Abstract
During drilling, to maximize future expected production of hydrocarbon resources, the experts commonly adjust the trajectory (geosteer) in response to new insights obtained through real-time measurements. Geosteering workflows are increasingly based on the quantification of subsurface uncertainties during real-time operations. As a consequence, operational decision-making is becoming both better informed and more complex. This paper presents an experimental web-based decision support system, which can be used to both teach expert decisions under uncertainty or further develop decision optimization algorithms in a controlled environment. A user of the system (either human or AI) controls the decisions to steer the well or stop drilling. Whenever a user drills ahead, the system produces simulated measurements along the selected well trajectory which are used to update the uncertainty represented by model realizations using the ensemble Kalman filter. To enable informed decisions the system is equipped with functionality to evaluate the value of the selected trajectory under uncertainty with respect to the objectives of the current experiment.To illustrate the utility of the system as a benchmark, we present the initial experiment, in which we compare the decision skills of geoscientists with those of a recently published automatic decision support algorithm. The experiment and the survey after it showed that most participants were able to use the interface and complete the three test rounds. At the same time, the automated algorithm outperformed 28 out of 29 human participants.Such an experiment is not sufficient to draw conclusions about practical geosteering but is nevertheless useful for geoscience. First, this communication-by-doing made 76% of respondents more curious about and/or confident in the presented technologies. Second, the system can be further used as a benchmark for sequential decisions under uncertainty. This can accelerate development of algorithms and improve the training for decision making.
Highlights
Geosteering is the intentional control of a well trajectory based on the results of down-hole real-time geophysical measurements (Shen et al, 2018)
We have developed a web-based platform that can update a multi-realization 2D geological model in response to decisions and share the current state of the system via an Application Program ming Interface (API) and a Graphical User Interface (GUI)
The web-based platform has been developed to compare the DSS-1 to human experts, and through this comparison, to communicate the concepts related to real-time decision making under uncertainty
Summary
Geosteering is the intentional control of a well trajectory based on the results of down-hole real-time geophysical measurements (Shen et al, 2018). As a result, during the last decade, there has been a steady growth of automated methods for measurement inversion and interpretation which yield steadily growing amounts of data that need to be handled by the decision-makers. This data opens the possibility to target the oil-bearing zones which were not economically viable previously (Larsen et al, 2016). Complex uncertainties that can impact decisions on one hand and contradicting objectives on the other (see e.g. Halset et al (2020)), pose difficulty for decision-makers and requires new workflows and/or training
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