Environment General Courses (ENVIRON)
graduate level, taught in Durham
298.22 Understanding Energy Models
and Modeling Syllabus
Timothy L. Johnson, Ph.D.
U.S. EPA, Office of Research and Development
johnson.tim@epa.gov
919-541-0575
“Office hours” before and after class, or at
a mutually-agreeable time
Course Description
and Learning Objectives
Energy models are widely used for forecasting,
system design, and pedagogical purposes. The availability
of cheap computing power has increased both the
sophistication and accessibility of these models,
providing the policy community with an increasingly
broad range of studies as well as the ability
to produce its own assessments. Such assessments
can provide a reasonably transparent and objective
foundation for studies of critical energy-related
issues, including the need to mitigate global
climate change, improve air quality, prepare for
the peaking of petroleum and natural gas production,
and ensure sufficient infrastructure capacity.
Like any modeling effort, however, energy models
have their limitations and lend themselves to
abuse and misinterpretation. Policy analysts and
decision makers therefore need to acquire a basic
literacy in energy modeling in order to understand
the modeling process and critically evaluate the
claims others derive from their analyses. What
should one look for in order to determine if conclusions
are credible? What happens inside the black box
of an energy model? How elaborate does a model
need to be, and at what point does technical sophistication
take on a life of its own? In the end, are energy
models actually useful?
This course aims to nurture a basic modeling
literacy by focusing on a widely-used class of
“bottom-up,” optimization-based, energy models
commonly used for economic and environmental assessments.
Students will acquire familiarity with the energy
modeling literature, obtain a working knowledge
of model mechanics and gain experience asking
the type of questions needed to evaluate the quality
of modeling results. Through class discussion,
readings, and student projects, the course will
cover the following topics:
• The history of energy modeling;
• Types of energy models and approaches to energy
modeling;
• Commonly used energy models;
• What typically goes into an energy model, what
comes out, and what happens in between;
• The critical need for sensitivity and uncertainty
analyses;
• How modeling results are actually used in the
policy process and different ways of interpreting
conclusions; and
• Modeling pitfalls, both deliberate abuses and
common misinterpretations.
All students with an interest in becoming good
consumers of energy models, as well as those who
wish to build the foundation needed to become
an actual modeler, are welcome. Comfort with mathematical
modeling would be beneficial, but prior experience
with optimization techniques is not a prerequisite.
Expectations and Grading
Coursework will consist of in-class discussions
of readings and two group-based assignments (see
below). Most class sessions will adopt a seminar-style
discussion format, structured around a combination
of highlights from the day’s readings and student
questions. Students should therefore come to class
having read – and thought about – the related
material. As the value and quality of energy modeling
rest partly in the eye of the beholder, a critical,
questioning attitude will be encouraged.
Final grades will be a combination of the two
assignments (45% each) plus class participation
(10%). The assignments will be graded on their
thoroughness and integration of material discussed
in class, and will depend on the quality of both
the write-up and in-class presentation.
Assignments
The assignments are intended to familiarize students
with the community of energy modeling users (developers,
analysts, and decision makers) and its literature.
In groups (size to be determined based on class
enrollment), students will complete two analyses:
• The first assignment will draw on the material
covered during the first three weeks and look
at the history, basic structure, users, uses,
and limitations of an existing energy model (e.g.,
AMIGA, LEAP, LIEF, MARKAL, MESSAGE, SAGE, etc.).
Each group will write up their findings (5 to
10 pages) and present their analyses to the class
during the fourth session.
• The second assignment will critique a published
modeling-based energy study (one that applies
the modeling framework analyzed in the first assignment)
using the best practice principles discussed in
class as a starting point. Again, each group will
write up their findings (5 to 10 pages) and present
their analyses to the class during the last (seventh)
session.
While all group members will normally receive
the same grade, please include a short statement
with each assignment listing individual member
contributions.
Class Schedule
Date Topic(s) Reading(s)
2/9 Introduction – The world of energy models
and modeling
Uses: Why model?
