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I have a function f(x,t) and I'd like to plot the function of the solution x(t) of f(x(t),t)=0 using Mathematica. How can I do it?

Mathematica is often quite different to other programming languages I can use. Normally, I would try something looking like:

Create arrays X, T

For t in T do
   solve (numerically) f(x,t)=0, append the solution to X

Plot X

However, I don't know really well how to use loops in Mathematica yet, and the same for arrays, so I'm having serious problems doing this.

Is there some rapid, direct way of solving this problem with Mathematica? If not, could somebody please help me out with this?

Also, does anybody have a better title for the question?


Edit: Following the suggestion of @LutzL, I would try something like the following:

Table[FindRoot[f[x,t]==0,{x,x_0}],{t,start,stop,step}]

Would this work correctly?

I still have a problem, because my function f(x,t) is highly nonlinear, and thus i would like to input a good starting point for every t. Specifically, I know the solution for t=0 and I would like to use for time step t_{n+1} the solution for t_n. Is there a way to do this?


Edit 2: I solved the problem the following way:

tmax = 10; nsteps = 100*tmax;
thrust = {v/2 - g}; angle = {Pi/2};
For[i = 1, i <= nsteps, i++, 
  sol = {thr, \[Theta]} /. 
    FindRoot[{eq1[i*tmax/nsteps], 
      eq2[i*tmax/nsteps]}, {{thr, Last[thrust]}, {\[Theta], 
       Last[angle]}}]; AppendTo[thrust, sol[[1]]]; 
  AppendTo[angle, sol[[2]]]];
ListPlot[Table[{i*tmax/nsteps, thrust[[i + 1]]}, {i, 0, nsteps}]]
ListPlot[Table[{i*tmax/nsteps, angle[[i + 1]]/Pi}, {i, 0, nsteps}]]

where eq1 and eq2 are my equations and thrust and angle are the solutions

share|improve this question
    
You could just simply plot the level sets of f(x,t) in a contour plot. There are options to control which levels are drawn, so the plot of f(x,t)=0 can be ensured. –  LutzL Mar 1 at 21:43
    
@LutzL The problem here is that x is a vector, so it would be really messy to do so. Thanks for the good idea anyway. –  Daniel Robert-Nicoud Mar 1 at 21:48
    
Then I would look into building an array of solution points using the table command and the numerical solvers. –  LutzL Mar 1 at 21:50
    
@LutzL I edited my answer with my attempt to do it using Table. I still have a little issue. Do you have any more suggestions? –  Daniel Robert-Nicoud Mar 1 at 22:45
    
This claims to deal with the initial point problem (library.wolfram.com/infocenter/MathSource/6710). I do not have mathematica on the computer to try it out or even find out what method is employed... –  LutzL Mar 1 at 22:54

1 Answer 1

up vote 1 down vote accepted

A way to do it would be to create a list and then to plot it.

You have x(0) and you want x(t) for t>0. You can use the expression Szabolcs provides:

root(t_NumericQ, x0_):= Module[{z}, z = z /. FindRoot[f[z, t] == 0, {z, x0}]]

And then you compute and plot a list.

list[tin_, tend_, tstep_, x0_] := Module[{z = x0, t = tin}, lis = {}; 
While[t < tend, z = root[t, z]; lis = Append[lis, {t, z}]; t = t + tstep; ];
ListPlot[lis]]

Or you can change the last line for a x=Interpolation[lis] and x[t] will be an interpolation function for the solution x(t)

Moreover you can test whether other solutions for x(t) are possible replacing root[t,z] for RandomReal[{x_1,x_2}] where x_1and x_2 are in the range of the x space you want to explore.

share|improve this answer
    
Thanks! I put in my question how I solved the problem, but I must say that my way looks way uglier than yours. –  Daniel Robert-Nicoud Mar 6 at 18:38
    
Ow! I didn't see your last edit. I'll have a look at it now. Another thing that can be interesting is to look for extra solutions.. –  Alasanid Mar 7 at 10:23

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