Is there any numerically stable angle bisector algorithm?

The problem is the following:

  • Given three vectors (2 dimensional) A,B,C
  • Find the bisector of angle B (angle between AB and BC)

Actually I'm computing it in the following way:

  • Normalize AB
  • Normalize BC
  • Find (AB+CD)/2f (Mid Point)
  • The bisector is line passing between B and the Mid Point.

The problem with my approach is that when the angle is almost 180° (AB almost parallel to BC) the bisector is very inaccurate (of course because mid point is almost coincident with B). The current algorithm is so inaccurate that sometimes the resulting bisector is almost parallel to one of the other 2 segments.

And yes there are no "cast" problems, all computations are done in single precision floating point.

  • Hint: try to build the bisector with compass and straightedge. Pretend that you've lost your eyeglasses and cannot separate points which are very close to each other. – n. 'pronouns' m. Apr 16 '17 at 8:10
  • which is exactly what I'm already doing ^^. The algorithm I'm using is using 2 unitary circles, eventually I'm asking how to make it numerically stable, or to provide an alternative stable variant. – GameDeveloper Apr 16 '17 at 8:14
  • The paper/compass algorithm requires 2 vectors of same lenght. In the case I make them longer, the problem still persists when starting vectors are short. – GameDeveloper Apr 16 '17 at 8:18
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    "which is exactly what I'm already doing" You are (1) connecting two points, (2) find the midpoint of the resulting segment, and (3) draw a line through the midpoint and another point which may lie arbitrarily close to it. A bisector can be built in a much simpler way. Don't start with (1). – n. 'pronouns' m. Apr 16 '17 at 8:34
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    "the problem still persists when starting vectors are short" You can scale the construction before you start solving the problem as much as you like. Floating point numbers are well suited to that. It's subtraction of two very close numbers which is problematic. – n. 'pronouns' m. Apr 16 '17 at 8:40

You could use that the angle bisector remains the same if you rotate BA by +90° and BC by -90°.

So use the original formula if the situation is stable, that is, if the dot product of BA and BC is positive.

If it is negative, apply the rotations, for BA (x,y) -> (-y,x) and for BC (x,y) -> (y,-x), which also renders the dot product positive. Proceed as before with the new vectors.

If you try this out you will note that the jump in direction of the bisector now occurs for the angle -90° between the vectors. It is not possible to avoid this jump, as a continuous bisector will only be the same after two turns (fixing BA and moving C).


You can find the bisecting vector quite simply with:

∥BC∥ * BA + ∥BA∥ * BC

But that also won't be numerically stable with ABC collinear or nearly so. What might work better would be to find the angle between AB and BC, via the dot product.

cos θ = (BA · BC) / (∥BC∥ * ∥BA∥)

That will produce the correct angle even in the collinear case.

  • This is a very concise answer, but I'm not quite sure I understand. |BC| is the length of the vector, C-B, but what is AB? Is that the vector from A to B (B-A)? – Limited Atonement Jan 1 at 2:42
  • The original question was a bit off in its terminology; addressed in some of the other answers. A, B, C can be considered points, with AB denoting the vector from point A to point B. – TrentP Jan 2 at 4:36
  • Thanks for the response! I considered that, but it doesn't look correct. Given A(0.2,0), B(0,0), and C(0, 2), I would expect a bisecting vector to be along the line y=x, but using your formula, I get the point (-2,0.2). (∥BC∥=2, AB=(-0.2,0), ∥AB∥=0.2, BC=(0,2).) What am I missing? – Limited Atonement Jan 3 at 16:42
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    I see the problem, the first vector should be BA. The question is finding the angle bisector, so the two vectors must have a common mid-point, in this case B. – TrentP Jan 4 at 19:28
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    So if we follow the math, ∥BC∥ * BA = (0.4, 0) and ∥BA∥ * BC = (0, 0.4), and then their sum is (0.4, 0.4). The vector from B to (0.4, 0.4) will bisect the angle. And it does, as the angle is obviously 90° and the bisector is clearly 45°. – TrentP Jan 4 at 19:32

Definition: If A and B are points, vector(A,B) is the vector from point A to B.

Lets say that point O is the point of origin for our coordinate system.

The coordinates of point A are the same as of radius-vector(O,A).

Let point M be the middle point for the bisector,so you need to:

-normalize vector(B,A)

-normalize vector(B,C)

-vector(B,M) = vector(B,A)+vector(B,C) //vector from B to middle point

-(optionally) You can multiply vector(B,M) with a scalar to get a longer vector / increase distance between B and M

-vector(O,M) = vector(O,B) + vector(B,M)//radius-vector from O to M

Now middle point M has the same coordinates as radius-vector(O,M).


A simple enough way to do this follows in two formats (but the content is otherwise identical):


// Move A and C to the origin for easier rotation calculations
// The counter-clockwise angle between the positive X axis to A'
angle_a = arctan(Aprime.y, Aprimet.x);
// ditto for C'
angle_c = arctan(Cprime.y, Cprime.x);
// The counter-clockwise angle from A' to C'
angle_ac = angle_c - angle_a;
// The counter-clockwise angle from the positive X axis to M'
angle_m = angle_ac/2 + angle_a;
// Construct M' which, like A' and C', is relative to the origin.
Mprime=(cos(angle_m), sin(angle_m));
// Construct M which is relative to B rather than relative to the origin.

In English

  1. Move the vectors to the origin by
    • A'=A-B
    • B'=B
    • C'=C-B
  2. Get the angle from the positive X axis to A' as angle_a = arctan(A_y, A_x).
  3. Get the angle from the positive X axis to C' as angle_c = arctan(C_y, C_x).
  4. Get the counter-clockwise angle from A' to C' as angle_ac = angle_c - angle_a.
  5. Get the angle from the positive X axis to M' as angle_m = angle_ac/2 + angle_a.
  6. Construct M' from this angle as M' = (cos(angle_m), sin(angle_m)).
  7. Construct M as M = M' + B.

The vector BM bisects the angle ABC.

Since there is arbitrary division, there are no difficulties with this method. Here's a graphing calculator to encourage intuition with the solution: https://www.desmos.com/calculator/xwbno717da

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