Autonomous ODE: Difference between revisions

From Rice Wiki
(Created page with "'''Autonomous ODE's''' have no explicit t-dependence. They come in the form <math> y' = F(y) </math> = Equilibrium = Autonomous ODE's have trivial ODE solutions. If <math> F(c) = 0 </math> then <math> y(t) = c </math> is the equilibrium solution of the ODE. If <math>y(t)</math> is a solution, then so is <math>z(t) = y(t + t_0)</math> for any constant <math>t_0</math> <math> \begin{aligned} y'(t) &= F(y(t))\\ z'(t) &= y'(t + t_0) \\ &= F(y(t + t_0)) \\ &= F(z(t)...")
 
No edit summary
 
(3 intermediate revisions by the same user not shown)
Line 5: Line 5:
</math>
</math>


= Equilibrium =
They can be solved by [[Separation of variables]] method.
 
= Equilibrium Solutions =


Autonomous ODE's have trivial ODE solutions.
Autonomous ODE's have trivial ODE solutions.
Line 21: Line 23:
</math>
</math>


is the equilibrium solution of the ODE.
is an equilibrium solution of the ODE.


If <math>y(t)</math> is a solution, then so is <math>z(t) = y(t + t_0)</math> for any constant <math>t_0</math>
If <math>y(t)</math> is a solution, then so is <math>z(t) = y(t + t_0)</math> for any constant <math>t_0</math>
Line 34: Line 36:
</math>
</math>


= Solution =
= General Solution =


Autonomous equations can be solved by [[Separation of Variables]] method.
Autonomous equations can be solved by [[Separation of Variables]] method.


= Phase Line =
= Equilibrium Analysis =


Consider <math>y' = F(y)</math>
Consider <math>y' = F(y)</math>


* If <math>F(y) = 0</math>, the solution is at equilibrium
* If <math>F(y) = 0</math>, the solution is at ''equilibrium''
* If <math>F(y) >0</math>, then ''y'' is increasing in ''t''
* If <math>F(y) >0</math>, then ''y'' is increasing in ''t''
* If <math>F(y) < 0</math>, then ''y'' is decreasing in ''t''
* If <math>F(y) < 0</math>, then ''y'' is decreasing in ''t''
This can be visualized on a '''phase line'''.
Some equilibrium solutions are [[Equilibrium#Stability|stable]], where the solutions converge and slight perturbations in ''y'' will not result in drastic changes in the solution. In contrast, some other equilibrium solutions are ''unstable'', where slight perturbation will result in drastic changes.
[[Category:Differential Equations]]

Latest revision as of 19:32, 17 May 2024

Autonomous ODE's have no explicit t-dependence. They come in the form

They can be solved by Separation of variables method.

Equilibrium Solutions

Autonomous ODE's have trivial ODE solutions.

If

then

is an equilibrium solution of the ODE.

If is a solution, then so is for any constant

General Solution

Autonomous equations can be solved by Separation of Variables method.

Equilibrium Analysis

Consider

  • If , the solution is at equilibrium
  • If , then y is increasing in t
  • If , then y is decreasing in t

This can be visualized on a phase line.

Some equilibrium solutions are stable, where the solutions converge and slight perturbations in y will not result in drastic changes in the solution. In contrast, some other equilibrium solutions are unstable, where slight perturbation will result in drastic changes.