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my question is regarding working out the direction of the smallest angle between two vectors in 2D. I am making a game in C++ where one of the obstacles is a heat seeking missile launcher. I have it working by calculating the vector between the target and bullet, normalising the vector and then multiplying it by its speed. However, I am now coming back to this class to make it better. Instead of instantly locking onto the player I want it to only do so only when the bullets vector is within a certain angle (the angle between the bullets vector and the vector bulletloc->target). Otherwise I want it to slowly pan towards the target by a degrees thus giving the player enough space to avoid it. I have done all this (in a vb.net project so i could simplify the problem, work it out then re write in in C++). However the bullet always rotates clockwise towards the target even if the quickest route would be counter clockwise. So the problem is working out the direction to apply the rotation in so the smallest angle is covered. Here is my code so you can try and see what I am describing:

    Function Rotate(ByVal a As Double, ByVal tp As Point, ByVal cp As Point, ByVal cv As Point)
    'params a = angle, tp = target point, cp = current point, cv = current vector of bullet'
    Dim dir As RotDir 'direction to turn in'
    Dim tv As Point 'target vector cp->tp'
    Dim d As Point 'destination point (d) = cp + vector'
    Dim normal As Point
    Dim x1 As Double
    Dim y1 As Double
    Dim VeritcleResolution As Integer = 600

    tp.Y = VeritcleResolution - tp.Y 'modify y parts to exist in plane with origin (0,0) in bottom left'
    cp.Y = VeritcleResolution - cp.Y
    cv.Y = cv.Y * -1

    tv.X = tp.X - cp.X 'work out cp -> tp'
    tv.Y = tp.Y - cp.Y

    'calculate angle between vertor to target and vecrot currntly engaed on'
    Dim tempx As Double
    Dim tempy As Double

    tempx = cv.X * tv.X
    tempy = cv.Y * tv.Y

    Dim DotProduct As Double

    DotProduct = tempx + tempy 'dot product of cp-> d and cp -> tp'

    Dim magCV As Double 'magnitude of current vector'
    Dim magTV As Double 'magnitude of target vector'

    magCV = Math.Sqrt(Math.Pow(cv.X, 2) + Math.Pow(cv.Y, 2))
    magTV = Math.Sqrt(Math.Pow(tv.X, 2) + Math.Pow(tv.Y, 2))

    Dim VectorAngle As Double

    VectorAngle = Acos(DotProduct / (magCV * magTV))
    VectorAngle = VectorAngle * 180 / PI 'angle between cp->d and cp->tp'

    If VectorAngle < a Then 'if the angle is small enough translate directly towards target'
        cv = New Point(tp.X - cp.X, tp.Y - cp.Y)
        magCV = Math.Sqrt((cv.X ^ 2) + (cv.Y ^ 2))

        If magCV = 0 Then
            x1 = 0
            y1 = 0
            x1 = cv.X / magCV
            y1 = cv.Y / magCV
        End If

        normal = New Point(x1 * 35, y1 * 35)
        normal.Y = normal.Y * -1

        cv = normal
    ElseIf VectorAngle > a Then 'otherwise smootly translate towards the target'
        Dim x As Single
        d = New Point(cp.X + cv.X, cp.Y + cv.Y)

        a = (a * -1) * PI / 180 'THIS LINE CONTROL DIRECTION a = (a*-1) * PI / 180 would make the rotation counter clockwise'

        'rotate the point'
        d.X -= cp.X
        d.Y -= cp.Y

        d.X = (d.X * Cos(a)) - (d.Y * Sin(a))
        d.Y = (d.X * Sin(a)) + (d.Y * Cos(a))

        d.X += cp.X
        d.Y += cp.Y

        cv.X = d.X - cp.X
        cv.Y = d.Y - cp.Y

        cv.Y = cv.Y * -1
    End If

    Return cv

End Function

One idea I had was to work out the bearing of the two vectors and if the difference is greater than 180 degrees, rotate clockwise otherwise rotate counter clockwise, any ideas would be helpful. Thanks.

