Second order linear ODE: Difference between revisions
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</math> | </math> | ||
=== Particular solution === | |||
An exponential function has the property of being the same after many differentiation. We take advantage of this property and guess the solution to be the form of | An exponential function has the property of being the same after many differentiation. We take advantage of this property and guess the solution to be the form of | ||
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ar^2+br+c&=0 | ar^2+br+c&=0 | ||
\end{aligned} | \end{aligned} | ||
</math> | |||
Depending on the constants, it will give us anywhere from zero to two solutions: <math>y_1</math> and <math>y_2</math> | |||
=== General solution === | |||
<math> | |||
y(t) = c_1 y_1+c_2 y_2 | |||
</math> | </math> | ||
[[Category:Differential Equations]] | [[Category:Differential Equations]] |
Revision as of 21:34, 1 May 2024
Second order linear ODEs are in the following form:
Important types of second order linear ODEs include
- Homogeneous
- Constant coefficients (where p and q are constants)
Initial value problem
There are two arbitrary constants in the solution of a second order linear ODE, so we need two initial conditions.
Solutions
Constant coefficient, homogeneous
These are the simplest kind. They have the general form
Particular solution
An exponential function has the property of being the same after many differentiation. We take advantage of this property and guess the solution to be the form of
We substitute in the guess and obtain the characteristic equation
Depending on the constants, it will give us anywhere from zero to two solutions: and
General solution