# Signed angle between two 3D vectors with same origin within the same plane

What I need is a signed angle of rotation between two vectors Va and Vb lying within the same 3D plane and having the same origin knowing that:

1. The plane contatining both vectors is an arbitrary and is not parallel to XY or any other of cardinal planes
2. Vn - is a plane normal
3. Both vectors along with the normal have the same origin O = { 0, 0, 0 }
4. Va - is a reference for measuring the left handed rotation at Vn

The angle should be measured in such a way so if the plane would be XY plane the Va would stand for X axis unit vector of it.

I guess I should perform a kind of coordinate space transformation by using the Va as the X-axis and the cross product of Vb and Vn as the Y-axis and then just using some 2d method like with atan2() or something. Any ideas? Formulas?

• And - Yes, I know about "acos( Va . Vb )" way but it due to the nature of cosine always gives the positive result. Commented Mar 4, 2011 at 1:12
• Could you explain Va? Is it parallel to Vn? Commented Mar 4, 2011 at 2:19
• Vn is the plane's normal vector here so it is perpendicular to both Va and Vb - and Vn is initially known Commented Mar 4, 2011 at 3:17
• The task in the question is simplified. In this particular case Vn is the only vector that was originally known along with the rotation matrix R. Va was computed then as a cross product of Vn and one of the cardinal base vectors: Va = normalize( Vn x {0,1,0} ); Commented Mar 4, 2011 at 3:49
• You don't need to divide by `(|Va||Vb|)` for the `sin` and `cos`. The way `atan2` works the denominators cancel out. Commented Apr 4, 2011 at 17:27

The solution I'm currently using seems to be missing here. Assuming that the plane normal is normalized (`|Vn| == 1`), the signed angle is simply:

For the right-handed rotation from Va to Vb:

`atan2((Va x Vb) . Vn, Va . Vb)`

For the left-handed rotation from Va to Vb:

`atan2((Vb x Va) . Vn, Va . Vb)`

which returns an angle in the range [-PI, +PI] (or whatever the available atan2 implementation returns).

`.` and `x` are the dot and cross product respectively.

No explicit branching and no division/vector length calculation is necessary.

Explanation for why this works: let alpha be the direct angle between the vectors (0° to 180°) and beta the angle we are looking for (0° to 360°) with `beta == alpha` or `beta == 360° - alpha`

``````Va . Vb == |Va| * |Vb| * cos(alpha)    (by definition)
== |Va| * |Vb| * cos(beta)     (cos(alpha) == cos(-alpha) == cos(360° - alpha)

Va x Vb == |Va| * |Vb| * sin(alpha) * n1
(by definition; n1 is a unit vector perpendicular to Va and Vb with
orientation matching the right-hand rule)

Therefore (again assuming Vn is normalized):
n1 . Vn == 1 when beta < 180
n1 . Vn == -1 when beta > 180

==>  (Va x Vb) . Vn == |Va| * |Vb| * sin(beta)
``````

Finally

``````tan(beta) = sin(beta) / cos(beta) == ((Va x Vb) . Vn) / (Va . Vb)
``````
• Works Perfectly! The most elegant solution by far. Thank you Adrian. Commented May 24, 2016 at 10:15
• This is by far the best answer here. I suspect this solution is also more numerically stable
– Eric
Commented May 3, 2017 at 15:05
• Am I wrong of atan2((Vb x Va) . Vn, Va . Vb) contains a typo? It should be atan2((Va x Vb) . Vn, Va . Vb) IMHO Commented Dec 31, 2017 at 14:32
• @MarcoM the original question asks for the left-handed rotation from Va to Vb. For the right-handed rotation Va x Vb is indeed correct. en.wikipedia.org/wiki/Right-hand_rule#Rotation Commented Dec 31, 2017 at 16:48
• @Alexko `sin(alpha) * n1 . Vn == sin(alpha) == sin(beta)` when `beta < 180` and `sin(alpha) * n1 . Vn == -sin(alpha) == sin(beta)` otherwise. Commented Mar 9, 2021 at 18:34

Use cross product of the two vectors to get the normal of the plane formed by the two vectors. Then check the dotproduct between that and the original plane normal to see if they are facing the same direction.

``````angle = acos(dotProduct(Va.normalize(), Vb.normalize()));
cross = crossProduct(Va, Vb);
if (dotProduct(Vn, cross) < 0) { // Or > 0
angle = -angle;
}
``````
• That was useful info that lead to the final solution - thanks! Commented Mar 5, 2011 at 17:39
• @Advanced Customer If this answer is correct please tick it? Otherwise what did you change to the above?
– user234736
Commented Jul 14, 2012 at 8:12
• Possible improvement: use `angle = angle*sgn(dotProduct(Vn,cross))` instead of the `if` statement. Not sure if it would be less/more efficient but it looks a little nicer. Commented Apr 2, 2015 at 1:33
• In my case the imprecision of this solution reached 30 degrees. Commented Apr 9, 2019 at 13:38
• This solution is very imprecise when vectors are nearly parallel or nearly opposite. This is because cosine function is almost flat at these points, so acos function has very little precision. Use the solution from the answer below instead. Commented Mar 5, 2021 at 3:29

You can do this in two steps:

1. Determine the angle between the two vectors

theta = acos(dot product of Va, Vb). Assuming Va, Vb are normalized. This will give the minimum angle between the two vectors

2. Determine the sign of the angle

Find vector V3 = cross product of Va, Vb. (the order is important)

If (dot product of V3, Vn) is negative, theta is negative. Otherwise, theta is positive.

