Pages

Thursday, March 01, 2007

About "The Psychology of Security"

CRYPTO-GRAM
February 28, 2007
by Bruce Schneier
Founder and CTO
BT Counterpane
schneier@schneier.com
http://www.schneier.com
http://www.counterpane.com

A free monthly newsletter providing summaries, analyses, insights, and
commentaries on security: computer and otherwise.
For back issues, or to subscribe, visit
<http://www.schneier.com/crypto-gram.html>.
You can read this issue on the web at
<http://www.schneier.com/crypto-gram-0702a.html>. These same essays
appear in the "Schneier on Security" blog:
<http://www.schneier.com/blog>. An RSS feed is available.

** *** ***** ******* *********** *************
This is a special issue of Crypto-Gram.
In this issue:
About "The Psychology of Security"
THE PSYCHOLOGY OF SECURITY
Comments from Readers

** *** ***** ******* *********** *************
About "The Psychology of Security"

This essay is a draft. It's something I'm working on -- possibly it
will become a book, but probably not -- and something I'm interested in
comments about.
It's also available as HTML and pdf:
http://www.schneier.com/essay-155.html
http://www.schneier.com/essay-155.pdf
Thank you for reading it. I look forward to your comments.

** *** ***** ******* *********** *************
THE PSYCHOLOGY OF SECURITY -- DRAFT


INTRODUCTION
Security is both a feeling and a reality. And they're not the same.
The reality of security is mathematical, based on the probability of
different risks and the effectiveness of different countermeasures. We
can calculate how secure your home is from burglary, based on such
factors as the crime rate in the neighborhood you live in and your
door-locking habits. We can calculate how likely it is for you to be
murdered, either on the streets by a stranger or in your home by a
family member. Or how likely you are to be the victim of identity
theft. Given a large enough set of statistics on criminal acts, it's
not even hard; insurance companies do it all the time.
We can also calculate how much more secure a burglar alarm will make
your home, or how well a credit freeze will protect you from identity
theft. Again, given enough data, it's easy.
But security is also a feeling, based not on probabilities and
mathematical calculations, but on your psychological reactions to both
risks and countermeasures. You might feel terribly afraid of terrorism,
or you might feel like it's not something worth worrying about. You
might feel safer when you see people taking their shoes off at airport
metal detectors, or you might not. You might feel that you're at high
risk of burglary, medium risk of murder, and low risk of identity theft.
And your neighbor, in the exact same situation, might feel that he's
at high risk of identity theft, medium risk of burglary, and low risk of
murder.
Or, more generally, you can be secure even though you don't feel secure.
And you can feel secure even though you're not. The feeling and
reality of security are certainly related to each other, but they're
just as certainly not the same as each other. We'd probably be better
off if we had two different words for them.
This essay is my initial attempt to explore the feeling of security:
where it comes from, how it works, and why it diverges from the reality
of security.
Four fields of research -- two very closely related -- can help
illuminate this issue. The first is behavioral economics, sometimes
called behavioral finance. Behavioral economics looks at human biases
-- emotional, social, and cognitive -- and how they affect economic
decisions. The second is the psychology of decision-making, and more
specifically bounded rationality, which examines how we make decisions.
Neither is directly related to security, but both look at the concept
of risk: behavioral economics more in relation to economic risk, and the
psychology of decision-making more generally in terms of security risks.
But both fields go a long way to explain the divergence between the
feeling and the reality of security and, more importantly, where that
divergence comes from.
There is also direct research into the psychology of risk.
Psychologists have studied risk perception, trying to figure out when we
exaggerate risks and when we downplay them.
A fourth relevant field of research is neuroscience. The psychology of
security is intimately tied to how we think: both intellectually and
emotionally. Over the millennia, our brains have developed complex
mechanisms to deal with threats. Understanding how our brains work, and
how they fail, is critical to understanding the feeling of security.
These fields have a lot to teach practitioners of security, whether
they're designers of computer security products or implementers of
national security policy. And if this paper seems haphazard, it's
because I am just starting to scratch the surface of the enormous body
of research that's out there. In some ways I feel like a magpie, and
that much of this essay is me saying: "Look at this! Isn't it
fascinating? Now look at this other thing! Isn't that amazing, too?"
Somewhere amidst all of this, there are threads that tie it together,
lessons we can learn (other than "people are weird"), and ways we can
design security systems that take the feeling of security into account
rather than ignoring it.
THE TRADE-OFF OF SECURITY
Security is a trade-off. This is something I have written about
extensively, and is a notion critical to understanding the psychology of
security. There's no such thing as absolute security, and any gain in
security always involves some sort of trade-off.
Security costs money, but it also costs in time, convenience,
capabilities, liberties, and so on. Whether it's trading some
additional home security against the inconvenience of having to carry a
key around in your pocket and stick it into a door every time you want
to get into your house, or trading additional security from a particular
kind of airplane terrorism against the time and expense of searching
every passenger, all security is a trade-off.
I remember in the weeks after 9/11, a reporter asked me: "How can we
prevent this from ever happening again?" "That's easy," I said, "simply
ground all the aircraft."
It's such a far-fetched trade-off that we as a society will never make
it. But in the hours after those terrorist attacks, it's exactly what
we did. When we didn't know the magnitude of the attacks or the extent
of the plot, grounding every airplane was a perfectly reasonable
trade-off to make. And even now, years later, I don't hear anyone
second-guessing that decision.
It makes no sense to just look at security in terms of effectiveness.
"Is this effective against the threat?" is the wrong question to ask.
You need to ask: "Is it a good trade-off?" Bulletproof vests work well,
and are very effective at stopping bullets. But for most of us, living
in lawful and relatively safe industrialized countries, wearing one is
not a good trade-off. The additional security isn't worth it: isn't
worth the cost, discomfort, or unfashionableness. Move to another part
of the world, and you might make a different trade-off.
We make security trade-offs, large and small, every day. We make them
when we decide to lock our doors in the morning, when we choose our
driving route, and when we decide whether we're going to pay for
something via check, credit card, or cash. They're often not the only
factor in a decision, but they're a contributing factor. And most of
the time, we don't even realize it. We make security trade-offs
intuitively.
