Executive Summary

This course provides a structured and applied approach to reservoir characterization for modelling to support reliable subsurface decision-making. It explains how geological, petrophysical, seismic, and dynamic data are integrated into consistent reservoir models. Participants learn how to translate raw data into usable modelling inputs such as facies, rock types, porosity, permeability, and saturation trends. The program emphasizes uncertainty management and the impact of assumptions on model outcomes. It covers practical workflows for static model construction and preparation for flow simulation. The course highlights data conditioning, quality control, and scaling from core to field scale. Participants practice building coherent reservoir frameworks that honor stratigraphy and structure. Integrated interpretation is reinforced to improve model realism and predictability. The training develops professional competence for creating fit-for-purpose reservoir models across exploration and development phases.

Introduction

The purpose of this course is to develop professional capability in reservoir characterization for modelling by focusing on integrated data interpretation and practical modelling deliverables. It addresses the challenge of converting diverse subsurface datasets into consistent geological and reservoir property models. The scope includes geological framework building, stratigraphic correlation, facies modelling, and petrophysical property distribution. Participants learn how to evaluate data quality and manage contradictions between sources. The course explains how core, logs, and seismic information are scaled and conditioned for modelling. It introduces rock typing and flow unit concepts that connect geology to reservoir performance. Dynamic data integration is addressed to ensure models remain consistent with production behavior. The training emphasizes uncertainty quantification and scenario thinking. It prepares participants to communicate model limitations clearly and support decisions with defensible reservoir characterization.

Course Objectives

Participants will achieve the following objectives by the Reservoir characterization for modelling course:

• Define reservoir characterization inputs and organize them into a clear modelling workflow with measurable deliverables.

• Interpret stratigraphic and structural controls and convert them into a consistent reservoir framework for modelling.

• Classify facies and rock types using core and log evidence to support realistic property modelling.

• Apply petrophysical quality control and select appropriate upscaling approaches to reduce modelling bias.

• Build property trends for porosity, permeability, and saturation that honor geology and data constraints.

• Integrate seismic information to improve reservoir geometry understanding and spatial property continuity.

• Validate static model outputs using dynamic data signals and identify mismatches that require revisions.

• Assess uncertainty sources and generate practical scenarios that bound key reservoir outcomes.

• Communicate model assumptions, limitations, and confidence levels clearly to multidisciplinary stakeholders.

Target Audience

This Reservoir characterization for modelling program targets a professional audience seeking to improve knowledge and skills:

• Reservoir geologists building static models.

• Petrophysicists preparing log-derived properties for modelling.

• Geomodellers responsible for facies and property distribution.

• Reservoir engineers using models for forecasting and development planning.

• Geophysicists integrating seismic into reservoir frameworks.

• Field development teams managing subsurface uncertainty.

• Subsurface team leaders reviewing modelling deliverables.

• Professionals transitioning into reservoir modelling roles.

Course Outline

Day 1: Reservoir Characterization Workflow and Data Readiness for Modelling

• Define the purpose of reservoir characterization in modelling and decision support.

• Map the end-to-end workflow from raw data to a model-ready dataset.

• Review core, log, seismic, and production data and identify strengths and limitations.

• Establish quality control rules for wells, depth shifts, and stratigraphic consistency.

• Build a structured data inventory and define minimum requirements for modelling.

• Explain scale differences between core, log, seismic, and field behavior using clear examples.

• Identify common causes of bias introduced during data conditioning and cleaning.

• Create a consistent terminology set for facies, rock types, and property definitions across teams.

Day 2: Structural Framework, Stratigraphic Correlation, and Reservoir Zonation

• Interpret structural elements that control reservoir geometry and compartmentalization.

• Convert faults and horizons into a modelling framework and define structural uncertainties.

• Perform stratigraphic correlation and define reservoir zones with clear rules.

• Identify key stratigraphic surfaces that control thickness, continuity, and connectivity.

• Develop a conceptual depositional model to guide facies expectations and trends.

• Define layering strategies and grid implications for modelling accuracy and stability.

• Evaluate the impact of correlation choices on volumes and connectivity.

• Document framework decisions to support auditability and future updates.

Day 3: Facies Modelling, Rock Typing, and Upscaling for Static Models

• Define facies schemes that are meaningful for modelling and reservoir performance.

• Use core descriptions and log patterns to classify lithofacies and depositional units.

• Build rock types and flow units that connect petrophysical behavior to geology.

• Apply statistical checks to ensure facies proportions match well control and concepts.

• Discuss geostatistical approaches and choose methods suited to data density and uncertainty.

• Apply upscaling principles from logs to grid scale with attention to heterogeneity.

• Identify pitfalls in facies modelling such as over-conditioning and unrealistic continuity.

• Establish validation checks using cross-sections, maps, and vertical proportion curves.

Day 4: Petrophysical Property Modelling and Seismic Integration

• Perform petrophysical quality control for porosity, permeability, and saturation inputs.

• Define property distributions by zone and facies and justify modelling assumptions.

• Build trends and anisotropy rules that reflect depositional and diagenetic controls.

• Select variogram concepts and continuity assumptions aligned with geological reality.

• Integrate seismic-derived information to refine geometry, thickness, and spatial patterns.

• Evaluate uncertainty in seismic interpretation and its consequences on property distribution.

• Apply model diagnostics to detect unrealistic property clustering or smoothing.

• Prepare model outputs for simulation use with clear metadata and version control logic.

Day 5: Dynamic Consistency, Uncertainty Management, and Fit-for-Purpose Models

• Link static model assumptions to expected dynamic behavior and flow performance.

• Compare model predictions with production indicators and pressure behavior trends.

• Identify mismatch causes and define practical revision actions for model improvement.

• Build uncertainty ranges using scenario design and sensitivity thinking.

• Define key uncertainties that influence reserves, recovery, and development planning.

• Communicate modelling risk and confidence in clear language for decision makers.

• Create a final model summary that states inputs, assumptions, limitations, and usability.

• Consolidate a repeatable reservoir characterization checklist for future modelling projects.

Course Duration

This [Reservoir characterization for modelling] course is available in different durations: 1 week (intensive training), 2 weeks (moderate pace with additional practice sessions), or 3 weeks (a comprehensive learning experience). The course can be attended in person or online, depending on the trainee's preference.

Instructor Information

This [Reservoir characterization for modelling] course is delivered by expert trainers worldwide, bringing global experience and best practices. The instructors have extensive experience in reservoir geology, geomodelling, and integrated subsurface studies. Their teaching approach emphasizes structured workflows and defensible technical reasoning. Training delivery focuses on practical modelling decisions and quality control discipline. Participants benefit from cross-domain expertise that connects geology, petrophysics, seismic, and reservoir engineering.

Frequently Asked Questions

1- Who should attend this [Reservoir characterization for modelling] course?

This course is suitable for subsurface professionals involved in building or using reservoir models for development and evaluation.

2- What are the key benefits of this [Reservoir characterization for modelling] training?

It improves the ability to integrate data, reduce uncertainty, and produce models that support reliable decisions.

3—Do participants receive a certificate? Yes, upon successful completion, all participants will receive a professional certification.

4- What language is the course delivered in? English and Arabic.

5- Can I attend online? Yes, you can attend in person, online, or in-house at your company.

Conclusion

This course builds a practical and structured foundation for reservoir characterization for modelling. It strengthens the ability to convert subsurface data into model-ready inputs with clear quality control. Participants learn how to build frameworks, facies, and property distributions that remain consistent with geological understanding. The training supports uncertainty-aware modelling and clearer communication of risk. The outcomes lead to more reliable reservoir models and better subsurface decisions.