# Detecting if angle is more than 180 degrees

I'm working on a problem that the professor assigned, and I'm having a problem looking for a way to detect if the angle between 3 points is more than 180 degrees, e.g:

I want to detect if alpha is more than 180 degrees. Anyways, my professor has a code that solves the problem, but he has a function called zcross, but I don't exactly know how it works. Could anyone tell me? His code is here:

``````#include <fstream.h>
#include <math.h>
#include <stdlib.h>

struct point {
double  x;
double  y;
double  angle;
};

struct vector {
double  i;
double  j;
};

point   P[10000];
int     hull[10000];

int
zcross (vector * u, vector * v)
{
double  p = u->i * v->j - v->i * u->j;
if (p > 0)
return 1;
if (p < 0)
return -1;
return 0;
}

int
cmpP (const void *a, const void *b)
{
if (((point *) a)->angle < ((point *) b)->angle)
return -1;
if (((point *) a)->angle > ((point *) b)->angle)
return 1;
return 0;
}

void
main ()
{
int     N, i, hullstart, hullend, a, b;
double  midx, midy, length;
vector  v1, v2;

ifstream fin ("fc.in");
fin >> N;
midx = 0, midy = 0;
for (i = 0; i < N; i++) {
fin >> P[i].x >> P[i].y;
midx += P[i].x;
midy += P[i].y;
}
fin.close ();
midx = (double) midx / N;
midy = (double) midy / N;
for (i = 0; i < N; i++)
P[i].angle = atan2 (P[i].y - midy, P[i].x - midx);
qsort (P, N, sizeof (P[0]), cmpP);

hull[0] = 0;
hull[1] = 1;
hullend = 2;
for (i = 2; i < N - 1; i++) {
while (hullend > 1) {
v1.i = P[hull[hullend - 2]].x - P[hull[hullend - 1]].x;
v1.j = P[hull[hullend - 2]].y - P[hull[hullend - 1]].y;
v2.i = P[i].x - P[hull[hullend - 1]].x;
v2.j = P[i].y - P[hull[hullend - 1]].y;
if (zcross (&v1, &v2) < 0)
break;
hullend--;
}
hull[hullend] = i;
hullend++;
}

while (hullend > 1) {
v1.i = P[hull[hullend - 2]].x - P[hull[hullend - 1]].x;
v1.j = P[hull[hullend - 2]].y - P[hull[hullend - 1]].y;
v2.i = P[i].x - P[hull[hullend - 1]].x;
v2.j = P[i].y - P[hull[hullend - 1]].y;
if (zcross (&v1, &v2) < 0)
break;
hullend--;
}
hull[hullend] = i;

hullstart = 0;
while (true) {
v1.i = P[hull[hullend - 1]].x - P[hull[hullend]].x;
v1.j = P[hull[hullend - 1]].y - P[hull[hullend]].y;
v2.i = P[hull[hullstart]].x - P[hull[hullend]].x;
v2.j = P[hull[hullstart]].y - P[hull[hullend]].y;
if (hullend - hullstart > 1 && zcross (&v1, &v2) >= 0) {
hullend--;
continue;
}
v1.i = P[hull[hullend]].x - P[hull[hullstart]].x;
v1.j = P[hull[hullend]].y - P[hull[hullstart]].y;
v2.i = P[hull[hullstart + 1]].x - P[hull[hullstart]].x;
v2.j = P[hull[hullstart + 1]].y - P[hull[hullstart]].y;
if (hullend - hullstart > 1 && zcross (&v1, &v2) >= 0) {
hullstart++;
continue;
}
break;
}

length = 0;
for (i = hullstart; i <= hullend; i++) {
a = hull[i];
if (i == hullend)
b = hull[hullstart];
else
b = hull[i + 1];
length += sqrt ((P[a].x - P[b].x) * (P[a].x - P[b].x) + (P[a].y - P[b].y) * (P[a].y - P[b].y));
}

ofstream fout ("fc.out");
fout.setf (ios: :fixed);
fout.precision (2);
fout << length << '\n';
fout.close ();
}
``````
-

First, we know that if `sin(a)` is negative, then the angle is more than 180 degrees.

How do we find the sign of `sin(a)`? Here is where cross product comes into play.

First, let's define two vectors:

``````v1 = p1-p2
v2 = p3-p2
``````

This means that the two vectors start at `p2` and one points to `p1` and the other points to `p3`.

Cross product is defined as:

``````(x1, y1, z1) x (x2, y2, z2) = (y1z2-y2z1, z1x2-z2x1, x1y2-x2y1)
``````

Since your vectors are in 2d, then `z1` and `z2` are 0 and hence:

``````(x1, y1, 0) x (x2, y2, 0) = (0, 0, x1y2-x2y1)
``````

That is why they call it zcross because only the z element of the product has a value other than 0.

Now, on the other hand, we know that:

``````||v1 x v2|| = ||v1|| * ||v2|| * abs(sin(a))
``````

where `||v||` is the norm (size) of vector `v`. Also, we know that if the angle `a` is less than 180, then `v1 x v2` will point upwards (right hand rule), while if it is larger than 180 it will point down. So in your special case:

``````(v1 x v2).z = ||v1|| * ||v2|| * sin(a)
``````

Simply put, if the z value of `v1 x v2` is positive, then `a` is smaller than 180. If it is negative, then it's bigger (The z value was `x1y2-x2y1`). If the cross product is 0, then the two vectors are parallel and the angle is either 0 or 180, depending on whether the two vectors have respectively same or opposite direction.

-
Thanks. nice and informative answer. –  Richie Li Oct 16 '11 at 17:05
In 2D, what you are really doing is computing the "outer product", which is a more general concept than cross product and works in any number of dimensions. They don't teach it in introductory linear algebra classes, which is a shame. (The formula is mostly the same, just with no mention of "z" coordinates, so it's simpler.) –  Dietrich Epp Nov 3 '11 at 4:07
Nice answer. This was exactly what I was looking for. –  Mark Simpson May 31 '12 at 18:26

zcross is using the sign of the vector cross product (plus or minus in the z direction) to determine if the angle is more or less than 180 degrees, as you've put it.

-
Hmm, I'll look into that now –  Richie Li Oct 16 '11 at 17:05

In 3D, find the cross product of the vectors, find the minimum length for the cross product which is basically just finding the smallest number of x, y and z.

If the smallest value is smaller than 0, the angle of the vectors is negative.

So in code:

``````float Vector3::Angle(const Vector3 &v) const
{
float a = SquareLength();
float b = v.SquareLength();
if (a > 0.0f && b > 0.0f)
{
float sign = (CrossProduct(v)).MinLength();
if (sign < 0.0f)
return -acos(DotProduct(v) / sqrtf(a * b));
else
return acos(DotProduct(v) / sqrtf(a * b));
}
return 0.0f;
}
``````
-
I think its important to mention, that the function returns a angle between [-180°;180°] - not a angle between [0;360°] - works perfect! –  Vertexwahn Apr 26 '13 at 6:57

Another way to do it would be as follows:

calculate vector v1=p2-p1, v2 = p2 -p3. Then, use the cross-product formula : u.v = ||u|| ||v|| cos(theta)

-
How do you handle angles > 180°? –  Vertexwahn Apr 26 '13 at 6:27
The sign tells you if it is more than 180°, doesn't it? –  Guru Devanla Apr 30 '13 at 17:46