Difference between revisions of "MAT3613"

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* Ahmad and Ambrosetti 2014, Ch. 3
 
* Ahmad and Ambrosetti 2014, Ch. 3
 
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* [[Exact Differential Equations (1st Order)]]
+
* [[Exact Differential Equations|Exact Differential Equations (1st Order)]]
 
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* [[Integrating Factor]] for exact equations.
 
* [[Integrating Factor]] for exact equations.
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:- [[Linear Differential Equations|Linear Differential Equations (1st Order)]]
 
:- [[Linear Differential Equations|Linear Differential Equations (1st Order)]]
 
:- [[Bernoulli Equations (1st Order)]]
 
:- [[Bernoulli Equations (1st Order)]]
:- [[Exact Differential Equations (1st Order)]]
+
:- [[Exact Differential Equations|Exact Differential Equations (1st Order)]]
 
||
 
||
 
* Determine the type of different classes of differential equations of the first order: separable, linear, homogeneous, Bernoulli, exact.
 
* Determine the type of different classes of differential equations of the first order: separable, linear, homogeneous, Bernoulli, exact.
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* Ahmad and Ambrosetti 2014, Ch. 5
 
* Ahmad and Ambrosetti 2014, Ch. 5
 
||
 
||
* [[Linear Dependence of Functions]].
+
* [[Linear Independence of Functions|Linear Dependence of Functions]].
 
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* [[Linear Dependence of Vectors]].
 
* [[Linear Dependence of Vectors]].
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||
 
||
 
* [[Linear Independence of Functions]].
 
* [[Linear Independence of Functions]].
* [[Linear Dependence of Functions]].
+
* [[Linear Independence of Functions|Linear Dependence of Functions]].
 
* [[Determinant]].
 
* [[Determinant]].
 
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* Ahmad and Ambrosetti 2014, Ch. 5
 
* Ahmad and Ambrosetti 2014, Ch. 5
 
||
 
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* [[Linear Non-homogeneous Equations]]
+
* [[Linear Differential Equations|Linear Non-homogeneous Equations]]
 
||
 
||
 
* [[Wronskian]].
 
* [[Wronskian]].
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* Ahmad and Ambrosetti 2014, Ch. 5
 
* Ahmad and Ambrosetti 2014, Ch. 5
 
||
 
||
* [[Variation of Parameters (Higher Order)]]
+
* [[Variation Of Parameters|Variation of Parameters (Higher Order)]]
 
||
 
||
* [[Variation of Parameters (2nd Order)]]
+
* [[Variation Of Parameters|Variation of Parameters (2nd Order)]]
 
||
 
||
 
* Apply variation of parameters technique for higher-order ODEs
 
* Apply variation of parameters technique for higher-order ODEs
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* Ahmad and Ambrosetti 2014, Ch. 5
 
* Ahmad and Ambrosetti 2014, Ch. 5
 
||
 
||
* [[Method of Undetermined Coefficients (Higher Order)]]
+
* [[Method of Undetermined Coefficients|Method of Undetermined Coefficients (Higher Order)]]
 
||
 
||
 
* [[Method of Undetermined Coefficients (2nd Order)]]
 
* [[Method of Undetermined Coefficients (2nd Order)]]
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||
 
||
 
* [[Linear Differential Equations|Linear Differential Equations (1st Order)]]
 
* [[Linear Differential Equations|Linear Differential Equations (1st Order)]]
* [[Variation of Parameters (Higher Order)]].
+
* [[Variation Of Parameters|Variation of Parameters (Higher Order)]].
* [[Method of Undetermined Coefficients (Higher Order)]].
+
* [[Method of Undetermined Coefficients|Method of Undetermined Coefficients (Higher Order)]].
 
||
 
||
 
* Methods for linear higher-order ODEs
 
* Methods for linear higher-order ODEs
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* [[Algebraic Equations]]
 
* [[Algebraic Equations]]
 
* Direct methods for second and higher-order ODEs:
 
* Direct methods for second and higher-order ODEs:
:- [[Variation of Parameters (Higher Order)]]
+
:- [[Variation Of Parameters|Variation of Parameters (Higher Order)]]
:- [[Method of Undetermined Coefficients (Higher Order)]]
+
:- [[Method of Undetermined Coefficients|Method of Undetermined Coefficients (Higher Order)]]
 
||
 
||
 
* Evaluate the exact solutions of important classes of differential equations such as second order differential equations as well as some higher order differential equations.
 
