# 2D Mathematics Geographical Directions

I am trying to check the location of a point(px, py) on 2D graph in relation to a line segment (lx1, ly1) (lx2, ly2), using logic of North South East West directions. The logic I have implemented is to draw a perpendicular on the line segment from the point.

if perpendicular is on line that means its south.

If point on right side means its East.

If point on left side means West.

If perpendicular is away from line in forward direction will mean North.

If perpendicular is away from line in backward direction will mean South.

My problem is that this logic looks good on paper, but its getting really hard to decide whether its a NW, NE, SW or SE case. Can anyone suggest me how to compute this logic?? I am using C++, but algorithm in any language will be a great help.

I am using end point of line segment to calculate North South East West relation.

Cheers

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• `delta_x = x2 - x1`
• `delta_y = y2 - y1`
• `distance = sqrt (delta_x^2 + delta_y^2)`
• `tan (theta) = delta_y / delta_x`
• `theta = arctan (delta_y / delta_x)` ;; but don't divide by zero!
• multiply `theta` by `180/PI` to get degrees

The degrees are counter-clockwise from the positive side of the x-axis. Eventually you'll need to do a small amount of algebra to reorient the degrees so that 0 is up (instead of to the right) and run clockwise. But before that:

A problem is that `arctan (1 / -1)` is the same as `arctan (-1 / 1)`. I.e., you'll get `-PI/4` radians or -45 degrees, for both upper left (needs 180 degree offset) and lower right (ok as is). You'll have to do tests on the sign of `delta_y` vs. `delta_x` to see if the result of `arctan` needs to be adjusted.

Before you code your solution, be sure to code tests as well to make sure the functions you are calling produce expected values.

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Use the `atan2()` function call available in most math libraries to avoid the division by zero problem. –  ndim Nov 29 '09 at 18:38
Oh, and given an angle in radians (like arctan() does), you get degrees by multiplying with `180/PI`, not by multiplying with `2*PI`. –  ndim Nov 29 '09 at 19:13
Hey guys, thanx for the help. I will try these suggestions and update you. –  Zinx Nov 30 '09 at 0:09
Thanks, ndim, I made the 180/PI vs. 2*PI correction. –  gknauth Dec 3 '09 at 15:05

I sympathise with `ndim`. Calculating direction from one point to another is easy. I don't understand which context would require you to want direction from a line. Is this a mapping application? Is there a road, and about halfway along a road segment you've got some point off to the side?

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Hi, yeah its for a road kind of game. Can you please tell me how to calculate direction from a point to another point??? –  Zinx Nov 29 '09 at 1:57

The semantics of what "north" or "NE" or "east" of a line segment actually means is unclear.

Directions like "north" or "east" or "NE" are usually used to describe the location of one point relative to another (base) point. What is the point on the line segment you are using as that base point?

EDIT: Now that you say you want to use the end point `(x2,y2)` as the center point for the compass, a point `(x,y)` will be located relative to the compass by examining the delta vector `(x-x2,y-y2)`.

The easy to reason about method uses `atan2()` on the delta vector, and considers the angle returned by `atan2()`.

However, it might also be a good idea to just compare the arguments to `atan2()` to each other and determine the resulting angle ranges from that. This basically avoids calling `atan2()` at runtime at the cost of you needing to do some calculations at (or before) compile time.

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Hi, I am using end point of line segment for that relation. –  Zinx Nov 29 '09 at 1:10