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Say I have a path with 150 nodes / verticies. How could I simplify if so that for example a straight line with 3 verticies, would remove the middle one since it does nothing to add to the path. Also how could I avoid destroying sharp corners? And how could I remove tiny variations and have smooth curves remaining.

Thanks

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Least Squares, i guess. Remove those nodes with least contribution to overall "shape". You need to be more specific what "path" you have and why it would be OK to remove nodes. Are you talking about a geometric path? –  zerm Jun 13 '10 at 14:55
    
Yes, a polygon, –  Milo Jun 13 '10 at 14:56
    
possible duplicate of Shortest distance between a point and a line segment –  Pratik Sep 26 '11 at 10:07

5 Answers 5

up vote 2 down vote accepted

The simpler approach. Take 3 vertecies a, b and c and calcule: The angle/inclination of between vertecies.

std::vector<VERTEX> path;
//fill path
std::vector<int> removeList;
//Assure that the value is in the same unit as the return of angleOf function.
double maxTinyVariation = SOMETHING; 

for (int i = 0; i < quantity-2; ++i) {
  double a = path[i], b = path[i + 1] , c = path[i + 2]
  double abAngle = angleOf(a, b);
  double bcAngle = angleOf(b, c);

  if (abs(ab - bc) <= maxTinyVariation) {
     //a, b and c are colinear
     //remove b later
     removeList.push_back(i+1);
  }
}
//Remove vertecies from path using removeList.
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Shouldn't you take into account situations like when abAngle = 359 and bcAngle = 1? (in degrees, that is). They are close but on opposite sides of zero. –  Noio Oct 10 '11 at 14:57

@max: this is very nice! Thanks for the idea!!! Works great! One improvement: the crossproduct can be negative, too! So it is better to replace this line:

float crossproduct = Y_ab * X_ac - X_ab * Y_ac

with this one:

float crossproduct = Math.Abs(Y_ab * X_ac - X_ab * Y_ac)
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Let A, B, C be some points.

The easiest way to check they lie on the same line is to count crossproduct of vectors B-A, C-A.

If it equals zero, they lie on the same line:

// X_ab, Y_ab - coordinates of vector B-A.
float X_ab = B.x - A.x
float Y_ab = B.y - A.y
// X_ac, Y_ac - coordinates of vector C-A.
float X_ac = C.x - A.x
float Y_ac = C.y - A.y
float crossproduct = Y_ab * X_ac - X_ab * Y_ac
if (crossproduct < EPS) // if crossprudct == 0
{
   // on the same line.
} else {
   // not on the same line.
}

After you know that A, B, C lie on the same line it is easy to know whether B lies between A and C throw innerproduct of vectors B-A and C-A. If B lies between A and C, then (B-A) has the same direction as (C-A), and innerproduct > 0, otherwise < 0:

float innerproduct = X_ab * X_ac + Y_ab * Y_ac;
if (innerproduct > 0) {
  // B is between A and C.
} else {
  // B is not between A and C.
}
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For every 3 vertices, pick the middle one and calculate its distance to the line segment between the other two. If the distance is less than the tolerance you're willing to accept, remove it.

If the middle vertex is very close to one of the endpoints, you should tighten the tolerance to avoid removing rounded corners for instance.

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How could I simplify if so that for example a straight line with 3 verticies, would remove the middle one since it does nothing to add to the path.

For each set of three consecutive vertices, test whether they are all in a straight line. If they are, remove the middle vertex.

Also how could I avoid destroying sharp corners?

If you're only removing vertices that fall on a straight line between two others, then you won't have a problem with this.

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You may also want to make sure that the "middle" (second) vertex of the three is actually between the two "endpoints". It may never happen if you can guarantee you're starting with a valid polygon, but if it ever does, removing the second vertex will usually give you a different-looking shape than you started with. –  cHao Jun 13 '10 at 15:14

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