8

I want to draw points at the visible Mesh intersections, like this:

Plot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {1, 4}, Boxed -> False]

Desired output:

enter image description here

I could calculate where the Mesh is going to be, based on PlotRange and the Mesh cardinality, and draw points there, but I think there should be an easier alternative way.

A big plus is to be able to chose the point color based upon the function value. Also, labeling the points would be wonderful.

Any ideas?

4 Answers 4

8

For what it's worth, I like the simple solution as well. Plus it is easy to use the same coloring function for both the surface and the points:

g = Plot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {1, 4}, Boxed -> False, ColorFunction -> "Rainbow"];
p = ListPointPlot3D[Table[{x, y, Sin[x + y^2]}, {x, -3, 3, (3 - (-3))/(1 + 1)}, {y, -2, 2, (2 - (-2))/(4 + 1)}], ColorFunction -> "Rainbow", PlotStyle -> PointSize[Large]];
Show[g, p]

enter image description here

Edit: If we want to make this into a customized myPlot3D, I think the following should do:

myPlot3D[f_, {x_, xmin_, xmax_}, {y_, ymin_, ymax_}, 
   Mesh -> {i_Integer, j_Integer}, opts : OptionsPattern[]] := 
  Module[{g = 
     Plot3D[f, {x, xmin, xmax}, {y, ymin, ymax}, Mesh -> {i, j}, 
      Evaluate@FilterRules[{opts}, Options[Plot3D]]],
    stx = (xmax - xmin)/(i + 1),
    sty = (ymax - ymin)/(j + 1), pts},
   pts = ListPointPlot3D[
     Table[{x, y, f}, {x, xmin + stx, xmax - stx, stx}, {y, 
       ymin + sty, ymax - sty, sty}], 
     Evaluate@FilterRules[{opts}, Options[ListPointPlot3D]]];
   Show[g, pts]];

Note that options are applied to both plots, but are filtered first. I also removed the points on the contour of the plot. For example,

myPlot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {4, 10}, 
 Boxed -> False, ColorFunction -> "Rainbow", Axes -> False, 
 PlotStyle -> PointSize[Large]]

will give as a result

enter image description here

1
  • @Felix Trying to generalize this in my answer. Do you see a better way? Jul 22, 2011 at 14:33
5

Here is a very hackish approach: Grab the mesh lines in the output and look for intersections. It is quite doable since the output is a GraphicsComplex.
First, find the indices of the mesh line points in the graphics complex:

g=Plot3D[Sin[x+y^2],{x,-3,3},{y,-2,2},Mesh->{1,4},Boxed->False];
meshlineptindices=First/@Cases[g, _Line, Infinity]

Now, go through the lines pairwise and look for intersections. The following, uses NestWhile to recursively look at all pairs (first line, another line) for shorter and shorter sublists of the original list of meshlines. The resulting intersections are returned via Sow:

intesectionindices=
  Flatten@Reap@NestWhile[(
    Sow@Outer[Intersection,{First[#]},Rest[#],1]; 
    Rest[#]
  )&, meshlineptindices, Length[#]>0&]

Out[4]= {1260,1491,1264,1401,1284,1371,1298,1448,1205,1219,1528,1525,1526,1527}

Look up the indices in the GraphicsComplex:

intesections = Part[g[[1,1]],intesectionindices]
Out[5]= {{-3.,-1.2,-0.997667},{3.,-1.2,-0.961188},<...>,{0.,1.2,0.977754}}

Finally, show the points together with original graphics:

Show[g,Graphics3D[{Red,PointSize[Large],Point[intesections]}]]

output graphics

HTH

Update: To get the colored points, you could just use

Graphics3D[{PointSize[Large],({colorfunction[Last@#],Point[#]}&)/@intesections]}]
4

Well, Janus beat me to writing the answer. I couldn't figure out the part of using Part. In any case, here is a simplified version:

g = Plot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {1, 4}, Boxed -> False];
index = Cases[Cases[g, _Line, \[Infinity]], _Integer, \[Infinity]];
inter = Part[Select[Tally@index, Part[#, 2] > 1 &], All, 1];
Show[g, Graphics3D[{Red, PointSize[Large], Point[Part[g[[1, 1]], inter]]}]]

Image Output

Update:

If you only want the intersections of the mesh then you need to remove the points that are on the boundary. Here I make a 4 by 4 mesh.

g = Plot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {4, 4}, Boxed -> False];
index = Cases[Cases[g, _Line, \[Infinity]], _Integer, \[Infinity]];
inter = Part[Select[Tally@index, Part[#, 2] > 1 &], All, 1];
range = AbsoluteOptions[g, PlotRange][[1]][[2]];
interior = Select[
   Part[g[[1, 1]], inter],
   IntervalMemberQ[Interval[range[[1]]]*0.9999,  Part[#, 1]]  
     && 
     IntervalMemberQ[Interval[range[[2]]]*0.9999,  Part[#, 2]] 
    &
   ];
Show[g, Graphics3D[{Red, PointSize[Large], Point[interior] }]]

Interior Points

2

Whenever possible, I prefer to stay away from messing up with the Graphics FullForm. So, going into my original lines, almost the same as FelixCQ did and trying to get a general function.

Options[myPlot3D] = Options[Plot3D];
myPlot3D[f_, p__] :=
  Module[
   {g = Plot3D[f, p],
    (*Get the Mesh Divisions*)
    m = Flatten@Cases[{p}, HoldPattern[Rule[Mesh, r_]] -> r],
    stx, sty},
   (*Get PlotRange*)
   pr = (List @@@ Options[g, PlotRange])[[1, 2]];
   (*Get Mesh steps*)
   stx = (pr[[1, 2]] - pr[[1, 1]])/(First@m + 1);
   sty = (pr[[2, 2]] - pr[[2, 1]])/(Last@m + 1);
   (*Generate points*)
   pts = Point[
     Flatten[Table[{a, b, f /. {x -> a, y -> b}}, {a, 
        pr[[1, 1]] + stx, pr[[1, 2]] - stx, stx},
       {b, pr[[2, 1]] + sty, pr[[2, 2]] - sty, sty}], 1]];
   Show[g, Graphics3D[{PointSize[Large], pts}]]
   ];

myPlot3D[Sin[x + y^2], {x, -3, 3}, {y, -2, 2}, Mesh -> {1, 2}, 
 Boxed -> False, ColorFunction -> "Rainbow", Axes -> False]

enter image description here

The main problem here is that the plotted function must depend on formal parameters x and y ... must solve it :(

1
  • I have updated my answer, hope this is what you are looking for!
    – FelixCQ
    Jul 22, 2011 at 15:59

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