Integrating factor: Difference between revisions

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(Created page with "'''Integrating factors''' is a method to solve scalar Linear First Order ODE<nowiki/>s. Consider <math>y' + p(t) y = g(t)</math> We multiply bothsides by integrating factor <math>\mu(t)</math> such that the left hand side to be the ''exact derivative of a product.'' For this to work, we need <math>\mu' = \mu p</math> Applying the integrating factor, we have <math>\begin{aligned} \mu(t) y + \mu(t) p(t) y &= \mu(t) g(t) \\ \mu y' + \mu ' y &= \mu g \\ (\mu y)' &=...")
 
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'''Integrating factors''' is a method to solve scalar [[Linear First Order ODE]]<nowiki/>s.
[[Category:Differential Equations]]
'''Integrating factor''' is a method to solve scalar [[Linear First Order ODE]]<nowiki/>s. It takes advantage of the product rule of derivatives


Consider
<math>(\mu y)' = \mu' y + \mu y'</math>
 
and attempts to move all y terms into the same differential order.
 
Note that [[Separation of variables]] is generally easier when both options are available.
 
= Procedure =
Consider a linear first order ODE.


<math>y' + p(t) y = g(t)</math>
<math>y' + p(t) y = g(t)</math>
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<math>\mu' = \mu p</math>
<math>\mu' = \mu p</math>
<math>\mu(t) = C \exp\left[ \int p dt  \right]</math>


Applying the integrating factor, we have
Applying the integrating factor, we have
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From there, simple integration and algebra will solve the equation.
From there, simple integration and algebra will solve the equation.
<math>y(t) = \frac{1}{\mu(t)}\int \mu g dt + C </math>

Latest revision as of 19:46, 17 May 2024

Integrating factor is a method to solve scalar Linear First Order ODEs. It takes advantage of the product rule of derivatives

and attempts to move all y terms into the same differential order.

Note that Separation of variables is generally easier when both options are available.

Procedure

Consider a linear first order ODE.

We multiply bothsides by integrating factor such that the left hand side to be the exact derivative of a product. For this to work, we need

Applying the integrating factor, we have

From there, simple integration and algebra will solve the equation.