Stack Overflow is a community of 4.7 million programmers, just like you, helping each other.

Join them; it only takes a minute:

Sign up
Join the Stack Overflow community to:
  1. Ask programming questions
  2. Answer and help your peers
  3. Get recognized for your expertise

i'd like to have something like this

w[w1_] := 
 NDSolve[{y''[x] + y[x] == 2, y[0] == w1, y'[0] == 0}, y, {x, 0, 30}]

this seems like it works better but i think i'm missing smtn

w := NDSolve[{y''[x] + y[x] == 2, y[0] == w1, y'[0] == 0}, 
  y, {x, 0, 30}]
w2 = Table[y[x] /. w, {w1, 0.0, 1.0, 0.5}]

because when i try to make a table, it doesn't work:

Table[Evaluate[y[x] /. w2], {x, 10, 30, 10}]

i get an error:

ReplaceAll::reps: {<<1>>[x]} is neither a list of replacement rules nor a valid dispatch table, and so cannot be used for replacing. >>

ps: is there a better place to ask questions like that? mathematica doesn't have supported forums and only has mathGroup e-mail list. it would be nice if stackoverflow would have more specific mathematica tags like simplify, ndsolve, plot manipulation

share|improve this question
    
I think there are no enough Mma users participating in SO to open sub-tags, regrettably – Dr. belisarius Dec 7 '10 at 21:44
up vote 4 down vote accepted

There are a lot of ways to do that. One is:

w[w1_] :=  NDSolve[{y''[x] + y[x] == 2, 
                     y'[0] == 0},      y[0] == w1,
                      y[x], {x, 0, 30}];

Table[Table[{w1,x,y[x] /. w[w1]}, {w1, 0., 1.0, 0.5}]/. x -> u, {u, 10, 30, 10}] 

Output:

{{{0., 10, {3.67814}}, {0.5, 10, {3.25861}}, {1.,10, {2.83907}}}, 
 {{0., 20, {1.18384}}, {0.5, 20, {1.38788}}, {1.,20, {1.59192}}}, 
 {{0., 30, {1.6915}},  {0.5, 30, {1.76862}}, {1.,30, {1.84575}}}}
share|improve this answer

I see you already chose an answer, but I want to toss this solution for families of linear equations up. Specifically, this is to model a slight variation on Lotka-Volterra.

(*Put everything in a module to scope x and y correctly.*)
Module[{x, y},

 (*Build a function to wrap NDSolve, and pass it
              the initial conditions and range.*)
 soln[iCond_, tRange_, scenario_] :=
  NDSolve[{
    x'[t] == -scenario[[1]] x[t] + scenario[[2]] x[t]*y[t],
    y'[t] == (scenario[[3]] - scenario[[4]]*y[t]) - 
      scenario[[5]] x[t]*y[t],
    x[0] == iCond[[1]],
    y[0] == iCond[[2]]
    },
   {x[t], y[t]},
   {t, tRange[[1]], tRange[[2]]}
   ];

 (*Build a plot generator*)
 GeneratePlot[{iCond_, tRange_, scen_, 
    window_}] :=
  (*Find a way to catch errors and perturb iCond*)     
  ParametricPlot[
   Evaluate[{x[t], y[t]} /. soln[iCond, tRange, scen]],
   {t, tRange[[1]], tRange[[2]]},
   PlotRange -> window,
   PlotStyle -> Thin, LabelStyle -> Medium
   ];

 (*Call the plot generator with different starting conditions*)
 graph[scenario_, tRange_, window_, points_] :=
  {plots = {};
   istep = (window[[1, 2]] - window[[1, 1]])/(points[[1]]+1);
   jstep = (window[[2, 2]] - window[[2, 1]])/(points[[2]]+1);
   Do[Do[
     AppendTo[plots, {{i, j}, tRange, scenario, window}]
     , {j, window[[2, 1]] + jstep, window[[2, 2]] - jstep, jstep}
     ], {i, window[[1, 1]] + istep, window[[1, 2]] - istep, istep}];
   Map[GeneratePlot, plots]
   }
 ]
]

We can then use Animate (or table, but animate is awesome)

tRange = {0, 4};
window = {{0, 8}, {0, 6}};
points = {5, 5}
Animate[Show[graph[{3, 1, 8, 2, 0.5},
      {0, t}, window, points]], {t, 0.01, 5},
      AnimationRunning -> False]
share|improve this answer

Your Answer

 
discard

By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.