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I'm trying to plot points that I've created in a table in mathematica but for some reason one component of my points seems to have double braces around it while the other only has one as below:


and list plot will not recognize these as points and will not plot them. Here is my mathematica code:

b = .1;
w = 1;
Period = 1;
tstep = 2 Pi/Period;
s = NDSolve[{x''[t] + b x'[t] - x[t] + x[t]^3 - .5 Cos[w t] == 0, 
 x'[0] == 0, x[0] == 0}, x[t], {t, 0, 1000}, MaxSteps -> Infinity];
x[t_] = x[t] /. s
data = Table[Evaluate[{x'[t], .5}], {t, 0, 1000, tstep}]

I've also tried using the command

ListPlot[Flatten[Table[Evaluate[{x'[t], .5}], {t, 0, 1000, tstep}]]]

to no avail as well as

ListPlot[Table[Evaluate[{Flatten[x'[t]], .5}], {t, 0, 1000, tstep}]]]

How can I remove the {}?

share|improve this question
While you're allowed to edit your own questions, it is somewhat bad form to remove so much of them that the answers appear to be answering a completely different question as they are privy to details no longer present. Hence, I rolled it back to the previous version. –  rcollyer May 17 '11 at 11:41
To clarify, the revised version is lacking enough detail to be able to answer it. If you had posted that version initially, you would have been asked for all the details you original question had. Also, it is very likely it would have been voted down, precisely because it could not have been answered in that form. –  rcollyer May 17 '11 at 15:51

4 Answers 4

up vote 1 down vote accepted

My colleagues are correct, but I think there is more that can be said. First, to your actual question. The output of NDSolve is a list of the form

{{x[t]->InterpolatingFunction[...]}, {x[t]->InterpolatingFunction[...]}, ...}

where the second and subsequent replacement rules are only there if more than one solution is present. I have never encountered a case using NDSolve where that is true, but it makes the answer consistent with Solve, where multiple solutions is not uncommon. Therefor, with only one solution, you have a double list, i.e.


As per Mr. Wizard, you can use First, or you can use Part, i.e.

NDSolve[ ... ][[ 1 ]]

which is my preferred method, although it is slightly more difficult to read and may obscure your intent. You should be aware that the InterpolatingFunction that NDSolve returns is a function, and it will accept variables directly. So, the variables on the left hand side of the declarations

x[t_] = x[t] /. s

and from Belisarius

xr[u_] := ((x[t] /. s[[1]]) /. t -> u)

are superfluous at best, and the second one requires the replacement to occur every time xr is used. Instead, you can declare

x = x[t] /. s

and then writing x[t] afterwards will return IntepolatingFunction[t], exactly like you want. Then, as Belisarius points out, you can use it, or its derivative, in Plot directly, instead of first building a table of values and feeding them into ListPlot.

Edit: when I first posted this, I didn't notice a quirk with NDSolve. If you explicitly solve for x[t] not x, then NDSolve returns InterpolatingFunction[...][t], but if you just solve for x you get what I posted. This quirk allows both the OP's and Belisarius's solutions to function, otherwise the replacement shouldn't occur.

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Please post the code for plotting x'[t]. I don't get it. Tnx! –  belisarius May 16 '11 at 11:45
@belisarius, it is exactly the same form as you have posted: Plot[x'[t], {t, 0, 30}]. See also the second example under "Basic Examples" in the IntepolatingFunction help page. –  rcollyer May 16 '11 at 11:56
Thank you guys! All your suggestions were really helpful and I got everything to work! –  Frustrated Programmer May 16 '11 at 17:32

You may try something along these lines:

b = .1;
w = 1;
s = NDSolve[{x''[t] + b x'[t] - x[t] + x[t]^3 - .5 Cos[w t] == 0, 
    x'[0] == 0, x[0] == 0}, x[t], {t, 0, 1000}, MaxSteps -> Infinity];

xr[u_] := ((x[t] /. s[[1]]) /. t -> u)
Plot[(xr'[u]), {u, 0, 30}]  

enter image description here

But I am not sure what are you trying to get from the {x'[t], .5} part

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It is most likely that x'[t] is returning something of the form {x_i}. Try replacing the data=Table... line with this

data = Table[Evaluate[{First[x'[t]], .5}], {t, 0, 1000, tstep}]

An alternative would be to do

data=data /. {{x_}, y_} :> {x, y};

which uses ReplaceAll (/.) to replace every occurrence of {{x_i},y_i} with {x_i,y_i}


enter image description here

share|improve this answer
The problem is not caused by derivative but by NDSolve returning its answer in {{x[t]-> ...}} form. This is done to be consistent with output in the case where more solutions are returned. –  Sjoerd C. de Vries May 15 '11 at 8:11
@Sjoerd: Yes, that is correct, but OP just wanted to know how to fix it in the Table, and that's what I answered. Fixing the output of NDSolve like @Mr. Wizard is also an option, but it does change x[t] from a row vector to a column vector, and that might break OP's code later on if it depends on it. –  r.m. May 15 '11 at 14:15

There are arguably better ways to accomplish what you are doing, but that is not what you asked.

To remove the extra {} recognize this comes from the result of NDSolve, and therefore use:

s = First @ NDSolve[{x''[t] + b x'[t] - x[t] + x[t]^3 - .5 Cos[w t] == 0, 
     x'[0] == 0, x[0] == 0}, x[t], {t, 0, 1000}, MaxSteps -> Infinity];
share|improve this answer

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