Basic GEOPHYSICS - BGP Virtual

DISCIPLINE: Geophysics
 
LEVEL: Basic
 

DURATION: 2 hours instructor-led (virtual), plus approximately 47 hours self-paced work

INSTRUCTORS:

Ms. Nancy House
Mr. John Logel
 
 
TUITION: $3,900 USD
 
 
UPCOMING SESSIONS:
 
8 January - 28 March 2018                   View Schedule                          ENROLL NOW  
 
2 April - 1 June 2018                               View Schedule                          ENROLL NOW  
 
23 July - 14 September 2018               View Schedule                          ENROLL NOW  
 
 
 

This workshop will be delivered virtually through PetroAcademy™ providing participants with the knowledge they need at their convenience. PetroAcademy™ FAQ

ABOUT THE COURSE

This course is designed to familiarize anyone using seismic data with the nature of the data and what they specifically represent. One of the key goals of the course is to explain the confusing amount of jargon that is used by the geophysical community when they use seismic data. The course is supplemented by a large number of case histories that concretely illustrate the principles in the course material. These are updated with every course presentation to keep up with the rapidly developing technology in this field.

 

DESIGNED FOR

Geoscientists, engineers, team leaders, geoscience technicians, asset managers, and anyone involved in using seismic data that needs to understand and use this data at a basic level or to communicate with others that use it.

LEARNING OBJECTIVES - CORE MODULES

  • NATURE OF SEISMIC IMAGE
  • GEOLOGICAL ASSOCIATION WITH SEISMIC REFLECTIONS
  • SEISMIC DATA ACQUISITION
  • WAVELET IN THE SEISMIC DATA AND LIMITS ON RESOLUTION
  • SEISMIC VELOCITIES
  • OVERVIEW OF SEISMIC DATA PROCESSING
  • SEISMIC MIGRATION
  • DIRECT HYDROCARBON INDICATORS
  • AMPLITUDE vs. OFFSET (AVO)
  • SEISMIC INVERSION
  • ATTRIBUTES
  • SEISMIC MAPPING FUNDAMENTALS

This introductory module is an overview of the nature of seismic data, and how it is constructed and displayed. The purpose of the module is to familiarize learners with the nature of the seismic data that is presented to them.

 

You will learn:

  • What’s propagating that we can record
  • Forming an image by compositing or “stacking”
  • Reflections at a geologic interface
  • The problem with stacking
  • An introduction to seismic migration
  • Seismic displays in both depth or time

The key to using or interpreting seismic data is to relate it to the geology and prospectivity. This module is designed to explain the basics of what is called the seismic process.

 

You will learn:

  • Changes in lithology
  • Velocity and density
  • The influence of porosity and pore filling material

The goal of this module is to present stacking in 3D for both land and marine data. The point here is that the seismic image is heavy composited from several hundred reflections off of the same point in 3-dimensional space.

 

You will learn:

  • Marine acquisition
  • Land acquisition
  • Making a 3D data cube
  • The concept of bin gathering

The vertical resolution of the seismic data is a critical issue because reservoirs are at or below the limit of resolution of the seismic data. The resolution is controlled by the propagating wavelet that is generated by the acquisition parameters. This concept is key to understanding the nature of seismic data.

 

You will learn:

  • Generating a propagating energy package
  • The wavelet and its resolution

The purpose of this module is to understand seismic velocities and how they are used to construct the seismic image. This is probably one of the biggest variables in seismic data.

 

You will learn:

  • The velocity family, the relationship between depth and time
  • Well velocities
  • Vertical seismic profiles (VSPs)
  • Overpressure and seismic velocities

This module gives a very general overview of the processes used to create the seismic image. The objective is to clarify the jargon. This consists of “pre-conditioning” the data, and then forming the image by seismic migration.

 

You will learn:

  • Data conditioning, deconvolution
  • Imaging with seismic migration in depth and time

This module gives a very general overview of the processes used to create the seismic image. The objective is to clarify the jargon. This consists of “pre-conditioning” the data, and then forming the image by seismic migration.

 

You will learn:

  • Data conditioning, deconvolution
  • Imaging with seismic migration in depth and time

The effect of hydrocarbons as a pore filling material in our seismic data is at the core of seismic interpretation. This module includes a section on rock physics.

 

You will learn:

  • The effects of hydrocarbons in the seismic image
  • Some rock physics
  • Pore filling materials

The effect of hydrocarbons as a pore filling material in our seismic data is at the core of seismic interpretation. This module includes a section on rock physics.

 

You will learn:

  • The effects of hydrocarbons in the seismic image
  • Some rock physics
  • Pore filling materials

What is done to the data is very simple, but the impact on our interpretation has become a huge issue. We have literally turned the seismic data into a rock property, specifically impedance. This is probably how we will view our seismic data in the future. Don’t forget about the importance of density.

 

You will learn:

  • Rock parameters (Impedance) from seismic data
  • Inversion overview

This introductory section is a quick overview of some of the rather puzzling attributes that are often shown, and ae usually poorly explained. We do not typically view our seismic data in the frequency or phase domain, but they are becoming popular displays.

 

You will learn:

  • Where seismic imaging is going
  • Getting down to rock properties
  • A bit of an interpretation enigma
  • How to solve the resolution problem
  • An attribute list

This module walks the participant through the process of 3D mapping that is carried out on a workstation.

 

You will learn:

  • The layout of a 3D seismic survey
  • How to turn the interpretation into a data reduction process resulting in an interpretation and a structural map originally in time
  • The relationship between the data acquired in time, and the presentation of the map in depth
BLENDED LEARNING WORKSHOP STRUCTURE
 

This program is comprised of the following activities:

 
= Virtual Instructor-led Training
 
 
 Online
= Online Learning Activity/Reading
 
 


UPCOMING SESSIONS:
 
8 January - 2 March 2018                     View Schedule                          ENROLL NOW  
 
2 April - 1 June 2018                               View Schedule                          ENROLL NOW  
 
23 July - 14 September 2018               View Schedule                          ENROLL NOW  
 

Week Activity Hours (Approx)  Subject
Week 1
1.0  Orientation Webcast
  Online 4.0 Nature of Seismic Image
Week 2 Online 4.0 Geological Association with Seismic Reflections
  Online 4.0 Seismic Data Acquisition
Week 3 Online 4.0 Wavelet in the Seismic Data and Limits on Resolution
  Online 4.0 Seismic Velocities
Week 4 Online 4.0 Overview of Seismic Data Processing
  Online 4.0 Seismic Migration
Week 5 2.0 Seismic Mapping Fundamentals - instructor-led session
  Online 2.0 Seismic Mapping Fundamentals
Week 6 Online 4.0 Direct Hydrocarbon Indicators
  Online 4.0 Amplitude vs. Offset
Week 7 Online 4.0 Seismic Inversion
Week 8 Online 4.0 Attributes