Modeling and Inversion of Shallow Seismic Data Including Nongeometrical Waves
Abstract
Solving a geophysical inverse problem requires making inferences about the earth from data. Since one always has only a finite number of (uncertain) data and since the models used to describe the earth are infinite dimensional (i.e., functions of space), it follows that if there are any models at all that fit the data, there will likely be many of them. Thus, finding a single model that fits the data is of limited value without a quantitative assessment of its uncertainty. During the course of this project we have developed novel theoretical and computational strategies for making statistically rigorous inferences about the earth's near-surface from full-waveform reflection and borehole seismic data. Our approach allows us to assimilate information at vastly different length scales and to take advantage of all the information in the seismic waveforms, as well as quantifying uncertainties in the data due to noise and theoretical errors. We have demonstrated the efficiency and utility of this approach on field data and have produced computer codes (using freely available compilers and message passing libraries) which perform in a scalable, distributed-parallel fashion on heterogeneous networks of workstations or shared-memory multiprocessors.
Document Details
- Document Type
- Technical Report
- Publication Date
- Dec 29, 1997
- Accession Number
- ADA344956
Entities
People
- Alberto Villarreal
- John A. Scales
- W. C. Navidi
Organizations
- Colorado School of Mines