EDIT: I would like to add that this site is very helpful. I often use questions posed by others to solve my own problems and I want to take the chance to say thanks.

share|improve this question
Side note: Your code would be significantly easier to read and modify/maintain if you wrote a (or used somebody else's) vector structure to encapsulate this stuff a bit. – Cameron Jun 13 '12 at 20:32
yes i used points to represent vectors, I wrote it in vb to try and work the problem out at work. my main project has a vector class :) – David Kimbrey Jun 13 '12 at 20:59
up vote 9 down vote accepted

As you've written in your code, the angle between two (normalized) vectors is the inverse cosine of their dot product.

To get a signed angle, you can use a third vector representing the normal of the plane that the other two vectors lie on -- in your 2D case, this would be a 3D vector pointing straight "up", say (0, 0, 1).

Then, take the cross-product of the first vector (the one you want the angle to be relative to) with the second vector (note cross-product is not commutative). The sign of the angle should be the same as the sign of the dot product between the resulting vector and the plane normal.

In code (C#, sorry) -- note all vectors are assumed to be normalized:

public static double AngleTo(this Vector3 source, Vector3 dest)
    if (source == dest) {
        return 0;
    double dot; Vector3.Dot(ref source, ref dest, out dot);
    return Math.Acos(dot);

public static double SignedAngleTo(this Vector3 source, Vector3 dest, Vector3 planeNormal)
    var angle = source.AngleTo(dest);
    Vector3 cross; Vector3.Cross(ref source, ref dest, out cross);
    double dot; Vector3.Dot(ref cross, ref planeNormal, out dot);
    return dot < 0 ? -angle : angle;

This works by taking advantage of the fact that the cross product between two vectors yields a third vector which is perpendicular (normal) to the plane defined by the first two (so it's inherently a 3D operation). a x b = -(b x a), so the vector will always be perpendicular to the plane, but on a different side depending on the (signed) angle between a and b (there's something called the right-hand rule).

So the cross product gives us a signed vector perpendicular to the plane which changes direction when the angle between the vectors passes 180°. If we know in advance a vector perpendicular to the plane which is pointing straight up, then we can tell whether the cross product is in the same direction as that plane normal or not by checking the sign of their dot product.

share|improve this answer
OK to make sure I am right in understanding what you have said consider the following two vectors V = -2x, 4y, 0z and U = 2x, y4, 0z. To work out the sign of the angle between V and U (where V is the starting point and U is the ending point meaning the answer ought to be clockwise) I should take the cross product of the two vectors by determining the matrix {(x, y, z), (-2, 4, 0), (4, 2, 0)} in which the x and y components become zero, and the z component = (-2 * 2)-(4*4) = -20 then get the dot product of this vector (0x, 0y, -20z) and the unit vector (0,0,1) = -20. – David Kimbrey Jun 13 '12 at 21:34
Since the sign is negative the sign of the angle should also be negative? If so I must have done something wrong (constructed the matrix the wrong way around?) – David Kimbrey Jun 13 '12 at 21:34
@David: You can use this cross-product calculator to help check your math. You did your example correctly; the dot product is negative, and the final angle should be negative too. The reason it's not what you expected is because your assumption that a clockwise angle is positive is wrong (or rather, goes against convention). Imagine the unit circle -- the point corresponding to angle 0 is on the far right of the circle, and as the angle increases the point moves counter-clockwise. – Cameron Jun 14 '12 at 0:25
@David: If you want a clockwise-increasing angle convention, simply negate the result, or use the opposite plane normal of (0, 0, -1). This might confuse other people who read your code, though (I'd add a comment if I did that myself). Does that help? :-) – Cameron Jun 14 '12 at 0:27
Hi, sorry I haven't got back. Had a bit of upheaval in the last couple of days. I sorted the problem out, it works perfectly now. Might just add some code to modify how much I rotate by based on how large the angle between the two vectors is such as the angle I rotate by being 30% of the angle between so if the target is in the opposite direction it rotates quickly then slowly locks onto them if you know what I mean. Thanks for the informative response and once again thanks for all that help make this site such a good source of knowledge. – David Kimbrey Jun 17 '12 at 12:29

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