Abstract
ABSTRACTElectrical resistivity tomography is a non‐linear and ill‐posed geophysical inverse problem that is usually solved through gradient‐descent methods. This strategy is computationally fast and easy to implement but impedes accurate uncertainty appraisals. We present a probabilistic approach to two‐dimensional electrical resistivity tomography in which a Markov chain Monte Carlo algorithm is used to numerically evaluate the posterior probability density function that fully quantifies the uncertainty affecting the recovered solution. The main drawback of Markov chain Monte Carlo approaches is related to the considerable number of sampled models needed to achieve accurate posterior assessments in high‐dimensional parameter spaces. Therefore, to reduce the computational burden of the inversion process, we employ the differential evolution Markov chain, a hybrid method between non‐linear optimization and Markov chain Monte Carlo sampling, which exploits multiple and interactive chains to speed up the probabilistic sampling. Moreover, the discrete cosine transform reparameterization is employed to reduce the dimensionality of the parameter space removing the high‐frequency components of the resistivity model which are not sensitive to data. In this framework, the unknown parameters become the series of coefficients associated with the retained discrete cosine transform basis functions. First, synthetic data inversions are used to validate the proposed method and to demonstrate the benefits provided by the discrete cosine transform compression. To this end, we compare the outcomes of the implemented approach with those provided by a differential evolution Markov chain algorithm running in the full, un‐reduced model space. Then, we apply the method to invert field data acquired along a river embankment. The results yielded by the implemented approach are also benchmarked against a standard local inversion algorithm. The proposed Bayesian inversion provides posterior mean models in agreement with the predictions achieved by the gradient‐based inversion, but it also provides model uncertainties, which can be used for penetration depth and resolution limit identification.
Highlights
The electrical resistivity tomography (ERT) is a non-linear problem and for this reason the posterior probability density (PPD) cannot be expressed in a closed form, but it must be numerically evaluated, for example by employing Markov Chain Monte Carlo algorithms (MCMC; Sambridge and Mosegaard, 2000)
This work was aimed at casting the electrical resistivity tomography (ERT) inversion into a solid probabilistic framework for accurate uncertainty assessments
In this paper, we proposed an alternative approach to the classical gradient-based electrical resistivity tomography inversion, that makes use of the Markov chain Monte Carlo probabilistic framework embedded in the differential evolution Markov chain sampling
Summary
Deterministic gradient-based algorithms (Zhang et al, 2005; Pidlisecky and Knight, 2008) are employed to tackle the ERT problem These methods linearize the problem around an initial solution, thereby losing the information for accurate uncertainty appraisals. The Bayesian approach is commonly employed to cast an inverse problem into a solid probabilistic framework In this context, the final solution of the inversion is the so-called posterior probability density (PPD) function in model space (Ramirez et al, 2005; Tarantola, 2005; Sen and Stoffa, 2013; Aleardi et al, 2018; Galetti and Curtis, 2018; Aleardi and Salusti, 2020) that fully quantifies the ambiguities in the recovered model. The sampling ability of MCMC algorithms severely decreases in highly dimensional model spaces due to the so-called curse of the dimensionality problem (Curtis et al, 2001)
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