Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free, no registration required.

I was initially attempting visualize a 4 parameter function with Plot3D and Manipulate sliders (with two params controlled by sliders and the other vary in the "x-y" plane). However, I'm not getting any output when my non-plotted parameters are Manipulate controlled?

The following 1d plot example replicates what I'm seeing in the more complex plot attempt:

Clear[g, mu]
g[ x_] = (x Sin[mu])^2 
Manipulate[ Plot[ g[x], {x, -10, 10}], {{mu, 1}, 0, 2 \[Pi]}] 
Plot[ g[x] /. mu -> 1, {x, -10, 10}] 

The Plot with a fixed value of mu has the expected parabolic output in the {0,70} automatically selected plotrange, whereas the Manipulate plot is blank in the {0, 1} range.

I was suspecting that the PlotRange wasn't selected with good defaults when the mu slider control was used, but adding in a PlotRange manually also shows no output:

Manipulate[ Plot[ g[x], {x, -10, 10}, PlotRange -> {0, 70}], {{mu, 1}, 0, 2 \[Pi]}]
share|improve this question
add comment

2 Answers

up vote 7 down vote accepted

This is because the Manipulate parameters are local.

The mu in Manipulate[ Plot[ g[x], {x, -10, 10}], {{mu, 1}, 0, 2 \[Pi]}] is different from the global mu you clear on the previous line.

I suggest using

g[x_, mu_] := (x Sin[mu])^2
Manipulate[Plot[g[x, mu], {x, -10, 10}], {{mu, 1}, 0, 2 \[Pi]}]

The following works too, but it keeps changing the value of a global variable, which may cause surprises later unless you pay attention, so I don't recommend it:

g[x_] := (x Sin[mu])^2
Manipulate[
 mu = mu2;
 Plot[g[x], {x, -10, 10}],
 {{mu2, 1}, 0, 2 \[Pi]}
]

It may happen that you Clear[mu], but find that it gets a value the moment the Manipulate object is scrolled into view.

share|improve this answer
    
thanks, that works well, and generalized fine to the four parameter plot I was actually attempting. –  Peeter Joot Nov 1 '11 at 0:03
add comment

Another way to overcome Manipulate's localization is to bring the function inside the Manipulate[]:

Manipulate[Module[{x,g},
  g[x_]=(x Sin[mu])^2;
  Plot[g[x], {x, -10, 10}]], {{mu, 1}, 0, 2 \[Pi]}]

or even

Manipulate[Module[{x,g},
  g=(x Sin[mu])^2;
  Plot[g, {x, -10, 10}]], {{mu, 1}, 0, 2 \[Pi]}]

Both of which give

Define g inside manipulate

Module[{x,g},...] prevents unwanted side-effects from the global context. This enables a simple definition of g: I've had Manipulate[]ed plots with dozens of adjustable parameters, which can be cumbersome when passing all those parameters as arguments to the function.

share|improve this answer
add comment

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.