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I needed some help with plotting a velocity vs forcing term diagram for a chaotic oscillator on mathematica.

Basically, I have to solve the following differential equation

x''[t] + b x'[t] - x[t] + x[t]^3 - f Cos[w t] == 0, x'[0] == 0, 
 x[0] == 0

and plot the velocity of my solution for times in the interval [0,1000] in increments of 2*Pi for different values of f.

That is, for each f in the interval [0,2] (in increments of .05), I will have approximately 150 velocity points, and I must plot all of these points on one graph.

I though about using a do loop and came up with something like


b = .1;
w = 1;
Period = 1;
tstep = 2 Pi/Period;

Do[{Do[{data = 
         x'[t] /. 
          NDSolve[{x''[t] + b x'[t] - x[t] + x[t]^3 - f Cos[w t] == 0,
             x'[0] == 0, x[0] == 0}, x[t], {t, 0, 1000}, 
           MaxSteps -> 59999]}]], {t, 0, 1000, tstep}]}, {t, 0, 1000, 
    1}]}, {f, 0, 2, .1}]

but had no luck.

How can I do this?

share|improve this question
Allow me to welcome you to StackOverflow and remind three things we usually do here: 1) As you receive help, try to give it too answering questions in your area of expertise 2) Read the FAQs 3) When you see good Q&A, vote them up by using the gray triangles, as the credibility of the system is based on the reputation that users gain by sharing their knowledge. Also remember to accept the answer that better solves your problem, if any, by pressing the checkmark sign – belisarius has settled May 16 '11 at 18:14
Your replacement rule, x'[t] /. NDSolve[...], won't work because NDSolve returns x[t] -> ..., but x'[t] internally has the form Derivative[1][x][t] which is very different. (You can check this yourself by using FullForm.) Replacement rules replace exactly the form you tell it to, and it can require a lot of effort to have them do any sort of transformation beyond the basic. This one qualifies as beyond basic. In those cases, FullForm and MatchQ are indispensable for determining what will and won't work. – rcollyer May 16 '11 at 18:34
You're not supposed to remove your question once you have received an answer. I've rolled back your last edit in which you did this. – Sjoerd C. de Vries May 16 '11 at 20:09
Thanks for the check mark. – Mr.Wizard May 17 '11 at 8:29
FP, is your update just to clarify the question, or are you hoping for a revised answer? – Mr.Wizard May 17 '11 at 18:54

1 Answer 1

up vote 2 down vote accepted

Does this do what you want?

b = .1;
w = 1;

sol := {f, 
  NDSolve[{x''[t] + b x'[t] - x[t] + x[t]^3 - f Cos[w t] == 0, 
     x'[0] == 0, x[0] == 0}, x[t], {t, 0, 1000}, MaxSteps -> 59999][[1, 1, 2]]}

interpsols = Table[sol, {f, 0, 2, 0.1}];

ListPlot[Table[interpsols, {t, 0, 1000, 2 Pi}]]

The Explanation

First, let me focus on sol. This is close to your own code (with a change) but refactored for clarity, rather than buried inside the loops.

  • sol := is equivalent to SetDelayed[sol, ...
  • This holds the unevaluated definition that it is given on the right-hand-side
  • The NDSolve operation is therefore not performed until sol is used somewhere

The change I made was to extract this portion from the result of NDSolve:


I do this with Part: NDSolve[...][[1, 1, 2]]

It could also be done with x[t] /. First @ NDSolve[...]

This extracted portion is paired with the current value of f in a list: {f, NDSolve[ ... } so that later they can be plotted.


interpsols = Table[sol, {f, 0, 2, 0.1}];

builds a table of the changing value of sol as it globally changes the value of f. This is where NDSolve is performed.

The result is a series of solutions for each value of f in this form:



ListPlot[Table[interpsols, {t, 0, 1000, 2 Pi}]]

creates a table by evaluating the entire series of results created above for globally changing values of t, and ListPlots it.

There are a few things more I would like to say but I am out of time. I will make a further edit in a few hours.

share|improve this answer
Yes, I think this fixes my problem. Thanks you so much! How does it work? – Frustrated Programmer May 16 '11 at 18:15
To honor his nickname, Mr. Wizard should answer -"It's magic"- – belisarius has settled May 16 '11 at 18:19
Haha, yes Also, why do the points have different colors? Is it because they correspond to the same t value but different f values? – Frustrated Programmer May 16 '11 at 18:21
Two nits: f should be incremented by 0.05 and the OP asked for the velocity. The second nit is easily fixable by prepending D[#, t]&@ in front of NDSolve. Otherwise, should work. – rcollyer May 16 '11 at 18:27
oh, I think I see, your iteration of D[#, t]&@ tells mathematica to take the derivative of the NDSolve solution for each t value, thereby giving me the velocity at each point. Also, if I do a listlineplot, I can see how my system changes with time for each f value, since each different line corresponds to the a set of points with the same f values but different time values right? – Frustrated Programmer May 16 '11 at 18:38

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