Untangling the Blum medial axis transform

For over 30 years, Blum’s Medial Axis Transform (MAT) has proven to be an intriguing tool for analyzing and computing with shape, but it is one that is notoriously difficult to apply in a robust and stable way. It is well documented how a tiny change to an object’s boundary can cause a large change in its MAT. There has also been great difficulty in using the MAT to decompose an object into a hierarchy of parts reflecting the natural parts-hierarchy that we perceive. This paper argues that the underlying cause of these problems is that medial representations embody both the substance of each part of an object and the connections between adjacent parts. A small change in an object’s boundary corresponds to a small change in its substance but may involve a large change in its connection information. The problems with Blum’s MAT are generated because it does not explicitly represent this dichotomy of information. To use the Blum MAT to it’s full potential, this paper presents a method for separating the substance and connection information of an object. This provides a natural parts-hierarchy while eliminating instabilities due to small boundary changes. The method also allows for graded, fuzzy classifications of object parts to match the ambiguity in human perception of many objects.