Two Dimensional Curve Approximation

here is what I want to do (preferably with Matlab):

Basically I have several traces of cars driving on an intersection. Each one is noisy, so I want to take the mean over all measurements to get a better approximation of the real route. In other words, I am looking for a way to approximate the Curve, which has the smallest distence to all of the meassured traces (in a least-square sense).

At the first glance, this is quite similar what can be achieved with spap2 of the CurveFitting Toolbox (good example in section Least-Squares Approximation here). But this algorithm has some major drawback: It assumes a function (with exactly one y(x) for every x), but what I want is a curve in 2d (which may have several y(x) for one x). This leads to problems when cars turn right or left with more then 90 degrees. Futhermore it takes the vertical offsets and not the perpendicular offsets (according to the definition on wolfram).

Has anybody an idea how to solve this problem? I thought of using a B-Spline and change the number of knots and the degree until I reached a certain fitting quality, but I can't find a way to solve this problem analytically or with the functions provided by the CurveFitting Toolbox. Is there a way to solve this without numerical optimization?

-
Could you make each path a function of time? For each time value, a car would only have one (x,y) coordinate. –  mbeckish Jan 4 '12 at 15:12
This yields to the problem, that every car drives with a different speed. If t=0 is set at a given point ahead of the intersection, one car may already have finished the turning manoever, while the other (more carefully car) has not after the same amount of time. As a consequence, the mean of (x,y) of both cars at the same time doesn't lead to a curve with the smallest distance (in the x-y-plane) to the measured traces . –  ILikeCars Jan 4 '12 at 15:28
I was thinking instead of averaging different cars' paths, you could just filter the high frequency noise out of each path to make them smooth. –  mbeckish Jan 4 '12 at 15:42