Question

Hi, I have no clue about trigonometry, despite learning it in school way back when, and I figure this should be pretty straightforward, but trawling through tons of trig stuff on the web makes my head hurt :) So maybe someone could help me...

The title explains exactly what I want to do, I have a line: x1,y1 and x2,y2 and want a function to find x3,y3 to complete an isosceles triangle, given the altitude.

Just to be clear, the line x1,y2 -> x2,y2 will be the base, and it will not be aligned any axis (it will be at a random angle..)

Does anyone have a simple function for this??

Answer 1

construct a normal to the vector (x1,y1)->(x2,y2). place it at the midpoint ((x1+x2)/2,(y1+y2)/2) and go out a distance h.

the normal will look like (-(y2-y1),x2-x1). make this a unit vector (http://en.wikipedia.org/wiki/Unit_vector).

add h times this unit vector to the midpoint.

Answer 2

Al I can remember is that an isosceles triangle will have sides of equal length, and equal angles at the base. If you have the height, then you have the final coordinate because this will be the point of intersection, right?

Answer 3

The third point is on the perpendicular bisector of your base, and is altitude units away from the line.

1. Calculate the midpoint of the base by averaging the x and y coordinates.
2. Calculate the slope of your altitude: -dx/dy (perpendicular to dy/dx). You now have your line (point and slope).
   • y - my = -dx/dy * (x - mx)
3. Substitute your variables in the distance formula: d = sqrt(dx^2 + dy^2)
   1. d = sqrt((x - mx)^2 + (y - my)^2)
   2. d = sqrt((x - mx)^2 + (-dx/dy * (x - mx))^2)
   3. d^2 = (x - mx)^2 + (-dx/dy * (x - mx))^2
   4. d^2 - (x - mx)^2 = (-dx/dy * (x - mx))^2
   5. ±sqrt(d^2 - (x - mx)^2) = -dx/dy * (x - mx)
   6. ±sqrt(d^2 - (x - mx)^2) * dy/dx = x - mx
   7. ±sqrt(d^2 - (x - mx)^2) * dy/dx + mx = x
   8. x = ±sqrt(d^2 - (x - mx)^2) * dy/dx + mx
4. Calculate the other variable (y here) using your line equation (from #2).
5. You now have two points; pick whichever you want...

In pseudocode:

dx = x1 - x2
midpoint = ((x1 + x2) / 2, (y1 + y2) / 2)
slope = -dx / (y1 - y2)
x = sqrt(altitude*altitude - dx*dx) / slope + midpoint.x
y = slope * (x - midpoint.x) + midpoint.y

This is probably not the most optimal method. Not sure if it even works. xD