You can get the angle up to sign using the dot product. To get the sign of the angle, take the sign of `Vn * (Va x Vb)`. In the special case of the XY plane, this reduces to just `Va_x*Vb_y - Va_y*Vb_x`.

• I guess this is for a 2d vector while there is a need to make it for 3d ones. The plane where both 3d vectros belong to is not parallel to XY so using just x and y components may not work in some cases. Commented Mar 4, 2011 at 3:19
• @Advanced Customer: You take the cross-product of Va and Vb dot-producted with Vn - the sign of that quantity is the sign of the angle. Commented Mar 4, 2011 at 4:12
• @StephenCanon: should `dot product` be `cross product`? Commented Aug 28, 2013 at 6:12
• @StephenCanon: I guess i misunderstood your meaning(`up to sign`). I mean the sign of the angle is depends on the `cross product`. Commented Aug 28, 2013 at 12:19
• @Jichao: There are two sentences. The first says you get the magnitude of the angle using the dot product. The second says that you get the sign of the angle using `Vn * (Va x Vb)`, which contains both a dot product and a cross product. The two sentences are independent. Commented Aug 28, 2013 at 12:27

Advanced Customer provided the following solution (originally an edit to the question):

``````SOLUTION:

sina = |Va x Vb| / ( |Va| * |Vb| )
cosa = (Va . Vb) / ( |Va| * |Vb| )

angle = atan2( sina, cosa )

sign = Vn . ( Va x Vb )
if(sign<0)
{
angle=-angle
}
``````

Cross one vector into the other and normalize to get the unit vector.

The sine of the angle between the two vectors equals the magnitude of the cross product divided by the magnitudes of the two vectors:

http://mathworld.wolfram.com/CrossProduct.html

• That way it works also with no sign becuase of magnitudes involved - angle is always positive as with acos(). It seems like the only proper and stable way to do so is to create a coordinate transformation matrix given Vn as Z-axis, Va as X-axis and their cross product as Y-axis so all of this would downgrade into a simple 2d case. Commented Mar 4, 2011 at 3:36
• Actually it works but I guess Parag described it a bit more clear - so see above :) Commented Mar 4, 2011 at 10:55
• The sign can be different because every 2D surface has two normal vectors, depending on which side you're interested in. Either one is equally valid. It's up to you to decide which one is appropriate for your problem. If I have a plane defined by two vectors for a wall in a room I can use the cross-product to get the normal vector that faces into the room or out of it, depending on my requirements and which vector comes first in the expression. Which one is correct? Both - it depends on context. Commented Mar 4, 2011 at 12:15
• could you please help me I am not good in math math.stackexchange.com/questions/2997836/… Commented Nov 14, 2018 at 7:29

For those using Python, the solution provided by Adrian Leonhard is now implemented in the scikit-spatial library (the latest version will be available soon). Look for the `angle_signed_3d` of the `Vector` class.

Here are two examples:

``````>>> import numpy as np
>>> from skspatial.objects import Vector
>>> np.degrees(Vector([1, 0, 0]).angle_signed_3d([0, -1, 0], direction_positive=[0, 0, 2]))
-90.0

>>> np.degrees(Vector([1, 0, 0]).angle_signed_3d([0, -1, 0], direction_positive=[0, 0, -5]))
90.0
``````

Let theta be the angle between the vectors. Let C = Va cross product Vb. Then

sin theta = length(C) / (length(Va) * length(Vb))

To determine if theta is positive or negative, remember that C is perpendicular to Va and Vb pointing in the direction determined by the right-hand rule. So in particular, C is parallel to Vn. In your case, if C points in the same direction as Vn, then theta is negative, since you want left-handed rotation. Probably the easiest computational way to quickly check if Vn and C point in the same direction is to just take their dot product; if it is positive they point in the same direction.

All this follows from elementary properties of the cross product.

• This is impractical in terms of the signedness as all magnitudes are a product of power of two - thus always positive. Commented Mar 5, 2011 at 17:40
• The sign comes from the dot product of C and Vn, which will be negative if they point in opposite directions. Commented Mar 5, 2011 at 19:35
• From the question "Vn - is a plane normal." Commented Jun 9, 2012 at 22:45
• could you please help me I am not good in math math.stackexchange.com/questions/2997836/… Commented Nov 14, 2018 at 7:30

Suppose Vx is the x-axis, given the normal Vn, you can get the y-axis by cross product, you can project the vector Vb to Vx and Vy (by the dot product you can get the length of the projection of Vb onto Vx and Vy), given the (x, y) coordinate on the plane, you can use atan2(y, x) to get the angle in the range [-pi, +pi]

This is the Matlab code to compute the signed angle between two vectors u,v either in 2D or in 3D. The code is self explanatory. The sign convention is such that a positive +90° is output between ix and iy ([1,0,0],[0,1,0]) or iy and iz ([0,1,0],[0,0,1])

``````function thetaDEG = angDist2Vecs(u,v)

if length(u)==3
%3D, can use cross to resolve sign
uMod = sqrt(sum(u.^2));
vMod = sqrt(sum(v.^2));
uvPr = sum(u.*v);
costheta = min(uvPr/uMod/vMod,1);

%resolve sign
cp=(cross(u,v));
idxM=find(abs(cp)==max(abs(cp)));
s=sign(cp(idxM(1)));
if s < 0