# How to draw three-dimensional image: Plot3D NDSolve

``````m = 10; c = 2; k = 5; F = 12;

NDSolve[{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*f*t])*x[t] == F*Sin[2*Pi*f*t],
x[0] == 0, x'[0] == 0}, x[t], {t, 0, 30}]
``````

{f, 0, 5} ( 0=< f <= 5 )

How to draw three-dimensional image:

x = u(t,f)

............

If f = 0.1,0.2,... 5, We can solve the equation:

``````NDSolve[{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*f*t])*x[t] == F*Sin[2*Pi*f*t],
x[0] == 0, x'[0] == 0}, x[t], {t, 0, 30}]
``````

x is a function of t and f

...............

``````m = 10; c = 2; k = 5; F = 12;

f = 0.1

s = NDSolve[{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*f*t])*x[t] == F*Sin[2*Pi*f*t],
x[0] == 0, x'[0] == 0}, x[t], {t, 0, 30}]
Plot[Evaluate[x[t] /. s], {t, 0, 30}, PlotRange -> All]
``````

f = 0.1

f = 0.2

f = 0.3

f = 5

How to draw three-dimensional image: x = u(t,f)

-
I attempted to fix the formatting in your question. Please tell me if that is what you intended. Also, I really don't understand your question. Would you please try to clarify it? –  Mr.Wizard Nov 18 '11 at 8:24
Trying the given code gives the error message `NDSolve::nlnum: "The function value {0.,1/10\ (0.\[VeryThinSpace]+12\ Sin[0.0193488\ f])}\\n is not a list of numbers with dimensions {2} at \!\({t, x[t], \*SuperscriptBox[\"x\", \"\[Prime]\",MultilineFunction->None][t]}\) = {0.00307945,0.,0.}."` — should that have been an uppercase F in the sine? –  celtschk Nov 18 '11 at 8:31
m = 10; c = 2; k = 5; F = 12; If f = 0.1,0.2,... 5, We can solve the equation: NDSolve[{mx''[t] + cx'[t] + (kSin[2*Pift])*x[t] == FSin[2*Pift], x[0] == 0, x'[0] == 0}, x[t], {t, 0, 30}] x is a function of t and f –  h02h001 Nov 18 '11 at 8:36
Thank you for updating your question. +1 –  Mr.Wizard Nov 18 '11 at 9:21

Here goes a solution.

``````m = 10; c = 2; k = 5; F = 12;
NumberOfDiscrit\$f = 20;(* Number of points you want to divide 0<=f<=5*)
NumberOfDiscrit\$t = 100;(* Number of points you want to divide 0<=t<=30 *)
fValues = Range[0., 5., 5./(NumberOfDiscrit\$f - 1)];
tValues = Range[0., 30., 30./(NumberOfDiscrit\$t - 1)];
res = Map[(x /.
First@First@
NDSolve[{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*#*t])*x[t] ==
F*Sin[2*Pi*#*t], x[0] == 0, x'[0] == 0}, x, {t, 0, 30}]) &,
fValues];
AllDat = Map[(#@tValues) &, res];
InterpolationDat =
Flatten[Table[
Transpose@{tValues,
Table[fValues[[j]], {i, 1, NumberOfDiscrit\$t}],
AllDat[[j]]}, {j, 1, NumberOfDiscrit\$f}], 1];
Final3DFunction = Interpolation[InterpolationDat];
Plot3D[Final3DFunction[t, f], {t, 0, 30}, {f, 0, 5}, PlotRange -> All,
PlotPoints -> 60, MaxRecursion -> 3, Mesh -> None]
``````

You can use `Manipulate` to dynamically change some of the parameters. By the way the above 3D picture may be misleading if one takes `f` as a continuous variable in `u(t,f)`. You should note that the numerical solution seems to blow up for asymptotic values of `t>>30`. See the picture below.

Hope this helps you out.