These intuitive choices are central to life on this planet. Every
living thing makes security trade-offs, mostly as a species -- evolving
this way instead of that way -- but also as individuals. Imagine a
rabbit sitting in a field, eating clover. Suddenly, he spies a fox.
He's going to make a security trade-off: should I stay or should I flee?
The rabbits that are good at making these trade-offs are going to live
to reproduce, while the rabbits that are bad at it are either going to
get eaten or starve. This means that, as a successful species on the
planet, humans should be really good at making security trade-offs.
And yet, at the same time we seem hopelessly bad at it. We get it wrong
all the time. We exaggerate some risks while minimizing others. We
exaggerate some costs while minimizing others. Even simple trade-offs
we get wrong, wrong, wrong -- again and again. A Vulcan studying human
security behavior would call us completely illogical.
The truth is that we're not hopelessly bad at making security
trade-offs. We are very well adapted to dealing with the security
environment endemic to hominids living in small family groups on the
highland plains of East Africa. It's just that the environment of New
York in 2007 is different from Kenya circa 100,000 BC. And so our
feeling of security diverges from the reality of security, and we get
things wrong.
There are several specific aspects of the security trade-off that can go
wrong. For example:
1. The severity of the risk.
2. The probability of the risk.
3. The magnitude of the costs.
4. How effective the countermeasure is at mitigating the risk.
5. How well disparate risks and costs can be compared.
The more your perception diverges from reality in any of these five
aspects, the more your perceived trade-off won't match the actual
trade-off. If you think that the risk is greater than it really is,
you're going to overspend on mitigating that risk. If you think the
risk is real but only affects other people -- for whatever reason --
you're going to underspend. If you overestimate the costs of a
countermeasure, you're less likely to apply it when you should, and if
you overestimate how effective a countermeasure is, you're more likely
to apply it when you shouldn't. If you incorrectly evaluate the
trade-off, you won't accurately balance the costs and benefits.
A lot of this can be chalked up to simple ignorance. If you think the
murder rate in your town is one-tenth of what it really is, for example,
then you're going to make bad security trade-offs. But I'm more
interested in divergences between perception and reality that _can't_ be
explained that easily. Why is it that, even if someone knows that
automobiles kill 40,000 people each year in the U.S. alone, and
airplanes kill only hundreds worldwide, he is more afraid of airplanes
than automobiles? Why is it that, when food poisoning kills 5,000
people every year and 9/11 terrorists killed 2,973 people in one
non-repeated incident, we are spending tens of billions of dollars per
year (not even counting the wars in Iraq and Afghanistan) on terrorism
defense while the entire budget for the Food and Drug Administration in
2007 is only $1.9 billion?
It's my contention that these irrational trade-offs can be explained by
psychology. That something inherent in how our brains work makes us
more likely to be afraid of flying than of driving, and more likely to
want to spend money, time, and other resources mitigating the risks of
terrorism than those of food poisoning. And moreover, that these
seeming irrationalities have a good evolutionary reason for existing:
they've served our species well in the past. Understanding what they
are, why they exist, and why they're failing us now is critical to
understanding how we make security decisions. It's critical to
understanding why, as a successful species on the planet, we make so
many bad security trade-offs.
CONVENTIONAL WISDOM ABOUT RISK
Most of the time, when the perception of security doesn't match the
reality of security, it's because the perception of the risk doesn't
match the reality of the risk. We worry about the wrong things: paying
too much attention to minor risks and not enough attention to major
ones. We don't correctly assess the magnitude of different risks. A
lot of this can be chalked up to bad information or bad mathematics, but
there are some general pathologies that come up over and over again.
In _Beyond Fear, _I listed five:
* People exaggerate spectacular but rare risks and downplay common risks.
* People have trouble estimating risks for anything not exactly like
their normal situation.
* Personified risks are perceived to be greater than anonymous risks.
* People underestimate risks they willingly take and overestimate risks
in situations they can't control.
* Last, people overestimate risks that are being talked about and remain
an object of public scrutiny.[1]
David Ropeik and George Gray have a longer list in their book _Risk: A
Practical Guide for Deciding What's Really Safe and What's Really
Dangerous in the World Around You_:
* Most people are more afraid of risks that are new than those they've
lived with for a while. In the summer of 1999, New Yorkers were
extremely afraid of West Nile virus, a mosquito-borne infection that had
never been seen in the United States. By the summer of 2001, though the
virus continued to show up and make a few people sick, the fear had
abated. The risk was still there, but New Yorkers had lived with it for
a while. Their familiarity with it helped them see it differently.
* Most people are less afraid of risks that are natural than those that
are human-made. Many people are more afraid of radiation from nuclear
waste, or cell phones, than they are of radiation from the sun, a far
greater risk.
* Most people are less afraid of a risk they choose to take than of a
risk imposed on them. Smokers are less afraid of smoking than they are
of asbestos and other indoor air pollution in their workplace, which is
something over which they have little choice.
* Most people are less afraid of risks if the risk also confers some
benefits they want. People risk injury or death in an earthquake by
living in San Francisco or Los Angeles because they like those areas, or
they can find work there.
* Most people are more afraid of risks that can kill them in
particularly awful ways, like being eaten by a shark, than they are of
the risk of dying in less awful ways, like heart disease -- the leading
killer in America.
* Most people are less afraid of a risk they feel they have some control
over, like driving, and more afraid of a risk they don't control, like
flying, or sitting in the passenger seat while somebody else drives.
* Most people are less afraid of risks that come from places, people,
corporations, or governments they trust, and more afraid if the risk
comes from a source they don't trust. Imagine being offered two glasses
of clear liquid. You have to drink one. One comes from Oprah Winfrey.
The other comes from a chemical company. Most people would choose
Oprah's, even though they have no facts at all about what's in either glass.
* We are more afraid of risks that we are more aware of and less afraid
of risks that we are less aware of. In the fall of 2001, awareness of
terrorism was so high that fear was rampant, while fear of street crime
and global climate change and other risks was low, not because those
risks were gone, but because awareness was down.
