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I have one line segment formed by two vectors, let's say v1 and v2, a vector v3 and an angle a. How do I write a method in Java (I'm also using Apache Commons Math to represent a vector) which gives me a vector v4, so that the line segments v1-v2 and v3-v4 are at angle a? There are infinite v4 elements, it would even be better if I could give a size to that method so that the line segment v3-v4 has that size. (all in 2d space, angle can be radians or degrees, doesn't matter)

Edit: as promised I have included an image of the problem I'm trying to solve. I have a line segment defined by 2 vectors (the line is a bit longer but that doesn't matter), an angle, and a third point. I need to draw the second line which intersects the first one at angle a. Since all lines in Javafx (which I'm using here) are drawn by defining two points, I needed to find the red point (or any of the possible ones). visual representation of the problem

Edit: Using Ali's answer I got the following method which does what I need:

public Pair<Vector2D, Vector2D> calculateFourthPoint(Vector2D v1, Vector2D v2, Vector2D v3, double angleInDegrees) {
    Vector2D r = v1.subtract(v2);
    double rx = r.getX();
    double ry = r.getY();
    double angle = toRadians(angleInDegrees);

    double a = pow(rx, 2) + pow(ry, 2);
    double b = 2 * sqrt(pow(rx, 2) + pow(ry, 2)) * cos(angle) * rx;
    double c = pow(rx, 2) * pow(cos(angle), 2) + pow(ry, 2) * pow(cos(angle), 2) - pow(ry, 2);
    double discriminant = sqrt(pow(b, 2) - (4 * a * c));

    double sx1 = (-b + discriminant) / (2 * a);
    double sx2 = (-b - discriminant) / (2 * a);

    double sy1 = sqrt(1 - pow(sx1, 2));
    double sy2 = sqrt(1 - pow(sx2, 2));

    Vector2D s1 = new Vector2D(sx1, sy1);
    Vector2D s2 = new Vector2D(sx2, sy2);

    Vector2D v4_1 = v3.subtract(s1);
    Vector2D v4_2 = v3.subtract(s2);

    return new Pair<Vector2D, Vector2D>(v4_1, v4_2);
share|improve this question
It seems quite easy, using dot product and arccos. –  Tom Aug 9 '12 at 19:48
Two dimensions or three? Or more? –  Beta Aug 9 '12 at 20:12
@Beta It has to be in 2D otherwise the problem is not well-definded. –  Ali Aug 9 '12 at 20:19
@Ali: Why is that? He recognized there could be multiple solutions, he just wants one of them. –  BlueRaja - Danny Pflughoeft Aug 9 '12 at 20:27
@BlueRaja-DannyPflughoeft In 3D the solution vectors are situated on a cone. In 2D the direction is well-defined. –  Ali Aug 9 '12 at 20:30

2 Answers 2

up vote 2 down vote accepted

I don't know Apache Commons Math so I am writing in pseudo code. Let vx and vy denote the x and y components of vector v, respectively.

Let r=v1-v2 and s=v3-v4. You have 2 unknowns (namely sx and sy; and v4=v3-s) so you need 2 equations. These should be:

dot_product(r,s)=length(r)*cos a // forces the desired angle

dot_product(s,s)=1 // just sets the length of s to 1

To spell it out, the above equations are:

(1)    rx*sx + ry*sy = sqrt(rx^2+ry^2)*cos a

(2)    sx^2 + sy^2 = 1

The first equation is linear in both sx and sy. Let's eliminate sy from the first equation (assuming that ry is not zero)

 sy = (1/ry)*(sqrt(rx^2+ry^2)*cos a - rx*sx)

and substitute this sy into the second equation. You get a quadratic equation in sy (I don't want to write it here because it is complicated) and that has 2 solutions. You get the corresponding sx by substituting the sy values into (assuming rx is not zero):

 sx = (1/rx)*(sqrt(rx^2+ry^2)*cos a - ry*sy).

