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.

Is it possible to create graphics of spherical co-ordinate system like this in mathematica or should I use photoshop? I'm asking because I want a high resolution graphic, but lot of the files on internet are grainy when zoomed.

Here is the image:

enter image description here

share|improve this question
    
Hello and welcome to StackOverflow. Could you be a bit more specific about what you wish to accomplish? –  Mr.Wizard Apr 25 '11 at 0:07
    
@Mr. Wizard: You're crazy fast at editing! I thought I saw the post when it read 36 secs ago, and before I could add the image, you've done it! –  Lorem Ipsum Apr 25 '11 at 0:09
    
@yoda it's magic. ;-) –  Mr.Wizard Apr 25 '11 at 0:10
add comment

2 Answers

up vote 6 down vote accepted

The figure is made up of simple geometric shapes and these can be easily recreated in Mathematica using equations. Here is one that is close to this plot, which IMO is less cluttered than the above, but you can always use these ideas to recreate your image exactly.

Clear[ellipsePhi, ellipseTheta, circle]
circle[x_] = {Cos[x], Sin[x]};
ellipsePhi[x_, a_: - Pi/2] = {Cos[x - a]/3, Sin[x + a]};
ellipseTheta[x_, a_: 0] = {Cos[x + a], Sin[-x - a]/2};
(*Main circle*)
ParametricPlot[circle[x], {x, 0, 2 Pi},
 PlotStyle -> Black,
 Epilog -> First /@ {
    (*Ellipses*)

    ParametricPlot[{ellipsePhi[x], ellipsePhi[-x], ellipseTheta[-x], 
      ellipseTheta[x]}, {x, 0, Pi},
     PlotStyle -> {{Black, Dashed}, Black}],
    (*Co-ordinate axes*)

    Graphics[
     Table[GeometricTransformation[{Arrowheads[0.03], 
        Arrow[{{0, 0}, {1.2, 0}}]}, 
       ReflectionMatrix[circle[x]]], {x, {Pi/2, -Pi/4, Pi/8}}]],
(*mark point, rho, phi & theta directions*)

ParametricPlot[{ellipsePhi[x, Pi/2], ellipseTheta[-x, 13 Pi/20]}, {x, 
   0, Pi/4},
  PlotStyle -> {{Red, Thick}, {Blue, Thick}}] /. 
 Line[x__] :> Sequence[Arrowheads[0.03], Arrow[x]],
Graphics[{{Directive[Darker@Green, Thick], Arrowheads[0.03], 
   Arrow[{{0, 0}, ellipsePhi[-3 Pi/4]}]},
  {Directive[Purple], Disk[ellipsePhi[-3 Pi/4], 0.02]}}],
(*text*)
Graphics[{
  Text[Style["x", Italic, Larger], 1.25 circle[5 Pi/4]],
  Text[Style["y", Italic, Larger], 1.25 circle[0]],
  Text[Style["z", Italic, Larger], 1.25 circle[Pi/2]],
  Text[Style["\[Rho]", Italic, Larger], 0.4 circle[4 Pi/11]],
  Text[Style["\[CurlyPhi]", Italic, Larger], 
   1.1 ellipsePhi[Pi + Pi/5]],
  Text[Style["\[Theta]", Italic, Larger], 
   1.1 ellipseTheta[13 Pi/20 - Pi/8]],
  Text[Style["P", Italic, Larger], 1.2 ellipsePhi[-3 Pi/4 + Pi/24]]}]
},
 Axes -> False, PlotRange -> 1.3 {{-1, 1}, {-1, 1}}
 ]

which gives you this

enter image description here

Although it is possible to set the angles & arrows precisely, in some places (e.g., 13 Pi/20), I've only roughly approximated it. You really can't tell the difference in the final figure, but if you're picky you can change them and fix the positions exactly.

share|improve this answer
1  
I completely missed this possible reading. I was trying to figure out what kind of spherical-coordinate graphics, like those 360° photos, or environment maps, he was trying to make. –  Mr.Wizard Apr 25 '11 at 0:18
    
wow, that looks nice! –  J. B. DeShaw Apr 25 '11 at 0:31
add comment

This alternative solution has the advantage of being created using 3D directives. As such, it was easy to wrap inside a Manipulate and you can drag it with your mouse to change the viewpoint:

Manipulate[
 Module[{x = Sin[\[Phi]] Cos[\[Theta]], y = Sin[\[Phi]] Sin[\[Theta]],
    z = Cos[\[Phi]]},
  Show[
   ParametricPlot3D[
    {{Cos[t], Sin[t], 0},
     {0, Sin[t], Cos[t]},
     {Sin[t], 0, Cos[t]}},
    {t, 0, 2 \[Pi]}, PlotStyle -> Black, Boxed -> False, 
    Axes -> False, AxesLabel -> {"x", "y", "z"}],
   ParametricPlot3D[0.5*{Cos[t], Sin[t], 0}, {t, 0, \[Theta]}],
   ParametricPlot3D[
    RotationTransform[\[Theta], {0, 0, 1}][{Sin[t]/2, 0, 
      Cos[t]/2}], {t, 0, \[Phi]}],
   Graphics3D[{
     {{Blue, Thick, 
       Arrow[{{0, 0, 0}, #}] & /@ {{1, 0, 0}, {0, 1, 0}, {0, 0, 
          1}, {x, y, z}}},
      {Opacity[0.1],
       Red, Polygon[{{0, 0, 0}, {x, y, 0}, {x, y, z}}],
       Green, Polygon[{{0, 0, 0}, {x, 0, 0}, {x, y, 0}}]}},
     {Opacity[0.05], Sphere[{0, 0, 0}]},
     {Text["O", {-.03, -.03, -.03}],
      Text["X", {1.1, 0, 0}],
      Text["Q", {x, y, 0}, {1, 1}],
      Text["P", {x, y, z}, {0, -1}],
      Text["Y", {0, 1.1, 0}],
      Text["Z", {0, 0, 1.1}],
      Text["r", {x/2, y/2, 0}, {1, 1}],
      Text[
       "\[Theta]", {Cos[\[Theta]/2]/2, Sin[\[Theta]/2]/2, 0}, {1, 
        1}],
      Text["\[Phi]", 
       RotationTransform[\[Theta], {0, 0, 1}][{Sin[\[Phi]/2]/2, 0, 
         Cos[\[Phi]/2]/2}], {1, 1}]}}]]],
 {{\[Phi], \[Pi]/4}, 0.01, \[Pi]/2}, {{\[Theta], \[Pi]/4}, 0.01, 
  2 \[Pi]}]

spherical coordinates

share|improve this answer
    
There is a problem when phi == zero –  belisarius Apr 25 '11 at 3:09
    
code doesn't work in ver 7 :( –  J. B. DeShaw Apr 25 '11 at 15:41
    
i'd like to try your code before i accept an answer... could you make it work in the prev version? –  J. B. DeShaw Apr 25 '11 at 16:33
    
What error do you get? I have just tested it successfully under Mathematica version 7.0.1. BTW, I have changed the initial phi value to 0.01 to avoid the problem reported by belisarius. –  gdelfino Apr 26 '11 at 14:42
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.