* We are much more afraid of risks when uncertainty is high, and less
afraid when we know more, which explains why we meet many new
technologies with high initial concern.
* Adults are much more afraid of risks to their children than risks to
themselves. Most people are more afraid of asbestos in their kids'
school than asbestos in their own workplace.
* You will generally be more afraid of a risk that could directly affect
you than a risk that threatens others. U.S. citizens were less afraid
of terrorism before September 11, 2001, because up till then the
Americans who had been the targets of terrorist attacks were almost
always overseas. But suddenly on September 11, the risk became
personal. When that happens, fear goes up, even though the statistical
reality of the risk may still be very low. [2]
Others make these and similar points, which are summarized in Table 1.
[3] [4] [5] [6]
When you look over the list in Table 1, the most remarkable thing is how
reasonable so many of them seem. This makes sense for two reasons.
One, our perceptions of risk are deeply ingrained in our brains, the
result of millions of years of evolution. And two, our perceptions of
risk are generally pretty good, and are what have kept us alive and
reproducing during those millions of years of evolution.
People exaggerate risks that are: People downplay risks that are:
--------------------------------- -------------------------------
Spectacular Pedestrian
Rare Common
Personified Anonymous
Beyond their control, or More under their control, or
externally imposed taken willingly
Talked about Not discussed
Intentional or man-made Natural
Immediate Long-term or diffuse
Sudden Evolving slowly over time
Affecting them personally Affecting others
New and unfamiliar Familiar
Uncertain Well understood
Directed against their children Directed towards themselves
Morally offensive Morally desirable
Entirely without redeeming Associated with some ancillary
features benefit
Not like their current situation Like their current situation
Table 1: Conventional Wisdom About People and Risk Perception

When our risk perceptions fail today, it's because of new situations
that have occurred at a faster rate than evolution: situations that
exist in the world of 2007, but didn't in the world of 100,000 BC. Like
a squirrel whose predator-evasion techniques fail when confronted with a
car, or a passenger pigeon who finds that evolution prepared him to
survive the hawk but not the shotgun, our innate capabilities to deal
with risk can fail when confronted with such things as modern human
society, technology, and the media. And, even worse, they can be made
to fail by others -- politicians, marketers, and so on -- who exploit
our natural failures for their gain.
To understand all of this, we first need to understand the brain.
RISK AND THE BRAIN
The human brain is a fascinating organ, but an absolute mess. Because
it has evolved over millions of years, there are all sorts of processes
jumbled together rather than logically organized. Some of the processes
are optimized for only certain kinds of situations, while others don't
work as well as they could. And there's some duplication of effort, and
even some conflicting brain processes.
Assessing and reacting to risk is one of the most important things a
living creature has to deal with, and there's a very primitive part of
the brain that has that job. It's the amygdala, and it sits right above
the brainstem, in what's called the medial temporal lobe. The amygdala
is responsible for processing base emotions that come from sensory
inputs, like anger, avoidance, defensiveness, and fear. It's an old
part of the brain, and seems to have originated in early fishes. When
an animal -- lizard, bird, mammal, even you -- sees, hears, or feels
something that's a potential danger, the amygdala is what reacts
immediately. It's what causes adrenaline and other hormones to be
pumped into your bloodstream, triggering the fight-or-flight response,
causing increased heart rate and beat force, increased muscle tension,
and sweaty palms.
This kind of thing works great if you're a lizard or a lion. Fast
reaction is what you're looking for; the faster you can notice threats
and either run away from them or fight back, the more likely you are to
live to reproduce.
But the world is actually more complicated than that. Some scary things
are not really as risky as they seem, and others are better handled by
staying in the scary situation to set up a more advantageous future
response. This means that there's an evolutionary advantage to being
able to hold off the reflexive fight-or-flight response while you work
out a more sophisticated analysis of the situation and your options for
dealing with it.
We humans have a completely different pathway to deal with _analyzing_
risk. It's the neocortex, a more advanced part of the brain that
developed very recently, evolutionarily speaking, and only appears in
mammals. It's intelligent and analytic. It can reason. It can make
more nuanced trade-offs. It's also much slower.
So here's the first fundamental problem: we have two systems for
reacting to risk -- a primitive intuitive system and a more advanced
analytic system -- and they're operating in parallel. And it's hard for
the neocortex to contradict the amygdala.
In his book _Mind Wide Open,_ Steven Johnson relates an incident when he
and his wife lived in an apartment and a large window blew in during a
storm. He was standing right beside it at the time and heard the
whistling of the wind just before the window blew. He was lucky -- a
foot to the side and he would have been dead -- but the sound has never
left him:
But ever since that June storm, a new fear has entered the
mix for me: the sound of wind whistling through a window. I
know now that our window blew in because it had been
installed improperly.... I am entirely convinced that the
window we have now is installed correctly, and I trust our
superintendent when he says that it is designed to withstand
hurricane-force winds. In the five years since that June, we
have weathered dozens of storms that produced gusts
comparable to the one that blew it in, and the window has
performed flawlessly.
I know all these facts -- and yet when the wind kicks up, and
I hear that whistling sound, I can feel my adrenaline levels
rise.... Part of my brain -- the part that feels most _me_-
like, the part that has opinions about the world and decides
how to act on those opinions in a rational way -- knows that
the windows are safe.... But another part of my brain wants
to barricade myself in the bathroom all over again.[7]
There's a good reason evolution has wired our brains this way. If
you're a higher-order primate living in the jungle and you're attacked
by a lion, it makes sense that you develop a lifelong fear of lions, or
at least fear lions more than another animal you haven't personally been
attacked by. From a risk/reward perspective, it's a good trade-off for
the brain to make, and -- if you think about it -- it's really no
different than your body developing antibodies against, say, chicken pox
based on a single exposure. In both cases, your body is saying: "This
happened once, and therefore it's likely to happen again. And when it
does, I'll be ready." In a world where the threats are limited -- where
there are only a few diseases and predators that happen to affect the
small patch of earth occupied by your particular tribe -- it works.
