Difference between revisions of "Separation of Variables"
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*[https://youtu.be/Vc6MwLVdCuM Solving a Separable Differential Equation, Another Example #2] by patrickJMT | *[https://youtu.be/Vc6MwLVdCuM Solving a Separable Differential Equation, Another Example #2] by patrickJMT | ||
+ | |||
+ | ==Licensing== | ||
+ | Content obtained and/or adapted from: | ||
+ | * [https://en.wikibooks.org/wiki/Ordinary_Differential_Equations/Separable_equations:_Separation_of_variables Separation of Variables, Wikibooks: Ordinary Differential Equations/Separable equations] under a CC BY-SA license |
Latest revision as of 11:14, 29 October 2021
Contents
Definition
A separable ODE is an equation of the form
for some functions , . In this chapter, we shall only be concerned with the case .
We often write for this ODE
for short, omitting the argument of .
[Note that the term "separable" comes from the fact that an important class of differential equations has the form
for some ; hence, a separable ODE is one of these equations, where we can "split" the as .]
Informal derivation of the solution
Using Leibniz' notation for the derivative, we obtain an informal derivation of the solution of separable ODEs, which serves as a good mnemonic.
Let a separable ODE
be given. Using Leibniz notation, it becomes
- .
We now formally multiply both sides by and divide both sides by to obtain
- .
Integrating this equation yields
- .
Define
- ;
this shall mean that is a primitive of . If then is invertible, we get
- ,
where is a primitive of ; that is, , now inserting the variable of back into the notation.
Now the formulae in this derivation don't actually mean anything; it's only a formal derivation. But below, we will prove that it actually yields the right result.
General solution
- Theorem 2.1:
- Let a separable, one-dimensional ODE
- be given, where is never zero. Let be an antiderivative of and an antiderivative of . If is invertible, the function
- solves the ODE under consideration.
Proof:
By the inverse and chain rules,
- ;
since is never zero, the fraction occuring above involving is well-defined.
Resources
- Differential Equations: Separation of Variables by James Sousa
- Ex.1 Differential Equations: Separation of Variables by James Sousa
- Ex.2 Differential Equations: Separation of Variables by James Sousa
- Ex.3 Differential Equations: Separation of Variables by James Sousa
- Ex 1: Initial Value Problem - Separation of Variables by James Sousa
- Ex 2: Initial Value Problem - Separation of Variables by James Sousa
Licensing
Content obtained and/or adapted from:
- Separation of Variables, Wikibooks: Ordinary Differential Equations/Separable equations under a CC BY-SA license