Difference between revisions of "MAT 5673"
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| + | ==Course description== | ||
| + | Partial differential equations arise in many different areas as one tries | ||
| + | to describe the behavior of a system ruled by some law. Typically, this has to do with | ||
| + | some physical process such as heat diffusion in a material, vibrations of a bridge, circulation | ||
| + | of fluids, the behavior of microscopic particles or the evolution of the universe as a whole. | ||
| + | Modeling by means of partial differential equations has been successful in other disciplines | ||
| + | as well, like in the case of the Black-Scholes equation for stock options pricing and the | ||
| + | Hodgkin–Huxley equations for firing patterns of a neuron. Partial differential equations are | ||
| + | an important tool in Applied Math and Pure Math. This course gives an introduction to PDE's in the setting of two independent variables. | ||
==Topics List== | ==Topics List== | ||
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* | * | ||
| + | || | ||
| + | Introduction and classification of PDE, Calculus review | ||
| + | || | ||
| + | Multivariable Calculus, Chain Rule | ||
| + | || | ||
| + | * Definition of a PDE as a relation between partial derivatives of an unknown function. Classification of PDE according to order - linear/nonlinear/quasilinear | ||
| + | |- | ||
| + | |Week 2 | ||
| + | || | ||
| + | * | ||
| + | || | ||
| + | Applied examples of PDE | ||
| + | || | ||
| + | Multivariable Calculus, Chain Rule | ||
| + | || | ||
| + | * Origin and background of common PDE's: heat equation, wave equation, transport equation, etc. | ||
| + | |- | ||
| + | |Week 3 | ||
| + | || | ||
| + | * | ||
| + | || | ||
| + | The method of characteristics for first-order quasilinear equations | ||
| + | || | ||
| + | Multivariable Calculus, Chain Rule | ||
| + | || | ||
| + | * Solving quasilinear first-order equations using the method of characteristics | ||
| + | |- | ||
| + | |Week 4 | ||
| + | || | ||
| + | * | ||
| + | || | ||
| + | The method of characteristics for first-order fully nonlinear equations | ||
| + | || | ||
| + | Multivariable Calculus, Chain Rule | ||
| + | || | ||
| + | * Solving fully nonlinear first-order equations (e.g. the Eikonal equation) using the method of characteristics | ||
| + | |- | ||
| + | |Week 5 | ||
|| | || | ||
* | * | ||
| + | || | ||
| + | Heat and wave equation on the whole real line | ||
| + | || | ||
| + | Differentiation of integrals with respect to a parameter, integration by parts | ||
| + | || | ||
| + | * Fundamental solution of the heat equation, D'Alembert's formula for the wave equation | ||
| + | |- | ||
| + | |Week 6 | ||
|| | || | ||
* | * | ||
|| | || | ||
| − | * | + | Initial-boundary value problem for heat and wave equation I |
| + | || | ||
| + | Partial derivatives, chain rule | ||
| + | || | ||
| + | * Separation of variables method for heat and wave equation | ||
| + | |- | ||
| + | |Week 7 | ||
| + | || | ||
| + | * | ||
| + | || | ||
| + | Initial-boundary value problem for heat and wave equation II, introduction to Fourier series | ||
| + | || | ||
| + | Partial derivatives, chain rule | ||
| + | || | ||
| + | * Infinite superposition of basic solutions found by separation to form more general solutions | ||
|} | |} | ||
Revision as of 08:54, 12 March 2023
Course description
Partial differential equations arise in many different areas as one tries to describe the behavior of a system ruled by some law. Typically, this has to do with some physical process such as heat diffusion in a material, vibrations of a bridge, circulation of fluids, the behavior of microscopic particles or the evolution of the universe as a whole. Modeling by means of partial differential equations has been successful in other disciplines as well, like in the case of the Black-Scholes equation for stock options pricing and the Hodgkin–Huxley equations for firing patterns of a neuron. Partial differential equations are an important tool in Applied Math and Pure Math. This course gives an introduction to PDE's in the setting of two independent variables.
Topics List
| Date | Sections | Topics | Prerequisite Skills | Student Learning Outcomes |
|---|---|---|---|---|
| Week 1 |
|
Introduction and classification of PDE, Calculus review |
Multivariable Calculus, Chain Rule |
|
| Week 2 |
|
Applied examples of PDE |
Multivariable Calculus, Chain Rule |
|
| Week 3 |
|
The method of characteristics for first-order quasilinear equations |
Multivariable Calculus, Chain Rule |
|
| Week 4 |
|
The method of characteristics for first-order fully nonlinear equations |
Multivariable Calculus, Chain Rule |
|
| Week 5 |
|
Heat and wave equation on the whole real line |
Differentiation of integrals with respect to a parameter, integration by parts |
|
| Week 6 |
|
Initial-boundary value problem for heat and wave equation I |
Partial derivatives, chain rule |
|
| Week 7 |
|
Initial-boundary value problem for heat and wave equation II, introduction to Fourier series |
Partial derivatives, chain rule |
|
