Take the 2-minute tour ×
Stack Overflow is a question and answer site for professional and enthusiast programmers. It's 100% free.

This is basic graphics geometry and/or trig, and I feel dumb for asking it, but I can't remember how this goes. So:

  1. I have a line defined by two points (x1, y1) and (x2, y2).
  2. I have a third point (xp, yp) which lies somewhere else.

I want to compute the point (x', y') that lies somewhere along the line in #1, such that, when joined with the point from #2, creates a new perpendicular line to the first line. enter image description here


share|improve this question

4 Answers 4

up vote 4 down vote accepted

You can find that point by considering first a generic point (x, y) along the line from (x1, y1) to (x2, y2):

x = x1 + t*(x2 - x1)
y = y1 + t*(y2 - y1)

and the computing the (squared) distance from this point from (xp, yp)

E = (x - xp)**2 + (y - yp)**2

that substituting the definition of x and y gives

E = (x1 + t*(x2 - x1) - xp)**2 +
    (y1 + t*(y2 - y1) - yp)**2

then to find the minimum of this distance varying t we derive E with respect to t

dE/dt = 2*(x1 + t*(x2 - x1) - xp)*(x2 - x1) +
        2*(y1 + t*(y2 - y1) - yp)*(y2 - y1)

that after some computation gives

dE/dt = 2*((x1 - xp)*(x2 - x1) + (y1 - yp)*(y2 - y1) +
           t*((x2 - x1)**2 + (y1 - y2)**2))

looking for when this derivative is zero we get an explicit equation for t

t = ((xp - x1)*(x2 - x1) + (yp - y1)*(y2 - y1)) /
    ((x2 - x1)**2 + (y2 - y1)**2)

so the final point can be computed using that value for t in the definition of (x, y).

Using vector notation this is exactly the same formula suggested by Gareth...

t = <p - p1, p2 - p1> / <p2 - p1, p2 - p1>

where the notation <a, b> represents the dot product operation ax*bx + ay*by.

Note also that the very same formula works in an n-dimensional space.

share|improve this answer
Thanks for this. Giving you the accepted answer as yours is the only one that takes what I know (cartesian coords) and gives me an actual formula to plug them into. (I like the vector idea but that raises more questions than answers given my geometry memory.) –  Ben Zotto Jul 8 '11 at 23:32
It's a heroic effort from @6502, but this answer shows why I have my rule of thumb about vectors! –  Gareth Rees Jul 8 '11 at 23:41
@gareth: When faced with a geometric problem I always think in vectors (that's why I upvoted your answer), but I know that most programmers don't feel comfortable with them. –  6502 Jul 9 '11 at 6:13

A useful rule of thumb in this kind of computational geometry is that you should work with vectors as long as you can, switching to Cartesian coordinates only as a last resort. So let's solve this using vector algebra. Suppose your line goes from p to p + r, and the other point is q.

Now, any point on the line, including the point you are trying to find (call it s), can be expressed as s = p + λ r for a scalar parameter λ.

Now the vector from q to s must be perpendicular to r. Therefore

(q − (p + λ r)) · r = 0

Where · is the dot product operator. Expand the product:

(qp) · r = λ (r · r)

And divide:

λ = (qp) · r / r · r

When you come to implement it, you need to check whether r · r = 0, to avoid division by zero.

share|improve this answer
Thanks for the enlightening thinking in vectors. –  Ben Zotto Jul 8 '11 at 23:32

The answer line is:

where a=(x1-x2)/(y2-y1)

How the result was obtained:

1) slope for the original line:   (y2-y1)/(x2-x1)

2) slope for the answer: -1/((y2-y1)/(x2-x1)) = (x1-x2)/(y2-y1)

3) Plug this into (xp,yp) we can have the result line.

Just calculate the answer from the lines after this (this is too long... I am hungry).

share|improve this answer
This doesn't work for y1=y2 (division by zero). Actually one should not use formulas based on "slope" when dealing with true bidimensional problems. The formula y=mx+q only works nicely when you're dealing with 1.5-dimensional problems (i.e. with graphs y=y(x)). –  6502 Jul 8 '11 at 21:55
@6502 Hmm. Thanks for saving me the bugs in the future because I would not likely to forget it again. –  Ziyao Wei Jul 8 '11 at 21:56

You can solve the slope of the line connecting (x1, y1) and (x2, y2). You then know the perpendicular line has a slope negative-inverse of that.

To find the y-intercept, use the slope to see how far the line travels in y from x=0 to x1.

b + (x1 - x0) * m = y1
b + (x1 -  0) * m = y1
b + (x1 * m)      = y1
b = y1 - x1 * m

You can then get the formulas for the line between your two points and the line from (xp, yp) with the above slope. For a given x, they have equal y's, so you can solve for that x, then plug that into either's formula for the y.

m = slope_from_1_to_2  = (y2 - y1) / (x2 - x1)
n = slopePerpendicular = (-1) / m

b = intercept_for_1_to_2 = y1 - x1 * m
c = intercept_for_p      = yp - xp * n

Thus the equations for the lines are of the form y = mx + b

Points 1 and 2:

y(x) = mx + b

Point p:

y(x) = nx + c

Set their y's equal to find x'

mx' + b = nx' + c
(m-n)x' = c - b
     x' = (c - b) / (m - n)

And thus use either formula to compute y'

y' = mx' + b

share|improve this answer
Thanks. In the equation y(x) = mx + y2 -- why do you use y2 to stand in for b? –  Ben Zotto Jul 8 '11 at 21:32
Good point, b should be the y-intercept, where the line hits the y-axis. y2 is not necessarily so, let me look over my math. –  Matt D Jul 8 '11 at 21:42
Using the formula y = m*x + q for a true bidimensional problem means look for troubles. You cannot handle vertical lines with this kind of approach; better to use parametric equations x = x(t), y = y(t) instead. –  6502 Jul 8 '11 at 21:57

Your Answer


By posting your answer, you agree to the privacy policy and terms of service.

Not the answer you're looking for? Browse other questions tagged or ask your own question.