SPE Journal
Volume 15, Number 2, June 2010, pp. 471-479

SPE-113647-PA

Control-Relevant Upscaling

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DOI  More information 10.2118/113647-PA http://dx.doi.org/10.2118/113647-PA

Citation

  • Vakili-Ghahani, S.A. and Jansen, J.D. 2009. Control-Relevant Upscaling. SPE J.  15 (2): 471-479. SPE-113647-PA. doi: 10.2118/113647-PA.

Discipline Categories

  • 6 Reservoir Description and Dynamics
  • 6.5 Reservoir Simulation
  • 6.8 Fundamental Research in Reservoir Description and Dynamics

Keywords

  • upscaling; model reduction; systems; control

Summary

The conventional reason for upscaling in reservoir simulation is the computational limit of the simulator. However, we argue that, from a system-theoretical point of view, a more fundamental reason is that there is only a limited amount of information (output) that can be observed from production data, while there is also a limited amount of control (input) that can be exercised by adjusting the well parameters; in other words, the input/output behavior is usually of much lower dynamical order than the number of gridblocks in the model. Therefore, we propose an upscaling approach to find a coarse model that optimally describes the input/output behavior of a reservoir system. In this control-relevant method, the coarse-scale-model parameters are calculated as the solution of an optimization problem that minimizes the distance between the input/output behaviors of the fine- and coarse-scale models. This distance is measured with the aid of the Hankel or energy norms, in which we use Hankel singular values as a measure of the combined controllability and observability and Markov parameters as a measure of the response of the system, respectively. The method is particularly attractive to scale up simulation models in flooding-optimization or history-matching studies for a given configuration of wells. An advantage of our upscaling method is that it relies most heavily on those parameter values that directly influence the input/output behavior. It is a global method in the sense that it relies on the system properties of the entire reservoir. It does not, however, require any forward simulation, either of the full or of the upscaled model. It also does not depend on a particular control strategy but instead uses the dynamical system equations directly. Its dependency on well locations, however, implies that it should be (partially) repeated when those locations are changed. We tested the method on several examples and, for nearly all cases, obtained coarse-scale models with a superior input/output behavior compared to common upscaling algorithms.

© 2009. Society of Petroleum Engineers

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History

  • Original manuscript received: 21 July 2008
  • Meeting paper published: 9 June 2008
  • Revised manuscript received: 21 June 2009
  • Manuscript approved: 27 June 2009
  • Published online: 22 December 2009
  • Version of record: 17 June 2010