English

Tensor-Based Modal Decomposition and Sparse Sensor Placement for the Brugge Field Simulation Model

Signal Processing 2026-06-17 v1

Abstract

Sparse monitoring of reservoir pressure and saturation requires numerical methods that retain gridded structure while reconstructing full fields from few observations. We present a four-dimensional tensor-based modal decomposition (TBMD) and sparse reconstruction framework for coupled pressure-saturation fields. The approach uses an explicit property mode, mode-4 pivoted orthogonal-triangular (QR) ranking of grid-wide spatial-property fibers, and tensor-based compressive sensing for both grid-wide and existing-well measurement operators. The Brugge benchmark is evaluated using 10 well-control realizations with fixed geology. Each realization is processed independently as a tensor of size 139 x 48 x 2 x 134 under an 80/20 temporal split with training-fitted property-wise min-max normalization. In the joint pressure-saturation well-only study, increasing the number of instrumented wells from 1 to 10 reduces the relative Frobenius error from about 0.57 to 0.20, increases the Structural Similarity Index Measure from about 0.47 to 0.88, and raises the peak signal-to-noise ratio from about 33.8 to 37 dB. By 20 wells, the relative error drops to about 0.11. The results support the feasibility of tensor-structured sparse reconstruction for coupled reservoir fields and provide a basis for controlled comparisons with alternative reduced-order and sparse-sensing methods.

Cite

@article{arxiv.2607.09687,
  title  = {Tensor-Based Modal Decomposition and Sparse Sensor Placement for the Brugge Field Simulation Model},
  author = {D. Samatov and B. Merzlikin and G. Shishaev},
  journal= {arXiv preprint arXiv:2607.09687},
  year   = {2026}
}

Comments

63 pages, 12 figures