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I am trying to use computer to show some planar geometry plots. I donot know what software can do this, or whether mathematica can produce such plots easily.

For example, I have the following plot to show. Given any triangle ABC, let AD be the line bisecting angle BAC and intersecting BC at D. Let M be the midpoint of AD. Let the circle whose diameter is AB intersects CM at F.

How to produce these plots and show the relevant labeling of the points in mma? Is it easy to do? Could someone please give an example, or give some recommendation as to what software is best suited for this purposes?

Many thanks.

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1  
If you do want to use Mma for this (which is ok), here's some demonstrations to get you started: TriangleCentroid, DistancesFromTheCentroid and lots more on Triangles –  Simon Feb 22 '11 at 22:05
    
@Simon: thank you for the pointers. –  Qiang Li Feb 22 '11 at 23:26
    
There's a PlaneGeometry package as part of the MathWorld packages. This is used to generate all of the geometry figures in MathWorld. This can probably do all that you want - but will take some time to learn. –  Simon Feb 25 '11 at 23:26
    
Here's a nice new demonstration showing some geometry in Mathematica. Four Lines and Four Circumcircles‌​. –  Simon Mar 24 '11 at 12:12

6 Answers 6

up vote 4 down vote accepted

I thought I'd show how one might approach this in Mathematica. While not the simplest thing to code, it does have flexibility. Also bear in mind that the author is fairly inept when it comes to graphics, so there might be easier and/or better ways to go about it.

offset[pt_, center_, eps_] := center + (1 + eps)*(pt - center);

pointfunc[{pt_List, center_List, ptname_String}, siz_, 
   eps_] := {PointSize[siz], Point[pt], 
   Inset[ptname, offset[pt, center, eps]]};

Manipulate[Module[
  {plot1, plot2, plot3, siz = .02, ab = bb - aa, bc = cc - bb, 
   ac = cc - aa, cen = (aa + bb)/2., x, y, soln, dd, mm, ff, lens, 
   pts, eps = .15},
  plot1 = ListLinePlot[{aa, bb, cc, aa}];
  plot2 = Graphics[Circle[cen, Norm[ab]/2.]];
  soln = NSolve[{Norm[ac]*({x, y} - aa).ab - 
       Norm[ab]*({x, y} - aa).ac == 
      0, ({x, y} - cc).({-1, 1}*Reverse[bc]) == 0}, {x, y}];
  dd = {x, y} /. soln[[1]];
  mm = (dd + aa)/2;
  soln = NSolve[{({x, y} - cen).({x, y} - cen) - ab.ab/4 == 
      0, ({x, y} - cc).({-1, 1}*Reverse[mm - cc]) == 0}, {x, y}];
  ff = {x, y} /. soln;
  lens = Map[Norm[# - cc] &, ff];
  ff = If[OrderedQ[lens], ff[[1]], ff[[2]]];
  pts = {{aa, cen, "A"}, {bb, cen, "B"}, {cc, cen, "C"}, {dd, cen, 
     "D"}, {ff, cen, "F"}, {mm, cen, "M"}, {cen, ff, "O"}};
  pts = Map[pointfunc[#, siz, eps] &, pts];
  plot3 = Graphics[Join[pts, {Line[{aa, dd}], Line[{cc, mm}]}]];
  Show[plot1, plot2, plot3, PlotRange -> {{-.2, 1.1}, {-.2, 1.2}}, 
   AspectRatio -> Full, Axes -> False]],
 {{aa, {0, 0}}, {0, 0}, {1, 1}, Locator},
 {{bb, {.8, .7}}, {0, 0}, {1, 1}, Locator},
 {{cc, {.1, 1}}, {0, 0}, {1, 1}, Locator}, 
 TrackedSymbols :> None]

Here is a screen shot.

enter image description here

Daniel Lichtblau Wolfram Research

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@Daniel: this is so nice. :) THanks a lot. Why the circle isn't really round? Removing AspectRatio -> 1 did seem to help. –  Qiang Li Feb 25 '11 at 1:56
    
@Qiang Li Good question about that roundness or lack thereof. There is some way to address that but I forgot what it is. Likewise some improvements can be made to avoid "jumpiness" as one moves the locators. So this code could be polished. –  Daniel Lichtblau Feb 25 '11 at 3:11
    
@Daniel: please let me know if you find the way to address both issues. I am eager to know! Many thanks. –  Qiang Li Feb 25 '11 at 19:35
    
@Qiang Li I find that setting AspectRatio->Full gives good behavior. That might be all it takes. Code in answer is edited to reflect this change. –  Daniel Lichtblau Feb 25 '11 at 21:01
1  
@Daniel: actually AspectRatio -> Automatic is the best i have seen so far. –  Qiang Li Feb 25 '11 at 21:23

Mathematica isn't the best software for this, although it will work out.

http://demonstrations.wolfram.com/DrawingATriangle/ has source code for a really nice triangle, and following that example you can add a bisecting line to the code.

