# Detecting if a triangle flips when changing a point

I need to change a triangle by replacing one of its points. However, I need to detect if doing so would cause the triangle to flip.

For example, the triangle defined by the points:

``````[(1.0,1.0), (2.0,3.0), (3.0,1.0)]
``````

would look like this:

If I change the third point from `(3.0,1.0)` to `(1.0,2.0)`, it flips, as shown here:

I've written a function that detects if a triangle is flipped by calculating the equation for the stationary points and detecting a sign difference in the y-intercept:

``````def would_flip(stationary, orig_third_point, candidate_third_point):

#m = (y2-y1)/(x2-x1)
slope = (stationary[1][3] - stationary[0][4]) / (stationary[1][0] - stationary[0][0])

#y = mx + b
#b = y-mx
yint = stationary[0][5] - slope * stationary[0][0]

orig_atline = slope * orig_third_point[0] + yint
candidate_atline = slope * candidate_third_point[0] + yint

if orig_atline > orig_third_point[1] and not(candidate_atline > candidate_third_point[1]) or \
orig_atline < orig_third_point[1] and not(candidate_atline < candidate_third_point[1]):
return True

return False
``````

This works nicely for most cases:

``````>>> would_flip([(1.0,1.0), (2.0,3.0)], (3.0,1.0), (1.0,2.0))
True
>>> would_flip([(1.0,1.0), (2.0,3.0)], (3.0,1.0), (4.0,2.0))
False
``````

The problem I have is that if the stationary points are vertical, the slope is infinite:

``````>>> would_flip([(1.0,1.0), (1.0,3.0)], (3.0,1.0), (4.0,2.0))
ZeroDivisionError: float division by zero
``````

Is there a better/faster way to detect a triangle flip that is robust to the stationary points being a vertical line? The fact that it's written in python is not important. I will accept an answer that is just a formula or well-described technique.

EDIT: More information on what it means for a triangle to "flip"

Consider the four triangles below:

The top-left is the original triangle. The red line (same in all four) are the two stationary points. The rest of the three triangles replace the third point. The top-right and bottom-left triangles are not flipped, while the triangle in the bottom-right is flipped. Essentially, the triangle is "flipped" if the third point ends up on the opposite side of the imaginary line formed by the two stationary points.

UPDATE2: Working function using cross product:

``````def would_flip2(stationary, orig_third_point, candidate_third_point):
vec1 = numpy.array([stationary[1][0] - stationary[0][0], stationary[1][1] - stationary[0][1], 0])
vec2_orig = numpy.array([orig_third_point[0] - stationary[0][0], orig_third_point[1] - stationary[0][1], 0])
vec2_candidate = numpy.array([candidate_third_point[0] - stationary[0][0], candidate_third_point[1] - stationary[0][1], 0])
orig_direction = numpy.cross(vec1, vec2_orig)[2]
candidate_direction = numpy.cross(vec1, vec2_candidate)[2]
if orig_direction > 0 and not(candidate_direction > 0) or \
orig_direction < 0 and not(candidate_direction < 0):
return True
return False
``````
-
I don't think you've stated clearly what you mean by "flip": it seems that you have some rule that makes one point in each triangle special, but you haven't stated explicitly what that rule is – Croad Langshan Sep 9 '11 at 18:02
Ah, I get it now that I look again: each point's position in the triple defines that point's identity. "flip" is defined such that a ("stretchy"!) physical triangle defined by those points would have to be rotated in 3D space about an axis in the 2D plane that contains your triangle, in order to go from the first triangle to the second. Maybe no clearer than your original explanation! – Croad Langshan Sep 9 '11 at 18:10
I updated with some more information about what it means to flip a triangle. Does that make it more clear? – jterrace Sep 9 '11 at 18:12
Another way of phrasing this question is to imagine an ant walking in a loop from point 1 to point 2 to point 3 back to point 1. The question is then; is the ant turning clockwise or counter-clockwise? A closely related term for this is winding number. which is -1 for the first triangle, and 1 for the second – SingleNegationElimination Sep 9 '11 at 18:27

Compute the cross-product of two vectors generated from your three points. If the direction of the cross product changes sign, the triangle has flipped.

For example:

Given `[(1.0,1.0), (2.0,3.0), (3.0,1.0)]`: Form two (3D) vectors

`(2-1,3-1,0) = (1,2,0)` and `(3-1,1-1,0) = (2,0,0)`

Take their cross product:

``````(1,2,0) x (2,0,0) = (0,0,0-4) = (0,0,-4)
``````

Or, using numpy:

``````import numpy as  np
np.cross([1,2,0],[2,0,0])
# array([ 0,  0, -4])
``````

While when given `[(1.0,1.0), (2.0,3.0), (1.0,2.0)]`: We form the two (3D) vectors:

`(2-1,3-1,0) = (1,2,0)` and `(1-1,2-1,0) = (0,1,0)`

And again take their cross product:

``````np.cross([1,2,0],[0,1,0])
# array([0, 0, 1])
``````

Since the vector (0,0,-4) points "down" and the vector (0,0,1) points "up", the triangle has flipped.

You don't really need numpy for this. If you work out the math on paper, it turns out that if the points are given by (x1,y1), (x2,y2) and (x3,y3), then the key number in the cross product is given by

``````(y2-y1)*(x2-x1) - (y3-y1)*(x2-x1)
``````

You just have to compute that value and watch for changes in its sign. (The three points are co-linear if and only if the expression above equals 0.)

-
Shouldn't that (2,1,0) be (2,0,0)? – jterrace Sep 9 '11 at 18:30
This works. Updated question with working funciton. Thanks! – jterrace Sep 9 '11 at 18:35
@jterrace: Oops, you are right. Correcting... – unutbu Sep 9 '11 at 18:36

You could start your `would_flip` function with an `is_straight_line` function, and the rest of the code only executes if it isn't a straight line.

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I could detect when the denominator is 0 or when the resulting slope is infinite and then calculate the equation differently based on the y value for input, but I was hoping for a more elegant solution. – jterrace Sep 9 '11 at 18:10