Finally, v4=v3-s. You get 2 solutions for v4, one for each of the solutions to the quadratic equation. (Degenerate cases, such as r being a null vector, are ignored in my answer.)

share|improve this answer
-1: Given the probable level of the OP, this answer contains far too little background. And there are 4 solutions total - perhaps you meant that, but it's not clear if you did. –  Rody Oldenhuis Aug 10 '12 at 9:41
+1: Given because it is a nice solution and doesn't deserve a -1 in my opinion. Nevertheless, I agree with @RodyOldenhuis that the answer could be extended a little bit regarding the (assumed) knowledge level of the OP. –  brimborium Aug 10 '12 at 9:48
@RodyOldenhuis I greatly appreciate that you rewarded my efforts with a -1. –  Ali Aug 10 '12 at 10:06
I'm sorry, but effort by itself it no reason for reward. Quality of outcome is... –  Rody Oldenhuis Aug 10 '12 at 10:29
Ah, now that's certainly improved! Still: you get 4 solutions (see my image), because, you get 2 quadratic equations - one for sx, one for sy. –  Rody Oldenhuis Aug 10 '12 at 11:41

Shame we can't do LaTeX-style equations here (or can we? I dunno, never done it here...), but here goes:

v1-v2 · v3-v4 = |v1-v2| * |v3-v4| * cos(a)   (by definition)

define |v3-v4| to be a unit vector, so that

v1-v2 · v3-v4 = |v1-v2|*1*cos(a) = |v1-v2|*cos(a)

working the left hand side out gives

v1·v4 + v2·v4 = |v1-v2|*cos(a) - v1·v3 + v2·v3


(v1+v2)·v4 = |v1-v2|*cos(a) - (v1-v2)·v3 


|v3-v4| = (v3-v4)·(v3-v4) = 1    

So, there are 2 equations in 2 unknowns. Now, for brevity,

aa  = (v1+v2|x
bb  = (v1+v2|y
x1 = v4|x
x2 = v4|y
A  = |v1-v2|*cos(a) - (v1-v2)·v3 

where |x means x-component, etc. With this, trivial substitution gives us

( (A-aa*x1)/bb )^2 + (aa*x1)^2 = 1     (-> 2 solutions)
( (A-bb*x2)/aa )^2 + (bb*x2)^2 = 1     (-> another 2 solutions) 

The solutions are a bit too messy to write down here, but they are plain quadratic equations that can be easily solved.

You then have 4 unique vectors which lie on a unit circle around v3 (see picture). These 4 vectors result in only 2 distinct lines, but it is still a good idea to find all 4 vectors (as a self-check, and to improve robustness -- there can be some fringe cases where one of the vectors is such that something like catastrophic cancellation occurs).

Which line is best suited for you, depends of course on your use case.

Whatever the solution you pick, you should of course always verify whether

arccos(((v1-v2)·(v3-v4))/|v1-v2|) = a

as it should be.

situation sketch

share|improve this answer
You can "write" equations. There is no direct LaTeX plugin or something like that (unfortunately), but you can use the google charts API. See this question on meta.. But it's a pain in the biep. Maybe there are some online LaTeX->Google API url tools. –  brimborium Aug 10 '12 at 10:23
@brimborium Wow...one thing is sure: I'm never gonna use that :) Equations do seem to work on SE Mathematics or SE Physics -- do you know why SO doesn't use the same set of extensions? Use for it is rare (much less common anyway compared to SE Mathematics), but that should be no excuse... –  Rody Oldenhuis Aug 10 '12 at 10:28
-1 There are only 2 solutions. You made your answer more complicated than it has to be. The 2 spurious solutions are likely to be harmless because they probably give the correct line, just the v3-v4 vectors have the opposite signs. –  Ali Aug 10 '12 at 10:50
@Ali there are 4 solutions -- see image. I didn't make it too complicated; you made it too simple. –  Rody Oldenhuis Aug 10 '12 at 11:38
@Ali: just for your information; I can name a few examples where people have died, and/or great economic losses have been suffered, all because a programmer forgot or neglected a minus sign. Always think about all solutions. –  Rody Oldenhuis Aug 10 '12 at 11:45

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