ABSTRACT Saturated hydraulic conductivity (Ks ) is among the most important soil parameters for modeling hydrological processes, and its field-scale variability plays a significant role for soils subjected to light and moderate rainfalls. It is often assessed by either making point-scale measurements using permeameters and infiltrometers or coupling probabilistic models with field-scale infiltration experiments under natural/artificial rainfall conditions. The former requires numerous measurements across the study area, and the latter is constrained by the infiltration experiment’s rainfall pattern, thereby restricting these approaches to only partially resolving the spatial variability of Ks , over a field. This study investigated the applicability of three in situ infiltration devices – the double-ring infiltrometer, Commonwealth Scientific and Industrial Research Organisation (CSIRO) version of the tension permeameter, and Guelph permeameter – using a Bayesian framework. Results indicate the disparate estimates of Ks distribution parameters obtained from each instrument’s infiltration data. Using field-scale rainfall-runoff data, a posterior coarsening method is proposed to reconcile the point estimates from different instruments.