Differential equations: Difference between revisions
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var N = brd.create('slider',[[-7,9.5],[7,9.5],[-15,10,15]], {name:'N'}); | var N = brd.create('slider',[[-7,9.5],[7,9.5],[-15,10,15]], {name:'N'}); | ||
var slider = brd.create('slider',[[-7,8],[7,8],[-15,0,15]], {name:'c'}); | var slider = brd.create('slider',[[-7,8],[7,8],[-15,0,15]], {name:'c'}); | ||
var P = brd.create('point',[0,1], {name:'( | var P = brd.create('point',[0,1], {name:'(t_0, y_0)'}); | ||
var f; | var f; | ||
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* [[Autocatalytic process]] | * [[Autocatalytic process]] | ||
* [[Logistic process]] | * [[Logistic process]] | ||
===The underlying JavaScript code=== | ===The underlying JavaScript code=== | ||
<source lang="xml"> | <source lang="xml"> | ||
<form> | <form> | ||
f( | f(t,y)=<input type="text" id="odeinput" value="(2-t)*y + c"><input type=button value="ok" onclick="doIt()"> | ||
</form> | </form> | ||
</source> | </source> | ||
| Line 62: | Line 61: | ||
var N = brd.create('slider',[[-7,9.5],[7,9.5],[-15,10,15]], {name:'N'}); | var N = brd.create('slider',[[-7,9.5],[7,9.5],[-15,10,15]], {name:'N'}); | ||
var slider = brd.create('slider',[[-7,8],[7,8],[-15,0,15]], {name:'c'}); | var slider = brd.create('slider',[[-7,8],[7,8],[-15,0,15]], {name:'c'}); | ||
var P = brd.create('point',[0,1], {name:'( | var P = brd.create('point',[0,1], {name:'(t_0, y_0)'}); | ||
var f; | var f; | ||
function doIt() { | function doIt() { | ||
var snip = brd.jc.snippet(document.getElementById("odeinput").value, true, ' | var snip = brd.jc.snippet(document.getElementById("odeinput").value, true, 't, y'); | ||
f = function ( | f = function (t, yy) { | ||
return [snip( | return [snip(t, yy[0])]; | ||
} | } | ||
brd.update(); | brd.update(); | ||
Latest revision as of 08:46, 18 December 2020
Display solutions of the ordinary differential equation
- [math]\displaystyle{ y'= f(t,y) }[/math]
with initial value [math]\displaystyle{ (t_0,y_0) }[/math].
It is easy to incorporate sliders: give the slider a (unique) name and use this name in the equation. In the example below, the slider name is [math]\displaystyle{ c }[/math].
See also
- Systems of differential equations
- Lotka-Volterra equations
- Epidemiology: The SIR model
- Population growth models
- Autocatalytic process
- Logistic process
The underlying JavaScript code
<form>
f(t,y)=<input type="text" id="odeinput" value="(2-t)*y + c"><input type=button value="ok" onclick="doIt()">
</form>
var brd = JXG.JSXGraph.initBoard('jxgbox', {axis:true, boundingbox:[-11,11,11,-11]});
var N = brd.create('slider',[[-7,9.5],[7,9.5],[-15,10,15]], {name:'N'});
var slider = brd.create('slider',[[-7,8],[7,8],[-15,0,15]], {name:'c'});
var P = brd.create('point',[0,1], {name:'(t_0, y_0)'});
var f;
function doIt() {
var snip = brd.jc.snippet(document.getElementById("odeinput").value, true, 't, y');
f = function (t, yy) {
return [snip(t, yy[0])];
}
brd.update();
}
function ode() {
return JXG.Math.Numerics.rungeKutta('heun', [P.Y()], [P.X(), P.X()+N.Value()], 200, f);
}
var g = brd.create('curve', [[0],[0]], {strokeColor:'red', strokeWidth:2});
g.updateDataArray = function() {
var data = ode();
var h = N.Value()/200;
var i;
this.dataX = [];
this.dataY = [];
for(i=0; i<data.length; i++) {
this.dataX[i] = P.X()+i*h;
this.dataY[i] = data[i][0];
}
};
doIt();