Unfortunately, the brain's fear system doesn't scale the same way the
body's immune system does. While the body can develop antibodies for
hundreds of diseases, and those antibodies can float around in the
bloodstream waiting for a second attack by the same disease, it's harder
for the brain to deal with a multitude of lifelong fears.
All this is about the amygdala. The second fundamental problem is that
because the analytic system in the neocortex is so new, it still has a
lot of rough edges evolutionarily speaking. Psychologist Daniel Gilbert
has a great quotation that explains this:
The brain is a beautifully engineered get-out-of-the-way
machine that constantly scans the environment for things out
of whose way it should right now get. That's what brains did
for several hundred million years -- and then, just a few
million years ago, the mammalian brain learned a new trick: to
predict the timing and location of dangers before they
actually happened.
Our ability to duck that which is not yet coming is one of the
brain's most stunning innovations, and we wouldn't have dental
floss or 401(k) plans without it. But this innovation is in
the early stages of development. The application that allows
us to respond to visible baseballs is ancient and reliable,
but the add-on utility that allows us to respond to threats
that loom in an unseen future is still in beta testing. [8]
A lot of what I write in the following sections are examples of these
newer parts of the brain getting things wrong.
And it's not just risks. People are not computers. We don't evaluate
security trade-offs mathematically, by examining the relative
probabilities of different events. Instead, we have shortcuts, rules of
thumb, stereotypes, and biases -- generally known as "heuristics."
These heuristics affect how we think about risks, how we evaluate the
probability of future events, how we consider costs, and how we make
trade-offs. We have ways of generating close-to-optimal answers quickly
with limited cognitive capabilities. Don Norman's wonderful essay,
"Being Analog," provides a great background for all this.[9]
Daniel Kahneman, who won a Nobel Prize in Economics for some of this
work, talks about humans having two separate cognitive systems: one that
intuits and one that reasons:
The operations of System 1 are typically fast, automatic,
effortless, associative, implicit (not available to
introspection), and often emotionally charged; they are also
governed by habit and therefore difficult to control or modify.
The operations of System 2 are slower, serial, effortful, more
likely to be consciously monitored and deliberately
controlled; they are also relatively flexible and potentially
rule governed.[10]
When you read about the heuristics I describe below, you can find
evolutionary reasons for why they exist. And most of them are still
very useful.[11] The problem is that they can fail us, especially in
the context of a modern society. Our social and technological evolution
has vastly outpaced our evolution as a species, and our brains are stuck
with heuristics that are better suited to living in primitive and small
family groups.
And when those heuristics fail, our feeling of security diverges from
the reality of security.
RISK HEURISTICS
The first, and most common, area that can cause the feeling of security
to diverge from the reality of security is the perception of risk.
Security is a trade-off, and if we get the severity of the risk wrong,
we're going to get the trade-off wrong. We can do this both ways, of
course. We can underestimate some risks, like the risk of automobile
accidents. Or we can overestimate some risks, like the risk of a
stranger sneaking into our home at night and kidnapping our child. How
we get the risk wrong -- when we overestimate and when we underestimate
-- is governed by a few specific brain heuristics.
Prospect Theory
Here's an experiment that illustrates a particular pair of
heuristics.[12] Subjects were divided into two groups. One group was
given the choice of these two alternatives:
* Alternative A: A sure gain of $500.
* Alternative B: A 50% chance of gaining $1,000.
The other group was given the choice of:
* Alternative C: A sure loss of $500.
* Alternative D: A 50% chance of losing $1,000.
These two trade-offs aren't the same, but they're very similar. And
traditional economics predicts that the difference doesn't make a
difference.
Traditional economics is based on something called "utility theory,"
which predicts that people make trade-offs based on a straightforward
calculation of relative gains and losses. Alternatives A and B have the
same expected utility: +$500. And alternatives C and D have the same
expected utility: -$500. Utility theory predicts that people choose
alternatives A and C with the same probability and alternatives B and D
with the same probability. Basically, some people prefer sure things
and others prefer to take chances. The fact that one is gains and the
other is losses doesn't affect the mathematics, and therefore shouldn't
affect the results.
But experimental results contradict this. When faced with a gain, most
people (84%) chose Alternative A (the sure gain) of $500 over
Alternative B (the risky gain). But when faced with a loss, most people
(70%) chose Alternative D (the risky loss) over Alternative C (the sure
loss).
The authors of this study explained this difference by developing
something called "prospect theory." Unlike utility theory, prospect
theory recognizes that people have subjective values for gains and
losses. In fact, humans have evolved a pair of heuristics that they
apply in these sorts of trade-offs. The first is that a sure gain is
better than a chance at a greater gain. ("A bird in the hand is better
than two in the bush.") And the second is that a sure loss is worse
than a chance at a greater loss. Of course, these are not rigid rules
-- given a choice between a sure $100 and a 50% chance at $1,000,000,
only a fool would take the $100 -- but all things being equal, they do
affect how we make trade-offs.
Evolutionarily, presumably it is a better survival strategy to -- all
other things being equal, of course -- accept small gains rather than
risking them for larger ones, and risk larger losses rather than
accepting smaller losses. Lions chase young or wounded wildebeest
because the investment needed to kill them is lower. Mature and healthy
prey would probably be more nutritious, but there's a risk of missing
lunch entirely if it gets away. And a small meal will tide the lion
over until another day. Getting through today is more important than
the possibility of having food tomorrow.
Similarly, it is evolutionarily better to risk a larger loss than to
accept a smaller loss. Because animals tend to live on the razor's edge
between starvation and reproduction, any loss of food -- whether small
or large -- can be equally bad. That is, both can result in death. If
that's true, the best option is to risk everything for the chance at no
loss at all.
These two heuristics are so powerful that they can lead to logically
inconsistent results. Another experiment, the Asian disease problem,
illustrates that.[13] In this experiment, subjects were asked to
imagine a disease outbreak that is expected to kill 600 people, and then
to choose between two alternative treatment programs. Then, the
subjects were divided into two groups. One group was asked to choose
between these two programs for the 600 people:
* Program A: "200 people will be saved."
* Program B: "There is a one-third probability that 600 people will be
saved, and a two-thirds probability that no people will be saved."
