Paper detail

Site characterization at downhole arrays by joint inversion of dispersion data and acceleration time series

We present a sequential data assimilation algorithm based on the ensemble Kalman inversion to estimate the near-surface shear wave velocity profile and damping when heterogeneous data and a priori information that can be represented in forms of (physical) equality and inequality constraints in the inverse problem are available. Although non-invasive methods, such as surface wave testing, are efficient and cost effective methods for inferring Vs profile, one should acknowledge that site characterization using inverse analyses can yield erroneous results associated with the inverse problem non-uniqueness. One viable solution to alleviate the inverse problem ill-posedness is to enrich the prior knowledge and/or the data space with complementary observations. In the case of non-invasive methods, the pertinent data are the dispersion curve of surface waves, typically resolved by means of active source methods at high frequencies and passive methods at low frequencies. To improve the inverse problem well-posedness, horizontal to vertical spectral ratio (HVSR) data are commonly used jointly with the dispersion data in the inversion. In this paper, we show that the joint inversion of dispersion and strong motion downhole array data can also reduce the margins of uncertainty in the Vs profile estimation. This is because acceleration time-series recorded at downhole arrays include both body and surface waves and therefore can enrich the observational data space in the inverse problem setting. We also show how the proposed algorithm can be modified to systematically incorporate physical constraints that further enhance its well-posedness. We use both synthetic and real data to examine the performance of the proposed framework in estimation of Vs profile and damping at the Garner Valley downhole array, and compare them against the Vs estimations in previous studies.