# Need help with solving differential equation and plotting velocity as a function of forcing term magnitude

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

``````Remove["Global`*"]

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

Do[{Do[{data =
Table[Flatten[
Evaluate[{f,
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}]
``````

How can I do this?

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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

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`:

``````InterpolatingFunction[{{0.,1000.}},<>][t]
``````

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.

Now:

``````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:

``````{{0.,InterpolatingFunction[{{0.,1000.}},<>][t]},
{0.1,InterpolatingFunction[{{0.,1000.}},<>][t]},
{0.2,InterpolatingFunction[{{0.,1000.}},<>][t]},
{0.3,InterpolatingFunction[{{0.,1000.}},<>][t]},
{0.4,InterpolatingFunction[{{0.,1000.}},<>][t]}
...
``````

Finally:

``````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 `ListPlot`s 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.

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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