The second group of subjects were asked to choose between these two
programs:
* Program C: "400 people will die."
* Program D: "There is a one-third probability that nobody will die, and
a two-thirds probability that 600 people will die."
Like the previous experiment, programs A and B have the same expected
utility: 200 people saved and 400 dead, A being a sure thing and B being
a risk. Same with Programs C and D. But if you read the two pairs of
choices carefully, you'll notice that -- unlike the previous experiment
-- they are exactly the same. A equals C, and B equals D. All that's
different is that in the first pair they're presented in terms of a gain
(lives saved), while in the second pair they're presented in terms of a
loss (people dying).
Yet most people (72%) choose A over B, and most people (78%) choose D
over C. People make very different trade-offs if something is presented
as a gain than if something is presented as a loss.
Behavioral economists and psychologists call this a "framing effect":
peoples' choices are affected by how a trade-off is framed. Frame the
choice as a gain, and people will tend to be risk averse. But frame the
choice as a loss, and people will tend to be risk seeking.
We'll see other framing effects later on.
Another way of explaining these results is that people tend to attach a
greater value to changes closer to their current state than they do to
changes further away from their current state. Go back to the first
pair of trade-offs I discussed. In the first one, a gain from $0 to
$500 is worth more than a gain from $500 to $1,000, so it doesn't make
sense to risk the first $500 for an even chance at a second $500.
Similarly, in the second trade-off, more value is lost from $0 to -$500
than from -$500 to -$1,000, so it makes sense for someone to accept an
even chance at losing $1,000 in an attempt to avoid losing $500.
Because gains and losses closer to one's current state are worth more
than gains and losses further away, people tend to be risk averse when
it comes to gains, but risk seeking when it comes to losses.
Of course, our brains don't do the math. Instead, we simply use the
mental shortcut.
There are other effects of these heuristics as well. People are not
only risk averse when it comes to gains and risk seeking when it comes
to losses; people also value something more when it is considered as
something that can be lost, as opposed to when it is considered as a
potential gain. Generally, the difference is a factor of 2 to 2.5.[14]
This is called the "endowment effect," and has been directly
demonstrated in many experiments. In one,[15] half of a group of
subjects were given a mug. Then, those who got a mug were asked the
price at which they were willing to sell it, and those who didn't get a
mug were asked what price they were willing to offer for one. Utility
theory predicts that both prices will be about the same, but in fact,
the median selling price was over twice the median offer.
In another experiment,[16] subjects were given either a pen or a mug
with a college logo, both of roughly equal value. (If you read enough
of these studies, you'll quickly notice two things. One, college
students are the most common test subject. And two, any necessary props
are most commonly purchased from a college bookstore.) Then the
subjects were offered the opportunity to exchange the item they received
for the other. If the subjects' preferences had nothing to do with the
item they received, the fraction of subjects keeping a mug should equal
the fraction of subjects exchanging a pen for a mug, and the fraction of
subjects keeping a pen should equal the fraction of subjects exchanging
a mug for a pen. In fact, most people kept the item they received; only
22% of subjects traded.
And, in general, most people will reject an even-chance gamble (50% of
winning, and 50% of losing) unless the possible win is at least twice
the size of the possible loss.[17]
What does prospect theory mean for security trade-offs? While I haven't
found any research that explicitly examines if people make security
trade-offs in the same way they make economic trade-offs, it seems
reasonable to me that they do at least in part. Given that, prospect
theory implies two things. First, it means that people are going to
trade off more for security that lets them keep something they've become
accustomed to -- a lifestyle, a level of security, some functionality in
a product or service -- than they were willing to risk to get it in the
first place. Second, when considering security gains, people are more
likely to accept an incremental gain than a chance at a larger gain; but
when considering security losses, they're more likely to risk a larger
loss than accept a larger gain.
Other Biases that Affect Risk
We have other heuristics and biases about risks. One common one is
called "optimism bias": we tend to believe that we'll do better than
most others engaged in the same activity. This bias is why we think car
accidents happen only to other people, and why we can at the same time
engage in risky behavior while driving and yet complain about others
doing the same thing. It's why we can ignore network security risks
while at the same time reading about other companies that have been
breached. It's why we think we can get by where others failed.
Basically, animals have evolved to underestimate loss. Because those
who experience the loss tend not to survive, those of us remaining have
an evolved experience that losses _don't_ happen and that it's okay to
take risks. In fact, some have theorized that people have a "risk
thermostat," and seek an optimal level of risk regardless of outside
circumstances.[18] By that analysis, if something comes along to reduce
risk -- seat belt laws, for example -- people will compensate by driving
more recklessly.
And it's not just that we don't think bad things can happen to us, we --
all things being equal -- believe that good outcomes are more probable
than bad outcomes. This bias has been repeatedly illustrated in all
sorts of experiments, but I think this one is particularly simple and
elegant.[19]
Subjects were shown cards, one after another, with either a cartoon
happy face or a cartoon frowning face. The cards were random, and the
subjects simply had to guess which face was on the next card before it
was turned over.
For half the subjects, the deck consisted of 70% happy faces and 30%
frowning faces. Subjects faced with this deck were very accurate in
guessing the face type; they were correct 68% of the time. The other
half was tested with a deck consisting of 30% happy faces and 70%
frowning faces. These subjects were much less accurate with their
guesses, only predicting the face type 58% of the time. Subjects'
preference for happy faces reduced their accuracy.
In a more realistic experiment,[20] students at Cook College were asked
"Compared to other Cook students -- the same sex as you -- what do you
think are the chances that the following events will happen to you?"
They were given a list of 18 positive and 24 negative events, like
getting a good job after graduation, developing a drinking problem, and
so on. Overall, they considered themselves 15% more likely than others
to experience positive events, and 20% less likely than others to
experience negative events.
The literature also discusses a "control bias," where people are more
likely to accept risks if they feel they have some control over them.
To me, this is simply a manifestation of the optimism bias, and not a
separate bias.