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As already stated, Mathematica is not the best software for this. There are several better options that you can use, depending on your exact purpose. To generate such figures programatically, there are several languages especially adapted for such tasks. I would recommend to try eukleides or GCLC. If you have any experience with TeX/LaTeX, you may want to look at metapost or asymptote, or even a LaTeX package such as tkz-euklide.

If you on the other hand prefer to create you drawings in an interactive way, there are number of programs available. Search the web for "dynamic geometry software", you should get a number of hits. Of those I would most recommend geogebra.

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+1 All good recommendations –  Simon Feb 22 '11 at 22:03
    
thank you for the links. –  Qiang Li Feb 22 '11 at 23:27

Here you have your graph done with Geometry Expressions in two minutes. It has many nice features, including elemental geometry calculations and an interface for exporting formulas to Mathematica.

The formula in the drawing was calculated by the program.

enter image description here

Free to use, $79 - $99 to be able to save.

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@belisarius: it looks very nice. :) –  Qiang Li Feb 22 '11 at 23:25
    
Looks like a nice program - it's shame that there's no Linux version. –  Simon Feb 22 '11 at 23:28
    
@Simon It's nice but able to do only 2D geometry. I use it a lot as laziness usually forbid me to do trigonometric calcs. The Mma and MathML export is a big plus. –  belisarius Feb 22 '11 at 23:56
    
@belisarius: It seems to work perfectly under wine. But I think I prefer Geogebra. –  Simon Feb 23 '11 at 1:06
    
@Simon The nicest feature of G Exp is the ability to do symbolic calculations (as the CM segment in the figure). Does Geogebra do this? –  belisarius Feb 23 '11 at 2:12

Here's a very quick solution using GeoGebra to the problem you described.

It is the first time I've used GeoGebra and this took me about 20mins to make - so the program is quite well made and intuitive. What's more, it can export to dynamic, java based, webpages. Here's the one for the problem you specified: TriangleCircle.

Edit

For Mathematica demonstrations, there are lots of good examples at Plane Geometry. From this page, I found other software such as Cabri Geometry and The Geometer's Sketchpad.

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Nice links. But I disagree about the intuitiveness of those programs ... I find Mma much more intuitive :). Although WISIWIG is sometimes welcome! –  belisarius Feb 25 '11 at 17:35
    
@Belisarius; Maybe you're right - I spent way more than 20mins playing with Manipulate trying to get the same thing, but then the geometry functions aren't part of Mathematica. Although, you should check out the PlaneGeometry package that is part of the MathWorld packages. –  Simon Feb 25 '11 at 23:31

I thought that I should really attempt this problem in Mathematica (only once I finished did I see Daniel's solution). It took me about half an hour - which is longer than my GeoGebra solution, despite the fact that I'd never used GeoGebra before.

The code is not as fast as it could be. This is because I was too lazy to code up proper code for finding intersections of lines and circles, so I just used the slower but more general FindInstance.

A quite comprehensive plane geometry package can be found as part of Eric Weinstein's MathWorld packages. It includes all the intersection, bisection etc... code that you could possibly want, but it would take a little bit of time to learn it all.

angleBisector[A_,{B_,C_}]:=Module[{ba=Norm[B-A],ca=Norm[C-A],m},
  m=A+((B-A)/ba+(C-A)/ca)]

intersect[Line[{A_,B_}],Line[{C_,D_}]]:=Module[{s,t},
  A + s(B-A)/.First@FindInstance[A + s(B-A) == C + t(D-C), {s,t}]]
intersect[Line[{A_,B_}],Circle[p0:{x0_,y0_},r_]]:=Module[{s,x,y},
  A + s(B-A)/.FindInstance[A + s(B-A) == {x,y} 
  && Norm[p0-{x,y}] == r, {s,x,y}, Reals, 2]]

Manipulate[Module[{OO,circ,tri,angB,int,mid,FF},
  OO=(AA+BB)/2;
  circ=Circle[OO,Norm[AA-BB]/2];
  tri=Line[{AA,BB,CC,AA}];
  angB=angleBisector[AA,{BB,CC}];
  int=intersect[Line[{BB,CC}],Line[{AA,angB}]];
  mid=(AA+int)/2;
  FF=intersect[Line[{CC,mid}],Circle[OO,Norm[AA-BB]/2]];
  Graphics[{PointSize[Large],Point[{OO,int,mid}],Point[FF],tri,circ,
    Line[{AA,AA+3(angB-AA)}],Line[{CC,CC+3(mid-CC)}],
    Text["A",AA,{2,-2}],Text["B",BB,{-2,-2}],Text["C",CC,{2,2}],
    Text["O",OO,{0,-2}],Text["D",int,{-2,-1}],Text["M",mid,{-2,-1}]},
    PlotRange->{{-2,2},{-2,2}}]],
  {{AA,{-1,1}},Locator},
  {{BB,{1,1}},Locator},
  {{CC,{0,-1}},Locator}]

TriangleCircle

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