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I have some lines that their intersection describes a polygon, like this:

main polygon

I know the order of the lines, and their equations.

To find the internal angles, I found each lines orientations. But I've got confused as subtracting two lines orientation would give two different angles, even if I do it in the order of polygon's sides.

For example, in the following image, if I just subtract the orientation of the lines, I would get any of the following angles:

defect 1

What made me more confused, is when the polygon is not convex, I will have angles greater than 180, and using my approach I don't get the correct angle at all:

defect 2

And I found out that this way of approaching the problem is wrong.

So, What is the best way of finding the internal angles using just the lines? I know for a convex polygon, I may find vectors and then find the angle between them, but even for P6 in my example the vector approach fails.

Anyway, I prefer a method that won't include a conditional case for solving that concavity problem.

Thanks.

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Do you know direction of polygon traversal (e.g. clockwise)? –  MBo Aug 23 '12 at 3:50
    
And how your lines are described? –  MBo Aug 23 '12 at 5:26
    
Yes, I know the direction, I have the set of lines in clockwise order. The lines are described with two points. –  Kamyar Aug 23 '12 at 11:10

1 Answer 1

up vote 3 down vote accepted

With ordered lines it is possible to find points of intersection (polygon vertexes) in clockwise order. Then you can calculate internal angles:

Angle[i] =  Pi + ArcTan2(V[i] x V[i+1], V[i] * V[i+1]) 

(crossproduct and dotproduct of incoming and outgoing vectors for every vertex)

or

Angle[i] = Pi + ArcTan2( dx_in*dy_out-dx_out*dy_in, dx_in*dx_out+dy_in*dy_out2 )

Note: change plus sign after Pi to minus for anti-clockwise direction.

Edit:

Note that crossproduct and dotproduct are scalars, not vectors.

Example for your data:

dx1 = 5; dy1 = -15; dx2 = -15; dy2 = 5

Angle = Pi + ArcTan2(5*5-15*15, -5*15-5*15) = Pi - 2.11 radians ~ 59 degrees

Example for vectors:

(0,-1) (1,0) (L-curve)

Angle = Pi + ArcTan2(1, 0) =  270 degrees
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Thank you very much for your answer. There's something I don't get about the arguments of ArcTan2, if the second argument is dotproduct, how is it possible to take ArcTan2 with a number and a vector? If it's possible, please consider illustrating the calculations with these two vectors: V[i]=(5,-15) and V[i+1]=(-15,5). Thanks again. –  Kamyar Aug 23 '12 at 14:27
    
Read the wiki on the crossproduct. A cross product returns a vector, perpendicular to the plane the polygon lies in. Because |𝐕<sub>1</sub>×𝐕<sub>2</sub>| = |𝐕<sub>1</sub>||𝐕<sub>2</sub>|sin(𝛼)β€ˆand 𝐕<sub>1</sub>·π•<sub>2</sub> = |𝐕<sub>1</sub>||𝐕<sub>2</sub>|cos(𝛼), and since tan(𝛼) ≑ sin(𝛼)/cos(𝛼), taking the arctangent of |cross|/dot finds the angle (but notice the magnitude signs). Your method is correct, but your understanding of it is incomplete. –  Rody Oldenhuis Oct 24 '12 at 14:20
    
More importantly, your method only applies to the 2D case, and will require a coordinate transformation for polygons defined in 3D, which I guarantee will be messy. A more general approach is thus to use the magnitude of the cross product, instead of just the z-component of the resultant vector (which is what your method implicitly does). –  Rody Oldenhuis Oct 24 '12 at 14:23

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