* Evaluate the exact solutions of important classes of differential equations such as second order differential equations as well as some higher order differential equations.
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* [[Power Series Solutions]]
 
* [[Power Series Solutions]]
 
||
 
||
* [[Power Series Inducution]]
+
* [[Power Series Induction]]
 
||
 
||
 
Apply power series method to evaluate solutions of first-order and second-order ODEs.
 
Apply power series method to evaluate solutions of first-order and second-order ODEs.
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* [[Laplace Transform to ODEs]]
 
* [[Laplace Transform to ODEs]]
 
||
 
||
* [[Linear Equations]]
+
* [[Linear Differential Equations|Linear Equations]]
 
* [[Laplace Transform]]
 
* [[Laplace Transform]]
 
* [[Inverse Laplace Transform]]
 
* [[Inverse Laplace Transform]]
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* Ahmad and Ambrosetti 2014, Ch. 11
 
* Ahmad and Ambrosetti 2014, Ch. 11
 
||
 
||
* [[Laplace Transform to Systems of ODEs]]
+
* [[Laplace Transform to ODEs|Laplace Transform to Systems of ODEs]]
 
||
 
||
 
* [[Solutions of Linear Systems]].
 
* [[Solutions of Linear Systems]].
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* [[Integrating Factor]]
 
* [[Integrating Factor]]
 
* [[Bernoulli Equations (1st Order)]]
 
* [[Bernoulli Equations (1st Order)]]
* [[Exact Differential Equations (1st Order)]]
+
* [[Exact Differential Equations|Exact Differential Equations (1st Order)]]
 
* [[Reduction of the Order]]
 
* [[Reduction of the Order]]
 
* [[Method of Undetermined Coefficients (2nd Order)]]
 
* [[Method of Undetermined Coefficients (2nd Order)]]
 
* [[Non-linear 2nd Order ODEs]]
 
* [[Non-linear 2nd Order ODEs]]
* [[Variation of Parameters (Higher Order)]]
+
* [[Variation Of Parameters|Variation of Parameters (Higher Order)]]
* [[Method of Undetermined Coefficients (Higher Order)]]
+
* [[Method of Undetermined Coefficients|Method of Undetermined Coefficients (Higher Order)]]
 
* [[Linear Differential Equations|Linear Differential Equations (Higher Order)]]
 
* [[Linear Differential Equations|Linear Differential Equations (Higher Order)]]
 
* [[Power Series Solutions]]
 
* [[Power Series Solutions]]
 
* [[Laplace Transform to ODEs]]
 
* [[Laplace Transform to ODEs]]
* [[Laplace Transform to Systems of ODEs]]
+
* [[Laplace Transform to ODEs|Laplace Transform to Systems of ODEs]]
 
||
 
||
 
* Apply all solutions methods discussed.
 
* Apply all solutions methods discussed.
 
|}
 
|}

Latest revision as of 12:24, 27 November 2021

Course Catalog

MAT 3613. Differential Equations I. (3-0) 3 Credit Hours.

Prerequisite: Completion of or concurrent enrollment in MAT2233. Basic notions of differential equations, solution of first-order equations and linear equations with constant coefficients, nth-order initial value problems, Laplace transforms, and may include additional topics such as power series solutions of differential equations, linear systems, and stability. Generally offered: Fall, Spring, Summer. Differential Tuition: $150.

Text

Ahmad, S., & Ambrosetti, A. (2014). textbook on Ordinary Differential Equations (Vol. 73). Springer

