I'm in the process of writing an application to suggest circular routes over OpenStreetMap data subject to some constraints (the Orienteering Problem). In the innermost loop of the algorithm I'm trialling is a requirement to find the lowest cost path between two given points. Given the layout of the graph (basically Euclidean), the A star algorithm seems to be likely to produce results in the fastest time given the graph. However as well as distances on my edges (representing actual distances on the map), I also have a series of weights (currently scaled from 0.0, least desirable to 1.0, most desirable) indicating how desirable the particular edge (road/path/etc) is, calculated according to some metrics I've devised for my application.
I would like to modify my distances based on these weights. I am aware that the standard A star heuristic relies on the true cost of the path being at least as great as the estimate (based on a euclidean distance between the points). So my first thought was to come up with a scheme where the minimum edge distance is the real distance (for weight 1.0) and the distance is increased as the weight decreases (for instance quadrupling the distance for weight 0.0). Does this seem a sensible approach, or is there a better standard technique for fast routing under these circumstances?