succeed in the course === |
=== Recommendations for students on how to succeed in the course === |
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* Participation is important. Attending lectures is the key to success in this course. |
* Participation is important. Attending lectures is the key to success in this course. |
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* Review lecture materials before classes to do well. |
* Review lecture materials before classes to do well. |
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* Reading the recommended literature is obligatory, and will give you a deeper understanding of the material. |
* Reading the recommended literature is obligatory, and will give you a deeper understanding of the material. |
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| + | --> |
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== Resources, literature and reference materials == |
== Resources, literature and reference materials == |
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=== Open access resources === |
=== Open access resources === |
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* Elementary Differential Equations by William F. Trench. Brooks/Cole Thomson Learning, 2001 [https://digitalcommons.trinity.edu/mono/8/ link] |
* Elementary Differential Equations by William F. Trench. Brooks/Cole Thomson Learning, 2001 [https://digitalcommons.trinity.edu/mono/8/ link] |
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| + | * Stephen L. Campbell and Richard Haberman, Introduction to differential equations with dynamical systems |
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| − | |||
| + | * J.L.Brenner, Problems in DifferentialEquations(adapted from ”Problems in differential equations” by A.F.Filippov) |
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| + | * S.G.Glebov, O.M.Kiselev, N.Tarkhanov. Nonlinear equations with small parameter. Volume I:Oscillations and resonances |
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| + | <!-- |
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== Activities and Teaching Methods == |
== Activities and Teaching Methods == |
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{| class="wikitable" |
{| class="wikitable" |
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=== The retake exam === |
=== The retake exam === |
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Retakes will be run as a comprehensive exam, where the student will be assessed the acquired knowledge coming from the textbooks, the lectures, the labs, and the additional required reading material, as supplied by the instructor. During such comprehensive oral/written the student could be asked to solve exercises and to explain theoretical and practical aspects of the course. |
Retakes will be run as a comprehensive exam, where the student will be assessed the acquired knowledge coming from the textbooks, the lectures, the labs, and the additional required reading material, as supplied by the instructor. During such comprehensive oral/written the student could be asked to solve exercises and to explain theoretical and practical aspects of the course. |
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| + | --> |
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Latest revision as of 21:12, 31 August 2023
Differential Equations
- Course name: Differential Equations
- Code discipline: CSE205
- Subject area: Math
Short Description
This course is an introduction to ordinary differential equations(ODEs) and their applications. Topics covered include first order ODEs, second order linear ODEs, Laypunov’s stability theory and numerical methods.The course will also introduce students to systems of linear equations and eigenvalue problems.
Course Topics
| Section | Topics within the section |
|---|---|
| Differential equations of the first order |
|
| Differential equations of the second order |
|
| Nonlinear equations and Lyapunov's stability |
|
| Systems of the differential equations |
|
| Numerical methods |
|
Intended Learning Outcomes (ILOs)
Course objectives
Upon completion of this course, students should be able to:
- Realize conditions of existence for the equations of the first order and solve first-order ordinary differential equations using various techniques such as separation of variables, integration factors.
- Solve second-order linear differential equations with constant coefficients using techniques such as the characteristic equation and the method of undetermined coefficients and applications of Laplace transform for the linear equations.
- Define the resonant conditions for the linear and nonlinear equations of the second order equation.
- Apply the Lyapunov's stability theory for the linear and nonlinear systems.
- Know the properties of the solutions of first-order partial differential equations.
- Apply numerical methods to approximate solutions to differential equations.
- Understand the concept of eigenvalues and eigenvectors and use them to solve systems of linear differential equations.
Grading
Course grading range
| Grade | Range | Description of performance |
|---|---|---|
| A. Excellent | 90-100 | - |
| B. Good | 75-89 | - |
| C. Satisfactory | 60-74 | - |
| D. Fail | 0-59 | - |
Course activities and grading breakdown
| Activity Type | Percentage of the overall course grade |
|---|---|
| Midterm | 20 |
| Interim Assessment | 20 pts (2 tests by 10 pts) |
| Final exam | 30 |
| Computational assignment | 30 |
| Attendance and In-class participation | 7 |
Resources, literature and reference materials
Open access resources
- Elementary Differential Equations by William F. Trench. Brooks/Cole Thomson Learning, 2001 link
- Stephen L. Campbell and Richard Haberman, Introduction to differential equations with dynamical systems
- J.L.Brenner, Problems in DifferentialEquations(adapted from ”Problems in differential equations” by A.F.Filippov)
- S.G.Glebov, O.M.Kiselev, N.Tarkhanov. Nonlinear equations with small parameter. Volume I:Oscillations and resonances