| Abstract |
Geothermal reservoirs are typical examples of natural systems having incomplete and discontinuous information. Data obtained show heterogeneity, frequently, at a high degree. Any geothermal reservoir manifests the following paradox: it is a natural phenomenon whose existence is uniquely determined in time and in space, but that can only�be known or measured in an incomplete and fractional manner. Advanced simulators used to study and predict the behavior of such systems require petrophysical and thermodynamical continuous parameters, even at places�where they have never been measured.��Traditional statistics used to calculate average values of those parameters, becomes evidently insufficient because the geothermal processes involved, are non-stationary. For example, temperature and pressure increase with depth, while porosity and permeability decrease. In this document we introduce practical applications of a numerical technique based on the theory of Intrinsic Random Functions of order k (k > l), for the optimum spatial interpolation of geothermal parameters. This method�allows the construction of geo-statistical generalized estimators composed by two functions: one portion can be totally random, while the second portion is deterministic, containing the spatial trend of the non-stationary�parameter. This methodology has great potential usefulness in the risk analysis of any geothermal project.� |