posted on 2016-11-07, 16:53authored byBjörn Heincke, Marion Jegen, Max Moorkamp, Richard W. Hobbs, Jin Chen
Joint inversion strategies for geophysical data have become increasingly popular as they allow for
the efficient combination of complementary information from different data sets. The algorithm
used for the joint inversion needs to be flexible in its description of the subsurface so as to be
able to handle the diverse nature of the data. Hence, joint inversion schemes are needed that
1) adequately balance data from the different methods, 2) have stable convergence behavior, 3)
consider the different resolution power of the methods used and 4) link the parameter models in
a way that they are suited for a wide range of applications.
Here, we combine active source seismic P-wave tomography, gravity and magnetotelluric
(MT) data in a petrophysical joint inversion that accounts for these issues. Data from the different
methods are inverted separately but are linked through constraints accounting for parameter
relationships. An advantage of performing the inversions separately is that no relative weighting
between the data sets is required. To avoid perturbing the convergence behavior of the inversions
by the coupling, the strengths of the constraints are readjusted at each iteration. The criterion
we use to control the adaption of the coupling strengths is based on variations in the objective
functions of the individual inversions from one to the next iteration. Adaption of the coupling
strengths makes the joint inversion scheme also applicable to subsurface conditions, where assumed
relationships are not valid everywhere, because the individual inversions decouple if it
is not possible to reach adequately low data misfits for the made assumptions. The coupling
constraints depend on the relative resolutions of the methods, which leads to an improved convergence
behavior of the joint inversion. Another benefit of the proposed scheme is that structural
information can easily be incorporated in the petrophysical joint inversion (no additional terms
are added in the objective functions) by using mutually controlled structural weights for the
smoothing constraints.
We test our scheme using data generated from a synthetic 2-D sub-basalt model. We observe
that the adaption of the coupling strengths makes the convergence of the inversions very robust
(data misfits of all methods are close to the target misfits) and that final results are always close to the true models independent of the parameter choices. Finally, the scheme is applied on real data
sets from the Faroe-Shetland Basin to image a basaltic sequence and underlying structures. The
presence of a borehole and a 3-D reflection seismic survey in this region allows direct comparison
and, hence, evaluate the quality of the joint inversion results. The results from joint inversion are
more consistent with results from other studies than the ones from the corresponding individual
inversions and the shape of the basaltic sequence is better resolved. However, due to the limited
resolution of the individual methods used it was not possible to resolve structures underneath the
basalt in detail, indicating that additional geophysical information (e.g. CSEM, reflection onsets)
needs to be included.
History
Citation
Journal of Applied Geophysics, 2017, 136, pp. 279–297
Author affiliation
/Organisation/COLLEGE OF SCIENCE AND ENGINEERING/Department of Geology
The file associated with this record is under embargo until 12 months after publication, in accordance with the publisher's self-archiving policy. The full text may be available through the publisher links provided above.