A systems view of the US energy economy
Approaches to energy modeling Craig, et al. (2002)
Hogan (2002)
Sterman (1991)
2/16 Energy Modeling 101
Energy modeling approaches and frameworks
What to look for in an energy model
The importance of technology change
Scenario analysis Edmonds, et al. (2000)
Grubler, et al. (1999)
Hansen, et al. (2004)
2/23 A look at the U.S. Department of Energy’s
National Energy Modeling System (NEMS): Its structure
and uses EIA (2003)
Skim over and familiarize yourself with the following:
EIA (2005a)
EIA (2005b)
3/9 Assignment 1 presentations
Assignment 1 write-ups due
3/23 Interpretation of model results
The need for sensitivity and uncertainty analyses
Best practices for energy modeling Koomey (2002)
Morgan and Henrion (1990)
Munson (2004)
3/30 Energy models in the policy process
Critique of energy modeling DeCanio (2003)
Laitner, et al. (2003)
Smil (2003)
Worrell, et al. (2004)
4/13 Assignment 2 presentations
Assignment 2 write-ups due
Note that there will be no class March 2, March
16, and April 6.
Readings
Craig, P.P., Gadgil, A., and Koomey, J.G. (2002).
“What can history teach us? A retrospective examination
of long-term energy forecasts for the United States.”
Annu. Rev. Energy Environ. 27:83-118.
DeCanio, S. (2003). “The Forecasting Performance
of Energy-Economic Models.” Chapter 5 from Economic
Models of Climate Change: A Critique. NY: Palgrave
Macmillan, pp. 126-152.
Grubler, A., Nakicenovic, N, and Victor, D.G.
(1999). “Dynamics of energy technologies and global
change.” Energy Policy 27:247-280.
Edmonds, J., Roop, J.M., and Scott, M.J. (2000).
“Technology and the economics of climate change
policy.” Washington, DC: Pew Center on Global
Climate Change. Accessed from http://www.pewclimate.org/global-warming-in-depth/economics/reports.
EIA (Energy Information Administration), Office
of Integrated Analysis and Forecasting, US Department
of Energy (2003). The National Energy Modeling
System: An Overview 2003. DOE/EIA-0581(2003).
Washington, DC: US Government Printing Office.
Accessed from http://www.eia.doe.gov/oiaf/aeo/overview/index.html.
EIA (Energy Information Administration), Office
of Integrated Analysis and Forecasting, US Department
of Energy (2005a). Annual Energy Outlook 2005
With Projections to 2025. DOE/EIA-0383(2005).
Washington, DC: US Government Printing Office.
Accessed from http://www.eia.doe.gov/oiaf/aeo/index.html.
Supplemental tables available from http://www.eia.doe.gov/oiaf/aeo/supplement/index.html.
EIA (Energy Information Administration), Office
of Energy Markets and End Use, US Department of
Energy (2005b). Annual Energy Review 2004. DOE/EIA-0384(2004).
Washington, DC: US Government Printing Office.
Accessed from http://www.eia.doe.gov/emeu/aer/contents.html.
Hansen, D.A., Mintzer, I., Laitner, J.A., and
Leonard, J.A. (2004). Engines of Growth: Energy
Challenges, Opportunities, and Uncertainties In
the 21st Century, Argonne, IL: Argonne National
Laboratory, Decision and Information Sciences
Division. Available from amiga.dis.anl.gov/Engines_of_GrowthJan17-04_rev161.pdf.
Hogan, W.W. (2002). “Energy modeling for policy
studies.” Operations Research 50(1): 89-95.
Koomey, J. (2002). “Avoiding ‘The Big Mistake’
in forecasting technology adoption.” Technology
Forecasting & Social Change 69:511-518.
Laitner, J.A., DeCanio, S.J., Koomey, J.G., and
Sanstad, A.H. (2003). “Room for improvement: increasing
the value of energy modeling for policy analysis.”
Utilities Policy 11:87-94.
Morgan, M.G., and Henrion, M. (1990). “Large
and complex models.” Chapter 11 from Uncertainty:
A Guide to Dealing with Uncertainty in Quantitative
Risk and Policy Analysis. Cambridge, MA: Cambridge
University Press, pp. 289-306.
Munson, R. (2004). “Improving prediction of energy
futures.” Issues in Science and Technology Spring:
26-29.
Smil, V. (2003). “Against forecasting.” Chapter
3 from Energy at the Crossroads: Global Perspectives
and Uncertainties. Cambridge, MA: The MIT Press,
pp. 121-180.
Sterman, J.D. (1991). “A skeptic's guide to computer
models.” In Barney, G. O. et al. (eds.), Managing
a Nation: The Microcomputer Software Catalog.
Boulder, CO: Westview Press, 209-229.
Worrell, E., Ramesohl, S., and Boyd, G. (2004).
“Advances in energy forecasting models based on
engineering economics.” Annu. Rev. Environ. Resour.
29:345-81.
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