# mathematica Plot with Manipulate shows no output

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]}]
``````
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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.

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

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

`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.

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