Another bias is the "affect heuristic," which basically says that an
automatic affective valuation -- I've seen it called "the emotional core
of an attitude" -- is the basis for many judgments and behaviors about
it. For example, a study of people's reactions to 37 different public
causes showed a very strong correlation between 1) the importance of the
issues, 2) support for political solutions, 3) the size of the donation
that subjects were willing to make, and 4) the moral satisfaction
associated with those donations.[21] The emotional reaction was a good
indicator of all of these different decisions.
With regard to security, the affect heuristic says that an overall good
feeling toward a situation leads to a lower risk perception, and an
overall bad feeling leads to a higher risk perception. This seems to
explain why people tend to underestimate risks for actions that also
have some ancillary benefit -- smoking, skydiving, and such -- but also
has some weirder effects.
In one experiment,[22] subjects were shown either a happy face, a
frowning face, or a neutral face, and then a random Chinese ideograph.
Subjects tended to prefer ideographs they saw after the happy face, even
though the face was flashed for only ten milliseconds and they had no
conscious memory of seeing it. That's the affect heuristic in action.
Another bias is that we are especially tuned to risks involving people.
Daniel Gilbert again:[23]
We are social mammals whose brains are highly specialized for
thinking about others. Understanding what others are up to --
what they know and want, what they are doing and planning --
has been so crucial to the survival of our species that our
brains have developed an obsession with all things human. We
think about people and their intentions; talk about them; look
for and remember them.
In one experiment,[24] subjects were presented data about different
risks occurring in state parks: risks from people, like purse snatching
and vandalism, and natural-world risks, like cars hitting deer on the
roads. Then, the subjects were asked which risk warranted more
attention from state park officials.
Rationally, the risk that causes the most harm warrants the most
attention, but people uniformly rated risks from other people as more
serious than risks from deer. Even if the data indicated that the risks
from deer were greater than the risks from other people, the
people-based risks were judged to be more serious. It wasn't until the
researchers presented the damage from deer as enormously higher than the
risks from other people that subjects decided it deserved more attention.
People are also especially attuned to risks involving their children.
This also makes evolutionary sense. There are basically two security
strategies life forms have for propagating their genes. The first, and
simplest, is to produce a lot of offspring and hope that some of them
survive. Lobsters, for example, can lay 10,000 to 20,000 eggs at a
time. Only ten to twenty of the hatchlings live to be four weeks old,
but that's enough. The other strategy is to produce only a few
offspring, and lavish attention on them. That's what humans do, and
it's what allows our species to take such a long time to reach maturity.
(Lobsters, on the other hand, grow up quickly.) But it also means
that we are particularly attuned to threats to our children, children in
general, and even other small and cute creatures.[25]
There is a lot of research on people and their risk biases.
Psychologist Paul Slovic seems to have made a career studying them.[26]
But most of the research is anecdotal, and sometimes the results seem
to contradict each other. I would be interested in seeing not only
studies about particular heuristics and when they come into play, but
how people deal with instances of contradictory heuristics. Also, I
would be very interested in research into how these heuristics affect
behavior in the context of a strong fear reaction: basically, when these
heuristics can override the amygdala and when they can't.
PROBABILITY HEURISTICS
The second area that can contribute to bad security trade-offs is
probability. If we get the probability wrong, we get the trade-off wrong.
Generally, we as a species are not very good at dealing with large
numbers. An enormous amount has been written about this, by John
Paulos[27] and others. The saying goes "1, 2, 3, many," but
evolutionarily it makes some amount of sense. Small numbers matter much
more than large numbers. Whether there's one mango or ten mangos is an
important distinction, but whether there are 1,000 or 5,000 matters less
-- it's a lot of mangos, either way. The same sort of thing happens
with probabilities as well. We're good at 1 in 2 vs. 1 in 4 vs. 1 in 8,
but we're much less good at 1 in 10,000 vs. 1 in 100,000. It's the same
joke: "half the time, one quarter of the time, one eighth of the time,
almost never." And whether whatever you're measuring occurs one time
out of ten thousand or one time out of ten million, it's really just the
same: almost never.
Additionally, there are heuristics associated with probabilities. These
aren't specific to risk, but contribute to bad evaluations of risk. And
it turns out that our brains' ability to quickly assess probability runs
into all sorts of problems.
The Availability Heuristic
The "availability heuristic" is very broad, and goes a long way toward
explaining how people deal with risk and trade-offs. Basically, the
availability heuristic means that people "assess the frequency of a
class or the probability of an event by the ease with which instances or
occurrences can be brought to mind." [28] In other words, in any
decision-making process, easily remembered (available) data are given
greater weight than hard-to-remember data.
In general, the availability heuristic is a good mental shortcut. All
things being equal, common events are easier to remember than uncommon
ones. So it makes sense to use availability to estimate frequency and
probability. But like all heuristics, there are areas where the
heuristic breaks down and leads to biases. There are reasons other than
occurrence that make some things more available. Events that have taken
place recently are more available than others. Events that are more
emotional are more available than others. Events that are more vivid
are more available than others. And so on.
There's nothing new about the availability heuristic and its effects on
security. I wrote about it in _Beyond Fear,_[29] although not by that
name. Sociology professor Barry Glassner devoted most of a book to
explaining how it affects our risk perception.[30] Every book on the
psychology of decision making discusses it.
In one simple experiment,[31] subjects were asked this question:
In a typical sample of text in the English language, is it
more likely that a word starts with the letter K or that K is
its third letter (not counting words with less than three
letters)?
Nearly 70% of people said that there were more words that started with
K, even though there are nearly twice as many words with K in the third
position as there are words that start with K. But since words that
start with K are easier to generate in one's mind, people overestimate
their relative frequency.
In another, more real-world, experiment,[32] subjects were divided into
two groups. One group was asked to spend a period of time imagining its
college football team doing well during the upcoming season, and the
other group was asked to imagine its college football team doing poorly.
Then, both groups were asked questions about the team's actual
prospects. Of the subjects who had imagined the team doing well, 63%
predicted an excellent season. Of the subjects who had imagined the
team doing poorly, only 40% did so.
The same researcher performed another experiment before the 1976
presidential election. Subjects asked to imagine Carter winning were
more likely to predict that he would win, and subjects asked to imagine
Ford winning were more likely to believe he would win. This kind of
experiment has also been replicated several times, and uniformly
demonstrates that considering a particular outcome in one's imagination
makes it appear more likely later.
