# Calculate Angle from Two Points and a Direction Vector

Facebook and Stack Exchange are now working together to support the Facebook developer community. Facebook engineers participate here along with the best Facebook developers in the world. If you have a technical question about Facebook, this is the best place to ask.

I have two vectors in a game. One vector is the player, one vector is an object. I also have a vector that specifies the direction the player if facing. The direction vector has no z part. It is a point that has a magnitude of 1 placed somewhere around the origin.

I want to calculate the angle between the direction the soldier is currently facing and the object, so I can correctly pan some audio (stereo only).

The diagram below describes my problem. I want to calculate the angle between the two dashed lines. One dashed line connects the player and the object, and the other is a line representing the direction the player is facing from the point the player is at.

At the moment, I am doing this (assume player, object and direction are all vectors with 3 points, x, y and z):

``````Vector3d v1 = direction;
Vector3d v2 = object - player;
v1.normalise();
v2.normalise();
float angle = acos(dotProduct(v1, v2));
``````

But it seems to give me incorrect results. Any advice?

Test of code:

``````Vector3d soldier = Vector3d(1.f, 1.f, 0.f);
Vector3d object = Vector3d(1.f, -1.f, 0.f);
Vector3d dir = Vector3d(1.f, 0.f, 0.f);

Vector3d v1 = dir;
Vector3d v2 = object - soldier;

long steps = 360;
for (long step = 0; step < steps; step++) {
float rad = (float)step * (M_PI / 180.f);
v1.normalise();

float dx = dotProduct(v2, v1);
float dy = dotProduct(v2, soldier);
float vangle = atan2(dx, dy);
}
``````
-
Your math is sound, clarify what you mean by 'incorrect results'. Is it a small offset from what you expect? Give us the numbers you were testing with. – Ron Warholic Feb 2 '11 at 21:23
@Ron Warholic, oggmonster: The math is not correct. One problem is that `acos` will always return angles in the range [0,pi], when you want an angle in the range [0,2pi]. You cannot take the dot product and solely compute the angle from that, because you lose information. What you need is the `atan2` function, which has a range of [-pi,pi], which is close enough to [0,2pi] -- a simple function can fix this if absolutely necessary, but negative angles are not really a huge problem in most cases. – drvitek Feb 2 '11 at 21:27
what should I use as the second argument to atan2? – oggmonster Feb 2 '11 at 21:32
i seem to get jumps in the angle from 0 straight to pi – oggmonster Feb 2 '11 at 21:33
In that case you need to get the signed angle as mentioned by drvitek. The dot product method produces a positive shortest angle and does not tell you which direction the rotation is in. – Ron Warholic Feb 2 '11 at 21:37
show 1 more comment

You shoud always use `atan2` when computing angular deltas, and then normalize. The reason is that for example `acos` is a function with domain -1...1; even if you normalize if the input absolute value because of approximations gets bigger than 1 the function will fail even if it's clear that in such a case you would have liked an angle of 0 or PI instead. Also `acos` cannot measure the full range -PI..PI and you'd need to use explicitly sign tests to find the correct quadrant.

Instead `atan2` only singularity is at `(0, 0)` (where of course it doesn't make sense to compute an angle) and its codomain is the full circle -PI...PI.

Here is an example in C++

``````// Absolute angle 1
double a1 = atan2(object.y - player.y, object.x - player.x);

// Absolute angle 2
double a2 = atan2(direction.y, direction.x);

// Relative angle
double rel_angle = a1 - a2;

// Normalize to -PI .. +PI
rel_angle -= floor((rel_angle + PI)/(2*PI)) * (2*PI) - PI;
``````

In the case of a general 3d orientation you need two orthogonal directions, e.g. the vector of where the nose is pointing to and the vector to where your right ear is. In that case the formulas are just slightly more complex, but simpler if you have the dot product handy:

``````// I'm assuming that '*' is defined as the dot product
// between two vectors: x1*x2 + y1*y2 + z1*z2
double dx = (object - player) * nose_direction;
double dy = (object - player) * right_ear_direction;
double angle = atan2(dx, dy); // Already in -PI ... PI range
``````

-
 This will work for his situation; however if the direction vector were not constrained to the XY plane it would fail. Also recommending always using `atan2` is a bit strong I think; the standard `acos` method is sufficient for most cases and is not restricted to a 2D mapping. – Ron Warholic Feb 2 '11 at 21:46 @Ron Warholic: For 3d you need two reference directions, otherwise you can just compute an angle without sign that is useless for stereo computation. I'll extend the answer. – 6502 Feb 2 '11 at 21:57 Hmm I just tested it with the code seen below my answer. but vangle stays in the range -pi to -2.35 and 2.35 to pi. what's going wrong here? I should see the full range of pi to -pi here right? – oggmonster Feb 2 '11 at 22:59

In 3D space, you also need to compute the axis:

``````Vector3d axis = normalise(crossProduct(normalise(v1), normalise(v2)));
``````
-