# Shortest path on a sphere direction descision

I'm trying to write an algorithm that does the following.

Given a current position (in Azimuth and Inclination) and a target position (again in A, I) in what direction should I travel to travel over the shortest path. The return value could be something like a vector A = -1, I = +0.5, that I can then scale for step size/time.

The shortest path can be found by using a great circle, this is easy to visualize, but it's hard to implement like above because my coordinate system isn't continuous.

My coordinate system is as followed (imagine standing in front of the sphere)

The azimuth is 0 ~ pi when traveling along the equator along the front side, it's 0 ~ -pi when traveling along the equator along the rear side.

The inclination is 0~+pi when traveling from the top to the bottom of the sphere.

So given this non-continuous coordinate system, how do I create a decision function that says 'increase A' to travel over the shortest path?

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ying to understand your problem. What prevents you to work in a (0 - 2 Pi) coordinate system, which seems known to you and then do If (a>Pi) then a=Pi - a ? –  belisarius Apr 29 '11 at 12:25
You mean for the azimuth? It's easy to map -pi~pi to 0~2pi if that makes finding the shortest path easier, but how would the total algorithm look? –  Roy T. Apr 29 '11 at 12:32