The vividness of memories is another aspect of the availability
heuristic that has been studied. People's decisions are more affected
by vivid information than by pallid, abstract, or statistical information.
Here's just one of many experiments that demonstrates this.[33] In the
first part of the experiment, subjects read about a court case involving
drunk driving. The defendant had run a stop sign while driving home
from a party and collided with a garbage truck. No blood alcohol test
had been done, and there was only circumstantial evidence to go on. The
defendant was arguing that he was not drunk.
After reading a description of the case and the defendant, subjects were
divided into two groups and given eighteen individual pieces of evidence
to read: nine written by the prosecution about why the defendant was
guilty, and nine written by the defense about why the defendant was
innocent. Subjects in the first group were given prosecution evidence
written in a pallid style and defense evidence written in a vivid style,
while subjects in the second group were given the reverse.
For example, here is a pallid and vivid version of the same piece of
prosecution evidence:
* On his way out the door, Sanders [the defendant] staggers against a
serving table, knocking a bowl to the floor.
* On his way out the door, Sanders staggered against a serving table,
knocking a bowl of guacamole dip to the floor and splattering guacamole
on the white shag carpet.
And here's a pallid and vivid pair for the defense:
* The owner of the garbage truck admitted under cross-examination that
his garbage truck is difficult to see at night because it is grey in color.
* The owner of the garbage truck admitted under cross-examination that
his garbage truck is difficult to see at night because it is grey in
color. The owner said his trucks are grey "because it hides the dirt,"
and he said, "What do you want, I should paint them pink?"
After all of this, the subjects were asked about the defendant's
drunkenness level, his guilt, and what verdict the jury should reach.
The results were interesting. The vivid vs. pallid arguments had no
significant effect on the subject's judgment immediately after reading
them, but when they were asked again about the case 48 hours later --
they were asked to make their judgments as though they "were deciding
the case now for the first time" -- they were more swayed by the vivid
arguments. Subjects who read vivid defense arguments and pallid
prosecution arguments were much more likely to judge the defendant
innocent, and subjects who read the vivid prosecution arguments and
pallid defense arguments were much more likely to judge him guilty.
The moral here is that people will be persuaded more by a vivid,
personal story than they will by bland statistics and facts, possibly
solely due to the fact that they remember vivid arguments better.
Another experiment[34] divided subjects into two groups, who then read
about a fictional disease called "Hyposcenia-B." Subjects in the first
group read about a disease with concrete and easy-to-imagine symptoms:
muscle aches, low energy level, and frequent headaches. Subjects in the
second group read about a disease with abstract and difficult-to-imagine
symptoms: a vague sense of disorientation, a malfunctioning nervous
system, and an inflamed liver.
Then each group was divided in half again. Half of each half was the
control group: they simply read one of the two descriptions and were
asked how likely they were to contract the disease in the future. The
other half of each half was the experimental group: they read one of the
two descriptions "with an eye toward imagining a three-week period
during which they contracted and experienced the symptoms of the
disease," and then wrote a detailed description of how they thought they
would feel during those three weeks. And then they were asked whether
they thought they would contract the disease.
The idea here was to test whether the ease or difficulty of imagining
something affected the availability heuristic. The results showed that
those in the control group -- who read either the easy-to-imagine or
difficult-to-imagine symptoms, showed no difference. But those who were
asked to imagine the easy-to-imagine symptoms thought they were more
likely to contract the disease than the control group, and those who
were asked to imagine the difficult-to-imagine symptoms thought they
were less likely to contract the disease than the control group. The
researchers concluded that imagining an outcome alone is not enough to
make it appear more likely; it has to be something easy to imagine.
And, in fact, an outcome that is difficult to imagine may actually
appear to be less likely.
Additionally, a memory might be particularly vivid precisely because
it's extreme, and therefore unlikely to occur. In one experiment,[35]
researchers asked some commuters on a train platform to remember and
describe "the worst time you missed your train" and other commuters to
remember and describe "any time you missed your train." The incidents
described by both groups were equally awful, demonstrating that the most
extreme example of a class of things tends to come to mind when thinking
about the class.
More generally, this kind of thing is related to something called
"probability neglect": the tendency of people to ignore probabilities in
instances where there is a high emotional content.[36] Security risks
certainly fall into this category, and our current obsession with
terrorism risks at the expense of more common risks is an example.
The availability heuristic also explains hindsight bias. Events that
have actually occurred are, almost by definition, easier to imagine than
events that have not, so people retroactively overestimate the
probability of those events. Think of "Monday morning quarterbacking,"
exemplified both in sports and in national policy. "He should have seen
that coming" becomes easy for someone to believe.
The best way I've seen this all described is by Scott Plous:
In very general terms: (1) the more _available_ an event is,
the more frequent or probable it will seem; (2) the more
_vivid_ a piece of information is, the more easily recalled
and convincing it will be; and (3) the more _salient_
something is, the more likely it will be to appear causal.[37]
Here's one experiment that demonstrates this bias with respect to
salience.[38] Groups of six observers watched a two-man conversation
from different vantage points: either seated behind one of the men
talking or sitting on the sidelines between the two men talking.
Subjects facing one or the other conversants tended to rate that person
as more influential in the conversation: setting the tone, determining
what kind of information was exchanged, and causing the other person to
respond as he did. Subjects on the sidelines tended to rate both
conversants as equally influential.
As I said at the beginning of this section, most of the time the
availability heuristic is a good mental shortcut. But in modern
society, we get a lot of sensory input from the media. That screws up
availability, vividness, and salience, and means that heuristics that
are based on our senses start to fail. When people were living in
primitive tribes, if the idea of getting eaten by a saber-toothed tiger
was more available than the idea of getting trampled by a mammoth, it
was reasonable to believe that -- for the people in the particular place
they happened to be living -- it was more likely they'd get eaten by a
saber-toothed tiger than get trampled by a mammoth. But now that we get
our information from television, newspapers, and the Internet, that's
not necessarily the case. What we read about, what becomes vivid to us,
might be something rare and spectacular. It might be something
fictional: a movie or a television show. It might be a marketing
message, either commercial or political. And remember, visual media are
more vivid than print media. The availability heuristic is less
reliable, because the vivid memories we're drawing upon aren't relevant
to our real situation. And even worse, people tend not to remember
_where_ they heard something -- they just remember the content. So even
if, at the time they're exposed to a message they don't find the source
credible, eventually their memory of the source of the information
degrades and they're just left with the message itself.