-
Thank you very much. –  h02h001 Nov 18 '11 at 15:21

You could also do something like this

``````Clear[f]
m = 10; c = 2; k = 5; F = 12;

s = NDSolve[{m*Derivative[2, 0][x][t, f] +
c*Derivative[1, 0][x][t, f] + (k*Sin[2*Pi*f*t])*x[t, f] == F*Sin[2*Pi*f*t],
x[0, f] == 0,
Derivative[1, 0][x][0, f] == 0}, x, {t, 0, 30}, {f, 0, .2}]

Plot3D[Evaluate[x[t, f] /. s[[1]]], {t, 0, 30}, {f, 0, .2}, PlotRange -> All]
``````

-
I tried to figure this out myself, but I gave up. I knew it had to be possible. Big +1. –  Mr.Wizard Nov 18 '11 at 12:19
Thank you very much. I tried to do like this way, but I gave up. Because I do not know to write this expression: Derivative[1, 0][x][0, f] == 0 –  h02h001 Nov 18 '11 at 15:18

This should do it.

``````m = 10; c = 2; k = 5; F = 12;

fun[f_?NumericQ] :=
Module[
{x, t},
First[x /.
NDSolve[
{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*f*t])*x[t] == F*Sin[2*Pi*f*t],
x[0] == 0, x'[0] == 0},
x, {t, 0, 30}
]
]
]

ContourPlot[fun[f][t], {f, 0, 5}, {t, 0, 30}]
``````

Important points:

• The pattern _?NumericQ prevents `fun` from being evaluated for symbolc arguments (think `fun[a]`), and causing `NDSolve::nlnum` errors.

• Since `NDSolve` doesn't appear to localize its function variable (`t`), we needed to do this manually using `Module` to prevent conflict between the `t` used in `NDSolve` and the one used in `ContourPlot`. (You could use a differently named variable in `ContourPlot`, but I think it was important to point out this caveat.)

For a significant speedup in plotting, you can use memoization, as pointed out by Mr. Wizard.

``````Clear[funMemo] (* very important!! *)

funMemo[f_?NumericQ] :=
funMemo[f] = Module[{x, t},
First[x /.
NDSolve[{m*x''[t] + c*x'[t] + (k*Sin[2*Pi*f*t])*x[t] ==
F*Sin[2*Pi*f*t], x[0] == 0, x'[0] == 0}, x, {t, 0, 30}]]]

ContourPlot[funMemo[f][t], {f, 0, 5}, {t, 0, 30}] (* much faster than with fun *)
``````

If you're feeling adventurous, and willing to explore Mathematica a bit more deeply, you can further improve this by limiting the amount of memory the cached definitions are allowed to use, as I described here.

Let's define a helper function for enabling memoization:

``````SetAttributes[memo, HoldAll]
SetAttributes[memoStore, HoldFirst]
SetAttributes[memoVals, HoldFirst]

memoVals[_] = {};

memoStore[f_, x_] :=
With[{vals = memoVals[f]},
If[Length[vals] > 100, f /: memoStore[f, First[vals]] =.;
memoVals[f] ^= Append[Rest[memoVals[f]], x],
memoVals[f] ^= Append[memoVals[f], x]];
f /: memoStore[f, x] = f[x]]

memo[f_Symbol][x_?NumericQ] := memoStore[f, x]
``````

Then using the original, non-memoized `fun` function, plot as

``````ContourPlot[memo[fun][f][t], {f, 0, 5}, {t, 0, 30}]
``````
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This does not copy and paste correctly on my machine. –  Mr.Wizard Nov 18 '11 at 10:53
@Mr.Wizard Oops ... –  Szabolcs Nov 18 '11 at 11:07
Now it works, but I think you will want to add memoization. –  Mr.Wizard Nov 18 '11 at 11:38
@Mr.Wizard Good point. I added memory-constrained memoization as well. –  Szabolcs Nov 18 '11 at 12:11
Nice. Now I am happy. +1 ;-) –  Mr.Wizard Nov 18 '11 at 12:16