Existence and phase structure of random inverse limit measures

Analogous to Kolmogorov's theorem for the existence of random functions, we consider the existence of limits of inverse systems of random histograms (restrictions of measures to finite partitions of the underlying space). Given a coherent inverse system of random (bounded/ signed/positive/probability) histograms on refining partitions, we study conditions for the existence and uniqueness of a corresponding random inverse limit measure, described by a Radon probability measure on the space of (bounded/signed/positive/probability) measures. Depending on the topology (vague, tight, weak or total-variational) and Kingman's notion of complete randomness, the limiting random (probability) measure is in one of four phases, distinguished by their degrees of concentration (support, domination, discreteness). Results are applied in the well-known Dirichlet and Polya tree families of random probability measures and in a new Gaussian family of signed inverse limit measures. In these three families, examples of all four phases occur and we describe the corresponding conditions on defining parameters.