# Plot a complex function in Mathematica

How can I make a Mathematica graphics that copies the behaviour of complex_plot in sage? i.e.

... takes a complex function of one variable, and plots output of the function over the specified xrange and yrange as demonstrated below. The magnitude of the output is indicated by the brightness (with zero being black and infinity being white) while the argument is represented by the hue (with red being positive real, and increasing through orange, yellow, ... as the argument increases).

Here's an example (stolen from M. Hampton of Neutral Drifts) of the zeta function with overlayed contours of absolute value:

In the Mathematica documentation page Functions Of Complex Variables it says that you can visualize complex functions using `ContourPlot` and `DensityPlot` "potentially coloring by phase". But the problem is in both types of plots, `ColorFunction` only takes a single variable equal to the contour or density at the point - so it seems impossible to make it colour the phase/argument while plotting the absolute value. Note that this is not a problem with `Plot3D` where all 3 parameters `(x,y,z)` get passed to `ColorFunction`.

I know that there are other ways to visualize complex functions - such as the "neat example" in the Plot3D docs, but that's not what I want.

Also, I do have one solution below (that has actually been used to generate some graphics used in Wikipedia), but it defines a fairly low level function, and I think that it should be possible with a high level function like `ContourPlot` or `DensityPlot`. Not that this should stop you from giving your favourite approach that uses a lower level construction!

Edit: There were some nice articles by Michael Trott in the Mathematica journal on:
Visualizing Riemann surfaces of algebraic functions, IIa, IIb, IIc, IId.
Visualizing Riemann surfaces demo.
The Return of Riemann surfaces (updates for Mma v6)

Of course, Michael Trott wrote the Mathematica guide books, which contain many beautiful graphics, but seem to have fallen behind the accelerated Mathematica release schedule!

• I haven't read the question yet, but +1 for the lovely plot :) – Dr. belisarius Mar 22 '11 at 0:02
• @belisarius: It's not my plot, but thanks! – Simon Mar 22 '11 at 0:08
• Are you sure you can't pass (x, y, z) into ColorFunction in DensityPlot? I've been able to do something along the lines of DensityPlot[..., ColorFunction->Function[{x, y, z}, f[x,y,z]]] – Mike Bailey Mar 22 '11 at 1:33
• @MikeBantegui: Note that only the `x` parameter in your function can be used and corresponds to the density at each point. See the first entry in the "MORE INFORMATION" section of the ColorFunction docs. It's strange that it doesn't yield a warning... – Simon Mar 22 '11 at 2:05
• @Mike, only `x` is given any info, if you use `ColorFunction->Function[{x,y,z}, Hue@(y/maxy)]` you only get gray. But, using `x/maxx` gives you something. – rcollyer Mar 22 '11 at 2:11

Here's my attempt. I winged the color function a bit.

``````ParametricPlot[
(*just need a vis function that will allow x and y to be in the color function*)
{x, y}, {x, -6, 3}, {y, -3, 3},

(*color and mesh functions don't trigger refinement, so just use a big grid*)
PlotPoints -> 50, MaxRecursion -> 0, Mesh -> 50,

(*turn off scaling so we can do computations with the actual complex values*)
ColorFunctionScaling -> False,

ColorFunction -> (Hue[
(*hue according to argument, with shift so arg(z)==0 is red*)
Rescale[Arg[Zeta[# + I #2]], {-Pi, Pi}, {0, 1} + 0.5], 1,

(*fudge brightness a bit:
0.1 keeps things from getting too dark,
2 forces some actual bright areas*)
Rescale[Log[Abs[Zeta[# + I #2]]], {-Infinity, Infinity}, {0.1, 2}]] &),

(*mesh lines according to magnitude, scaled to avoid the pole at z=1*)
MeshFunctions -> {Log[Abs[Zeta[#1 + I #2]]] &},

(*turn off axes, because I don't like them with frames*)
Axes -> False
]
``````

I haven't thought of a good way to get the mesh lines to vary in color. Easiest is probably to just generate them with `ContourPlot` instead of `MeshFunctions`.

• Nice! It's very close to the solution that I'd seen which uses `RegionPlot[True, {x, xmin, xmax}, {y, ymin, ymax}, opts...]` as the base `Graphics` object. – Simon Mar 22 '11 at 4:01
• @BrettChampion Nice plot! Is there an easy way to include some kind of plotlegend where hue runs from -pi to pi ? – Nick Feb 26 '15 at 13:53

Here's my variation on the function given by Axel Boldt who was inspired by Jan Homann. Both of the linked to pages have some nice graphics.

``````ComplexGraph[f_, {xmin_, xmax_}, {ymin_, ymax_}, opts:OptionsPattern[]] :=
RegionPlot[True, {x, xmin, xmax}, {y, ymin, ymax}, opts,
PlotPoints -> 100, ColorFunctionScaling -> False,
ColorFunction -> Function[{x, y}, With[{ff = f[x + I y]},
Hue[(2. Pi)^-1 Mod[Arg[ff], 2 Pi], 1, 1 - (1.2 + 10 Log[Abs[ff] + 1])^-1]]]
]
``````

Then we can make the plot without the contours by running

``````ComplexGraph[Zeta, {-7, 3}, {-3, 3}]
``````

We can add contours by either copying Brett by using and showing a specific plot mesh in the ComplexGraph:

``````ComplexGraph[Zeta, {-7, 3}, {-3, 3}, Mesh -> 30,
MeshFunctions -> {Log[Abs[Zeta[#1 + I #2]]] &},
MeshStyle -> {{Thin, Black}, None}, MaxRecursion -> 0]
``````

or by combining with a contour plot like

``````ContourPlot[Abs[Zeta[x + I y]], {x, -7, 3}, {y, -3, 3}, PlotPoints -> 100,
Contours -> Exp@Range[-7, 1, .25], ContourShading -> None];
Show[{ComplexGraph[Zeta, {-7, 3}, {-3, 3}],%}]
``````

Not a proper answer, for two reasons:

• This is not what you asked for
• I'm shamelessly using Brett's code

Anyway, for me the following is much more clear to interpret (brightness is ... well, just brightness):

Brett's code almost intact:

``````Plot3D[
Log[Abs[Zeta[x + I y]]], {x, -6, 3}, {y, -3, 3},
(*color and mesh functions don't trigger refinement,so just use a big grid*)
PlotPoints -> 50, MaxRecursion -> 0,
Mesh -> 50,
(*turn off scaling so we can do computations with the actual complex values*)
ColorFunctionScaling -> False,
ColorFunction -> (Hue[
(*hue according to argument,with shift so arg(z)==0 is red*)
Rescale[Arg[Zeta[# + I #2]], {-Pi, Pi}, {0, 1} + 0.5],
1,(*fudge brightness a bit:
0.1 keeps things from getting too dark,
2 forces some actual bright areas*)
Rescale[Log[Abs[Zeta[# + I #2]]], {-Infinity, Infinity}, {0.1, 2}]] &),
(*mesh lines according to magnitude,scaled to avoid the pole at z=1*)
MeshFunctions -> {Log[Abs[Zeta[#1 + I #2]]] &},
(*turn off axes,because I don't like them with frames*)
Axes -> False]
``````
• Not a proper answer, but I agree - it does make some aspects more clear and it is pretty! +1 – Simon Mar 22 '11 at 4:29