Wireless channels exhibit complex signal strength fluctuation over time due to signal propagation effects interacting with a dynamic environment. For accurate simulation of wireless networking protocols, it is important to model wireless channels accurately; without accurate models, simulation results have been shown to be significantly different from measured results. Accurate statistical models of the state of a particular channel can be constructed based on obtained experimental measurements. However, this approach cannot be easily exploited for dynamic simulations (e.g., those with mobility), because it is impossible to pre-measure all of the possible channels that arise during the simulation; for example, in a mobile ad hoc network the nodes move and a very large number of channels is encountered in the lifetime of the simulation. In this paper, we propose the use of interpolation between measured channels to produce models for other channels that have not been measured, significantly increasing the flexibility of this approach. Instead of obtaining measurement traces for every link, our method estimates the essential parameters for a new link by interpolation from nearby measured links. Thus, the flexibility of measurement based models is increased dramatically, providing a modeling approach that is both accurate and flexible. We validate the approach using representative experiments.