Topics List

Date Sections Topics Prerequisite Skills Student Learning Outcomes
Week I
  • Ahmad and Ambrosetti 2014, Chaps. 1, 2, 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Explain the basic notion of the order of a differential equation.
Week I
  • Ahmad and Ambrosetti 2014, Chaps. 1, 2, 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Explain the basic notion of solutions of differential equations.
Week I
  • Ahmad and Ambrosetti 2014, Chaps. 1, 2, 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Explain the basic notion of the initial values problem.
Week I
  • Ahmad and Ambrosetti 2014, Chaps. 1, 2, 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Explain the Cauchy Problem
  • Explain the basic notion of existence and uniqueness of a solution to the Cauchy Problem.
Week I
  • Ahmad and Ambrosetti 2014, Chaps. 1, 2, 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Determine separable differential equations of the first order.
  • Apply direct methods to evaluate exact solutions of separable differential equations of the first order.
Week II
  • Ahmad and Ambrosetti 2014, Chaps. 1 and 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Determine homogeneous differential equations of the first order.
  • Apply direct methods to evaluate exact solutions of homogeneous differential equations of the first order (substitutions).
  • Use some differential equations as mathematical models in biology, population dynamics, mechanics and electrical circuit theory problems.
Week II
  • Ahmad and Ambrosetti 2014, Chaps. 1 and 3
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Determine linear differential equations of the first order.
  • Use some differential equations as mathematical models in biology, population dynamics, mechanics and electrical circuit theory problems.
Week II
  • Ahmad and Ambrosetti 2014, Chaps. 1 and 3
  • Apply integrating factor to solve linear differential equations of the first order.
  • Use some differential equations as mathematical models in biology, population dynamics, mechanics and electrical circuit theory problems.
Week III
  • Ahmad and Ambrosetti 2014, Ch. 3
  • Determine Bernoulli of the first order.
  • Apply direct methods to evaluate exact solutions of Bernoulli of the first order.
Week III
  • Ahmad and Ambrosetti 2014, Ch. 3
  • Determine Exact Differential Equations of the first order.
  • Apply direct methods to evaluate exact solutions of Exact Differential Equations of the first order.
  • Use the integrating factor technique for exact equations.
Week IV
  • Ahmad and Ambrosetti 2014, Chaps. 1-3
  • Overview of the solutions methods discussed so far (Chapters 1-3).
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
- Separation of Variables (1st Order)
- Homogeneous Differential Equations (1st Order)
- Linear Differential Equations (1st Order)
- Bernoulli Equations (1st Order)
- Exact Differential Equations (1st Order)
  • Determine the type of different classes of differential equations of the first order: separable, linear, homogeneous, Bernoulli, exact.
  • Use direct methods to solve first order differential equations solved and not solved for the first derivative.
Week V
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Understanding of Linear Independence of Functions.
Week V
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Understanding of Linear Dependence of Functions.
Week V
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Showing linear independence of two functions using the Wronskian.
  • Showing linear independence of two solutions of Linear Second-Order ODEs using the Wronskian.
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Apply of the reduction of the order technique for second-order ODEs with a given solution.
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Determine homogeneous classes of differential equations of the second and higher order.
  • Determine linear and non-linear classes of differential equations of the second and higher order.
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Determine Wronskian for a second-order ODE with 2 given solutions.
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Determine fundamental solutions.
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Determine non-homogeneous classes of differential equations of the second and higher order.
  • Determine linear and non-linear classes of differential equations of the second and higher order
Week VI
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Apply of the variation of parameters technique for second-order ODEs.
Week VII
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Integration techniques
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Apply variation of parameters technique for second-order ODEs.
Week VII
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Apply method of undetermined coefficients technique for second-order ODEs.
Week VIII
  • Ahmad and Ambrosetti 2014, Ch. 5
- Direct Integration
- Integration by Substitution
- Integration by Parts
- Partial Fractions
  • Methods for nonlinear second-order ODEs.
  • Apply reduction of the order method to some nonlinear second-order ODEs.
Week VIII
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Apply variation of parameters technique for higher-order ODEs
Week VIII
  • Ahmad and Ambrosetti 2014, Ch. 5
  • Apply method of undetermined coefficients technique for higher-order ODEs
Week IX
  • Ahmad and Ambrosetti 2014, Ch. 6
  • Methods for linear higher-order ODEs
Week X
  • Ahmad and Ambrosetti 2014, Chaps. 5, 6
  • Overview of the solutions methods for second and higher order differential equations.
- Variation of Parameters (Higher Order)
- Method of Undetermined Coefficients (Higher Order)
  • Evaluate the exact solutions of important classes of differential equations such as second order differential equations as well as some higher order differential equations.
Week X
  • Ahmad and Ambrosetti 2014, Chaps. 10

Apply power series method to evaluate solutions of first-order and second-order ODEs.

Week XI
  • Ahmad and Ambrosetti 2014, Chaps. 10

Apply power series method to evaluate solutions of first-order and second-order ODEs.

Week XII
  • Ahmad and Ambrosetti 2014, Ch. 11
  • Definition and main properties of the L-transform.
Week XIII
  • Ahmad and Ambrosetti 2014, Ch. 11
  • Apply the theorem(s) for inverse L-transform.
Week XIV
  • Ahmad and Ambrosetti 2014, Ch. 11
  • Apply the Laplace transform as solution technique.
Week XIV
  • Ahmad and Ambrosetti 2014, Ch. 11
  • Apply the Laplace transform as solution technique.
Week XV
  • Ahmad and Ambrosetti 2014
  • Overview of the solutions methods discussed.
  • Apply all solutions methods discussed.
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