Abstract

In this study, we focus on a hydrogeological inverse problem specifically targeting monitoring soil moisture variations using tomographic ground penetrating radar (GPR) travel time data. Technical challenges exist in the inversion of GPR tomographic data for handling non-uniqueness, nonlinearity and high-dimensionality of unknowns. We have developed a new method for estimating soil moisture fields from crosshole GPR data. It uses a pilot-point method to provide a low-dimensional representation of the relative dielectric permittivity field of the soil, which is the primary object of inference: the field can be converted to soil moisture using a petrophysical model. We integrate a multi-chain Markov chain Monte Carlo (MCMC)–Bayesian inversion framework with the pilot point concept, a curved-ray GPR travel time model, and a sequential Gaussian simulation algorithm, for estimating the dielectric permittivity at pilot point locations distributed within the tomogram, as well as the corresponding geostatistical parameters (i.e., spatial correlation range). We infer the dielectric permittivity as a probability density function, thus capturing the uncertainty in the inference. The multi-chain MCMC enables addressing high-dimensional inverse problems as required in the inversion setup. The method is scalable in terms of number of chains and processors, and is useful for computationally demanding Bayesian model calibration in scientific and engineering problems. The proposed inversion approach can successfully approximate the posterior density distributions of the pilot points, and capture the true values. The computational efficiency, accuracy, and convergence behaviors of the inversion approach were also systematically evaluated, by comparing the inversion results obtained with different levels of noises in the observations, increased observational data, as well as increased number of pilot points.

Highlights

  • Monitoring soil moisture in the vadose zone is crucial for weather forecasts (Ni-Meister et al 2005), predicting natural disaster (Tohari et al 2007), evaluating contaminant transport (Murdoch 2000), agriculture (Shaxson and Barber 2003), and many other societal needs.The techniques of monitoring soil moisture can be divided into four main classes, and they are space-borne sensors, air-borne sensors, wireless sensor networks, and ground-based sensors (Vereecken et al 2008)

  • In this study, we focus on a hydrogeological inverse problem targeting monitoring soil moisture variations using tomographic ground penetrating radar (GPR) travel time data

  • We integrate a multi-chain Markov chain Monte Carlo (MCMC)–Bayesian inversion framework with the pilot point concept, a curved-ray GPR travel time model, and a sequential Gaussian simulation algorithm, for estimating the dielectric permittivity at pilot point locations distributed within the tomogram, as well as the corresponding geostatistical parameters

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Summary

Introduction

The techniques of monitoring soil moisture can be divided into four main classes, and they are space-borne sensors, air-borne sensors, wireless sensor networks, and ground-based sensors (Vereecken et al 2008). GPR does not provide the most accurate soil moisture measurement compared to some conventional sensors (e.g., gravimetric, frequencyand time-domain reflectometry (FDR and TDR), neutron probe and capacitance probe techniques), but in practice, it is very time-consuming to capture the spatial variability of soil moisture by using large numbers of closely spaced conventional sensors/probes. Through time-lapse and/or joint inversion, tomographic GPR has the capability for longterm monitoring of spatial distribution of soil moisture within the vadose zone (Binley et al 2002; Hubbard et al 1997), and for deriving other spatially heterogeneous soil physical properties (e.g., permeability and porosity) (Binley et al 2002; Chen et al 2001; Clement and Barrash 2006; Dubreuil-Boisclair et al 2011; Hubbard et al 1997, 2001; Kowalsky et al 2004, 2005)

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