October 26-28, 2021
PRACTICAL SEISMIC PETROPHYSICS: THE EFFECTIVE USE OF LOG DATA FOR SEISMIC ANALYSIS
Instructors: Tad Smith, Petrophysical Solutions, Inc (PSI) and Matt Blyth, Schlumberger
COURSE SUMMARY: The conditioning and analysis of log data for quantitative seismic interpretation is often simply categorized as “rock physics.” Unfortunately,
rock physics workflows often overlook or oversimplify the proper
editing and interpretation of log data, the result of which can be
unrealistic expectations and interpretations of seismic amplitude
responses. The more
encompassing phrase “seismic petrophysics” better describes the
necessary linkage between petrophysics and rock physics. Seismic
petrophysics not only includes rock physics, but also includes the
proper conditioning and interpretation of log data that should occur
prior to the application of rock physics and seismic models. This
is especially true in conditioning log data for shear-wave velocity
estimation, fluid substitution calculations, and AVO modeling.
This class will focus on the important
role of “seismic petrophysics” in the quest to extract additional
information from subtle seismic responses. Some of the topics covered
will include important background information, relevant aspects of
petrophysical interpretation, various aspects of log editing, and the
basics of elasticity and rock physics. We will spend considerable time
discussing some common pitfalls associated with the “workhorses” of rock
physics, including invasion corrections, problems associated with shear
velocity estimation, and some of the challenges and pitfalls associated
with Gassmann fluid substitution. It is important to recognize that
log data should not simply be recomputed to fit prior expectations as
defined by a rock physics model. Instead, rock physics models should be
used as templates, which allow the interpreter to better understand the
underlying physics of observed log responses and how they are governed
by local petrophysical properties. Case studies will be used to
reinforce critical concepts.
ABOUT THE INSTRUCTORS
Tad Smith specializes in seismic rock properties and petrophysics at Petrophysical Solutions, Inc (PSI). Prior to joining PSI in January of 2019, Tad worked as a technical contributor and/or manager at various companies, including Apache Corporation, ConocoPhillips, VeritasDGC, Newfield, BP, and Amoco. In 1995 – 1996, he participated in the Amoco Petrophysics Training program, where he developed a keen interest in petrophysics and seismic rock properties (“seismic petrophysics”). Since then, he has been actively engaged in the process of integrating petrophysical data into geophysical workflows. In 2011 he was the North American Honorary Lecturer for the Society of Exploration Geophysicists, with the topic of his tour being “Seismic Petrophysics”. Tad was elected President of the Geophysical Society of Houston for the 2013-2014 term; he previously served as the GSH Secretary during the 2005-2006 term. From 2010 – 2014 he served on the editorial board for The Leading Edge, a leading industry publication, and served as the Editorial Board chair during the 2013-2014 term. He currently serves on the Board of Directors for the Society of Exploration Geophysicists as a Director at Large. Tad has a PhD in geology from Texas A&M University (1991), an MSc from Washington State University, and a BA from Ohio Wesleyan University. He is a member of SEG, SPWLA, and GSH. When he is not working on interesting petrophysical problems, he enjoys time with his wife and son, riding bicycles, spending time with good friends, and listening to good music.
Matthew Blyth, Schlumberger Drilling and Measurements will be providing the class with some very useful information on sonic and density logs.
DURATION: This will be one class over 3 half-days.
REGISTRATION FEES: Member $350 - Non-Member $450 - Students $50
DATES: Oct 26 (Tuesday) Oct 27(Wednesday) Oct 28 (Thursday)
TIME: Class starts at 8a - 12p (CST) 3 days.
LOCATION: Presented via Webinar - Registration Link will be sent to your email.