Suppose that the track is small enough that we can assume that the points lie in a flat plane, e.g., we can ignore the curvature of the earth. In this case you can convert all the points to points in a plane, e.g., P(i) = (x(i), y(i)) without a z-coordinate.
Consider the following algorithm: Find a point C = (Cx, Cy) that is somewhere in the middle of track, e.g., the centroid of all the points. The exact position doesn't matter. Then imagine that an observer is standing at point C and is always rotating to face the vehicle. You want to count how many times the observer rotates as the vehicle travels.
To do this, you need to be able to find the signed angle the observer will rotate as the vehicle travels between two adjacent points P(i) and P(i+1) in the list of points. This is the same as finding the signed angle between the vectors P(i) - C and P(i+1) - C, which can be done using the cross product. This is particularly easy, since we have 2-dimensional points. We have
P = (x(i) - Cx) * (y(i+1) - Cy) +
(x(i+1) - Cx) * (y(i) - Cy)
If P is positive then the observer is rotating counter-clockwise and if it is negative the the observer is rotating clockwise. The angle the observer rotates is
theta(i, i+1) = arcsin( P /
(length(x(i) - C) * length(x(i+1) -
where again theta(i, i+1) is positive or negative depending on which direction the observer is rotating.
Here we are using that adjacent points are close together, so that the observer just rotates through a small angle less than pi/2 between adjacent points.
To find the total amount the observer rotates just sum all the thetas from the beginning to the ending of the path, making sure to preserve the sign of the theta in case the vehicle moves backwards for some reason. Assuming that the theta are in radians, the total number of circuits is just the sum of the thetas divided by 2 * pi.
For the truly geeky, this is just calculating the winding number of the vehicle's path around C using the definition.