Solving the assignment problem is overkill for this, given that you are trying to assign three points to three fingers. Even if you are trying to assign five points to five fingers, you are better off using a brute force approach to figuring out the optimal configuration of points to fingers. Note that for three fingers and three points, there are only six possible unique assignments of fingers to points. So it's best to just calculate the cost of each assignment configuration and choose the one with least cost.
However, I think this is missing the point of your question. The tricky part is not the assignment process itself, but choosing a decent "cost" function for each possible assignment. If the cost function doesn't take account of prior finger-point assignments, then there's an equal cost to assigning any finger to any point and so you lack any "continuity" where fingers are assigned to the same moving point.
So your goal is to ensure your assignment models 'real life'. The approach I suggest is this:
Define a physical model for the movement of fingers. A very simple model would be a momentum model where each finger is independent of each other and is assumed to have some inertia. If a finger moves dx,dy in one frame, you would expect it to move dx,dy in the second frame. This gives you an expectation value for where you expect the finger to be next. Now you can define the cost of assigning a finger to a point as some function of the distance between the location of the actual point registered and where you expected it to be.
Sum up the costs for each finger-point assignment and find the configuration with lowest cost.
Now, if you want to be more sophisticated, all you have to do is use a more sophisticated model. Perhaps you don't want to assume fingers move independently. You might want to expect some correlation between the finger movements. In which case, refine the model, calculate the new point expectations and calculate the cost of the assignment as before.