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Is it possible to overlay two or more graphics in Mathematica, if the graphics are generated by functions such as ReliefPlot or DensityPlot, using Opacity to control the appearance?

For example:

a = ReliefPlot[
        Table[i + Sin[i^2 + j^2], {i, -4, 4, .03}, {j, -4, 4, .03}], ImageSize -> 100]
b = ReliefPlot[
        Table[i + Sin[i^3 + j^3], {i, -4, 4, .03}, {j, -4, 4, .03}], ImageSize -> 100]

combines the two, but I can't work out how to insert an Opacity command anywhere here such that both are visible. The documentation states that these functions accept the same options as Graphics ("ReliefPlot has the same options as Graphics, with the following additions and changes:"), but I don't understand how to control the graphics... (And I may be confused about the difference between graphics options and directives, as well.)

Enlightenment - and less opacity - very welcome!

Edit: Wow, you guys are quicker than my version of Mathematica - thanks!

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It's hard to choose, sometimes... :) – cormullion Nov 9 '11 at 16:17
I think Yoda's is more general, and allows for finer control over styles. – Brett Champion Nov 9 '11 at 16:27
And the styles need be specified just once, I suppose. – cormullion Nov 9 '11 at 16:33

5 Answers 5

up vote 11 down vote accepted

You'll have to issue the opacity directive to ColorFunction like so:

a = ReliefPlot[
  Table[i + Sin[i^2 + j^2], {i, -4, 4, .03}, {j, -4, 4, .03}], 
  ImageSize -> 100]
b = ReliefPlot[
  Table[i + Sin[i^3 + j^3], {i, -4, 4, .03}, {j, -4, 4, .03}], 
  ImageSize -> 100, 
  ColorFunction -> (Directive[Opacity[0.5], 
      ColorData["Rainbow"][#]] &)]
Show[a, b]

enter image description here

In general, in all *Plot* functions, you control opacity with either PlotStyle or ColorFunction, as the case may be. If this were just a Graphics primitive, you'd probably do something like Graphics[{Opacity[0.5], object}].

share|improve this answer

Since ReliefPlot doesn't have a PlotStyle option, you can use BaseStyle -> Opacity[0.5] to introduce transparency into the graphics.

enter image description here

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hold on... this works only if both images have the same BaseStyle. – abcd Nov 9 '11 at 16:19
@yoda BaseStyle is an option to Graphics, so you get all the usual behaviors of how Show combines options from multiple graphics. Now that I think about this for a moment more, you could just apply the BaseStyle option in the call to Show, rather than adding it to the individual plots. Note that BaseStyle will apply to the entire graphic; not just the primitives from either a or b. – Brett Champion Nov 9 '11 at 16:25
Yeah, that's what I was pointing out. If you wanted to overlay the second plot with 0.5 opacity on the first like in my answer, you cannot use BaseStyle... – abcd Nov 9 '11 at 16:26

An alternative is to work with Images and the ReliefImage function, and then compose the resulting images together using ImageCompose:

 ReliefImage[Table[i + Sin[i^2 + j^2], {i, -4, 4, .03}, {j, -4, 4, .03}]],
 {ReliefImage[Table[i + Sin[i^3 + j^3], {i, -4, 4, .03}, {j, -4, 4, .03}]], 

enter image description here

Since ReliefPlot also essentially returns pixel data in a Graphics-compatible format, perhaps Images will suit you better.

The default colour function of ReliefImage is different: you can use ColorFunction -> "LakeColors" to switch to ReliefPlot's one.

Originally I had a function here to extract the raster data from ReliefPlot, but then Brett Champion pointed to RasterImage in the comment below

share|improve this answer
Assuming V8, you could also use ReliefImage instead of ReliefPlot, although then you have to reverse the input due to differences in coordinate systems, and there's also a different default color function. (The default color function for ReliefImage is a bit dark for my tastes, but ImageAdd[a,b] looks decent.) – Brett Champion Nov 9 '11 at 16:17
@Brett I was looking for that but couldn't find it!! (Some Linux interfaces are really unwieldy and frustrating ...) Will correct the answer. – Szabolcs Nov 9 '11 at 16:20

The answers using transparency will work in a very general way, but in this particular example of combining two ReliefPlot[]s, you might want to consider plotting the sum of the two:

f[i_] := i + Sin[i^2 + j^2];
g[i_] := i + Sin[i^3 + j^3];
ReliefPlot[Table[f[i] + g[i], {i, -4, 4, .03}, {j, -4, 4, .03}], ImageSize -> 100]
share|improve this answer
Thanks - it's a better solution in some ways! One of the good things about Mathematica is how it allows you to approach problems from various angles. – cormullion Nov 9 '11 at 19:17
Show[a, {Opacity[0.5],#}& /@ b]
share|improve this answer
+1. Alternatively, one can use Show[a, {Opacity[0.5], #} & @@@ b] with the same effect. – Alexey Popkov Nov 10 '11 at 3:07
@AlexeyPopkov While celtschk's command works, your command fails for me... – jibe Sep 15 at 15:39
@jibe Which Mathematica version do you use? I just have checked both solutions with version 10.2 on Win7 x64 and the output is visually the same. Please check again starting from the code in the question. – Alexey Popkov Sep 15 at 15:49
@AlexeyPopkov You're absolutely right. On Mac OS 10.8.5, with MMA 10.2, the examples of the OP with ReliefPlot does work. BUT, the test I made was with (contour) plots of my own and it did not work. Can you try to run this (without the ;, but I don't manage to indent in the comments...) ? a = ContourPlot[Sin[x + y], {x, 0, 1}, {y, 0, 1}]; b = ContourPlot[Cos[x - y], {x, 0, 1}, {y, 0, 1}]; Show[a, {Opacity[0.5], #} & /@ b]; Show[a, {Opacity[0.5], #} & @@@ b]; – jibe Sep 15 at 15:59
@jibe ContourPlot produces a Graphics expression with entirely different structure than ReliefPlot. You can see this structure by applying InputForm or by using my specially-designed shortInputForm function. The code in my comment was intended only for ReliefPlot and based on undocumented details of current implementation of ReliefPlot (which can be changed in future versions of Mathematica). – Alexey Popkov Sep 15 at 16:50

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