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Given two points, A and B, defined by longitude and latitude I want to determine if another point C is ~between~ A and B. ~between~ is hard for me to define. I don't mean on the line - it almost certainly won't be.

Geometric diagram

In this diagram, point C is ~between~ A and B because it is between the normals of points A and B and the line between them (normals denoted by thin line). Point D is not ~between~ A and B but it is ~between~ B and F.

Another way of saying this is that I want to determine if the triangles ABC and ABD are obtuse or not.

Note that the points will be very close together - within 10s of metres normally.

I'm thinking that the law of haversines may help but I don't know what the inverse of haversine is.

Many thanks for all help.

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The thin lines are lines of longitude? –  Alok Singhal Jan 28 '10 at 4:16
    
No, the thin lines are the normals from the line AB. The situation represented by the diagram might be rotated by any amount. –  Sarge Jan 28 '10 at 4:22
1  
Your definition of the problem is incorrect. You do not need to know whether ABC is obtuse, but whether one of the angles CAB and CBA is obtuse. Imagine, if C is very close to AB, the triangle will be obtuse, but yet C is "inside" as you say. –  Pavel Radzivilovsky Jan 28 '10 at 4:34
    
The thin lines are great circles that are perpindicular to the thick line, which is also a great circle. –  mob Jan 28 '10 at 4:40

2 Answers 2

up vote 3 down vote accepted

First, start with translating your points to local tangent plane. We will use the fact that your triangles are much smaller than the earth's radius. (Tangent space is such that equal deltas in each of the two coordinates correspond to equal distances)

This is done by dividing longtitudes by sin(lat):

A_local_x = A_lat_rads;
A_local_y = A_lon_rads/sin(A_lat_rads);

Then,

Compute lengths:

double ABsquared = (A_local_x - B_local_x)*(A_local_x - B_local_x) + (A_local_y - B_local_y)*(A_local_y - B_local_y);
double BCsquared = ..., ACsquared.

Finally:

bool obtuse = (ABsquared+BCsquared < ACsquared) || (ABsquared+ACsquared < BCsquared); 

Obtuse means "it is not within the line", as you say. I am not checking whether triangle ABC is obtuse, but whether the angles at B and at A are obtuse. That's it.

note: I haven't tested this code. Please tell me how it works by plugging different points, if there's a bug I will fix it.

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2  
Nice. Your distance formula should add the squares, of course. Do tangent planes guarantee angles being preserved? Or only equal distance in one system == equal distance in the plane? –  Alok Singhal Jan 28 '10 at 8:46
    
Thanks, corrected the "-". Oops. Angles - yes. They are preserved. It's like mappping all points in the vicinity to a tangent plane. –  Pavel Radzivilovsky Jan 28 '10 at 13:22
    
Pavel: For the simple points I've thrown at my implementation of this answer it works very well. Thank you. –  Sarge Jan 28 '10 at 13:56

If your points are very close—10s of meters could easily qualify—you may be able to approximate it as a 2-d problem, and just calculate the angles CAB, θ and CBA, φ (using dot product). If both θ and φ are less than π/2, you C is "between".

cos(θ) = (AC · AB) / (|AC| |AB|)

If that approximation isn't good enough for you, you will need spherical trigonometry, which is also not too hard.

Note that if I understood your problem correctly, you need to check if the angles CAB and CBA are acute, not that the angle ACB is obtuse or acute.

share|improve this answer
    
Yes, Alok, you understand the problem correctly. –  Sarge Jan 28 '10 at 4:53
    
+1; however, this would require translating to 3d cartesian coordinates (important). see my answer on how to avoid it. –  Pavel Radzivilovsky Jan 28 '10 at 8:22

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