Title: Flaw of Averages
1Flaw of Averages
- This presentation explains a common problem in
the design and evaluation of systems - This problem is the pattern of designing and
evaluating systems based on the average or
most likely future projections - Problem derives from misunderstanding of
probability and systems behavior, known as - FLAW OF AVERAGES
2Flaw of Averages
- Name derives from Sam Savage
- It is a pun, integrating two concepts
- It refers to
- A mistake gt a flaw
- The concept of the law of averages, that is,
that things balance out on average - The flaw consists of assuming that design or
evaluation based on average (or most likely)
conditions give correct answers
3A motivating example
- The design of an oil platform and wells in Golf
of Mexico (Babajide)
4Gulf of Mexico Platform Probability Mass
Functions
Note Most likely scenarios are 150 and 100
5Combined PMF
6Comparison of Values
Based on most likely estimates
Based on actual distribution of possibilities
Actual ENPV ? Value based on Mostly Likely
Conditions
7Another motivating example
- Decision Analysis example
8Comparison of Results
Value based on most likely event (No Carbon Tax)
6.00 Value based on recognizing possibility of
Carbon Tax is different 10.8
9Why does Flaw occur?
- Flaw is a pattern in systems design, Why?
- Several reasons converge
- Difficult to evaluate system over many different
possibilities hard enough to create one design - Management fixes parameters (such as oil price)
to facilitate comparisons in company - Uncertainties exist outside of technical
specialty (markets, geology) so that designers
use best estimates
10Mathematics of Flaw
- Jensens law
- The Average of all the possible outcomes
associated with uncertain parameters
- generally does not equal
- the value obtained from using the average value
of the parameters - E f(x) ? f E(x) except when f(x) linear
11Consequences
- In simple terms, this means that the answer you
get from a realistic description differs often
greatly from the answer you from using most
likely estimates - This is because the gains when things do well do
not balance the losses when things do not - (sometimes theyre more, sometimes less)
- In short system behavior is non-linear
123 Reasons for Non-Linearity
- System response is non-linear
- System response involves some discontinuity (step
change) - Management rationally imposes a discontinuity
13System Response is Non-Linear
- Economies of Scale Unit costs decrease with
scale of production - Large initial costs prorated over volume, so that
unit costs decrease as scale increases toward
capacity - Increasing marginal costs as scale increases
(labor, material costs higher)
Unit Cost
This is Usual Situation!
Scale
14System Response involves some Discontinuity
- Discontinuities special form of non-linearity
- Discontinuities are Common
- Expansion of a Project might only occur in large
increments (new runways, for example) - A System may be capacity constrained, so that
profitability or values increases with demand up
to a point, and then levels off
15Management Creates Discontinuity
- Whenever the Managers or System Operators decide
to take some major decision about a project to
enlarge it or change its function this creates
a step change in the performance of the system. - This can happen often and does!
- See Flaw of Averages draft chapter
16Take-Aways
- Do not be a victim of Flaw of Averages
- Do not value projects or make design decisions
based on average or most likely forecasts. - Do consider, as best you can, the entire range of
possible events and examine the entire
distribution of consequences.