We in the security industry are used to the effects of the availability
heuristic. It contributes to the "risk du jour" mentality we so often
see in people. It explains why people tend to overestimate rare risks
and underestimate common ones.[39] It explains why we spend so much
effort defending against what the bad guys did last time, and ignore
what new things they could do next time. It explains why we're worried
about risks that are in the news at the expense of risks that are not,
or rare risks that come with personal and emotional stories at the
expense of risks that are so common they are only presented in the form
of statistics.
It explains most of the entries in Table 1.
Representativeness
"Representativeness" is a heuristic by which we assume the probability
that an example belongs to a particular class is based on how well that
example represents the class. On the face of it, this seems like a
reasonable heuristic. But it can lead to erroneous results if you're
not careful.
The concept is a bit tricky, but here's an experiment makes this bias
crystal clear.[40] Subjects were given the following description of a
woman named Linda:
Linda is 31 years old, single, outspoken, and very bright.
She majored in philosophy. As a student, she was deeply
concerned with issues of discrimination and social justice,
and also participated in antinuclear demonstrations.
Then the subjects were given a list of eight statements describing her
present employment and activities. Most were decoys ("Linda is an
elementary school teacher," "Linda is a psychiatric social worker," and
so on), but two were critical: number 6 ("Linda is a bank teller," and
number 8 ("Linda is a bank teller and is active in the feminist
movement"). Half of the subjects were asked to rank the eight outcomes
by the similarity of Linda to the typical person described by the
statement, while others were asked to rank the eight outcomes by
probability.
Of the first group of subjects, 85% responded that Linda more resembled
a stereotypical feminist bank teller more than a bank teller. This
makes sense. But of the second group of subjects, 89% of thought Linda
was more likely to be a feminist bank teller than a bank teller.
Mathematically, of course, this is ridiculous. It is impossible for the
second alternative to be more likely than the first; the second is a
subset of the first.
As the researchers explain: "As the amount of detail in a scenario
increases, its probability can only decrease steadily, but its
representativeness and hence its apparent likelihood may increase. The
reliance on representativeness, we believe, is a primary reason for the
unwarranted appeal of detailed scenarios and the illusory sense of
insight that such constructions often provide."[41]
Doesn't this sound like how so many people resonate with movie-plot
threats -- overly specific threat scenarios -- at the expense of broader
risks?
In another experiment,[42] two groups of subjects were shown short
personality descriptions of several people, all of which were sampled
from a population of 100 engineers or lawyers. Here's a sample description:
Tom W. is of high intelligence, although lacking in true creativity. He
has a need for order and clarity, and for neat and tidy systems in which
every detail finds its appropriate place. His writing is rather dull
and mechanical, occasionally enlivened by somewhat corny puns and
flashes of imagination of the sci-fi type. He has a strong drive for
competence. He seems to have little feel and little sympathy for other
people and does not enjoy interacting with others. Self-centered, he
nonetheless has a deep moral sense.
Then, the subjects were asked to give a probability that each
description belonged to an engineer rather than a lawyer. One group of
subjects was told this about the population:
* Condition A: The population consisted of 70 engineers and 30 lawyers.
The second group of subjects was told this about the population:
* Condition B: The population consisted of 30 engineers and 70 lawyers.
Statistically, the probability that a particular description belongs to
an engineer rather than a lawyer should be much higher under Condition A
than Condition B. However, subjects judged the assignments to be the
same in either case. They were basing their judgments solely on the
stereotypical personality characteristics of engineers and lawyers, and
ignoring the relative probabilities of the two categories.
Interestingly, when subjects were not given any personality description
at all and simply asked for the probability that a random individual was
an engineer, they answered correctly: 70% under Condition A and 30%
under Condition B. But when they were given a neutral personality
description, one that didn't trigger either stereotype, they assigned
the description to an engineer 50% of the time under both Conditions A
and B.
And here's a third experiment. Subjects (college students) were given a
survey which included these two questions: "How happy are you with your
life in general?" and "How many dates did you have last month?" When
asked in this order, there was no correlation between the answers. But
when asked in the reverse order -- when the survey reminded the subjects
of how good (or bad) their love life was before asking them about their
life in general -- there was a 66% correlation.[43]
Representativeness also explains the base rate fallacy, where people
forget that if a particular characteristic is extremely rare, even an
accurate test for that characteristic will show false alarms far more
often than it will correctly identify the characteristic. Security
people run into this heuristic whenever someone tries to sell such
things as face scanning, profiling, or data mining as effective ways to
find terrorists.
And lastly, representativeness explains the "law of small numbers,"
where people assume that long-term probabilities also hold in the short
run. This is, of course, not true: if the results of three successive
coin flips are tails, the odds of heads on the fourth flip are not more
than 50%. The coin is not "due" to flip heads. Yet experiments have
demonstrated this fallacy in sports betting again and again.[44]
COST HEURISTICS
Humans have all sorts of pathologies involving costs, and this isn't the
place to discuss them all. But there are a few specific heuristics I
want to summarize, because if we can't evaluate costs right -- either
monetary costs or more abstract costs -- we're not going to make good
security trade-offs.
Mental Accounting
Mental accounting is the process by which people categorize different
costs.[45] People don't simply think of costs as costs; it's much more
complicated than that.
Here are the illogical results of two experiments.[46]
In the first, subjects were asked to answer one of these two questions:
* Trade-off 1: Imagine that you have decided to see a play where the
admission is $10 per ticket. As you enter the theater you discover that
you have lost a $10 bill. Would you still pay $10 for a ticket to the play?
* Trade-off 2: Imagine that you have decided to see a play where the
admission is $10 per ticket. As you enter the theater you discover that
you have lost the ticket. The seat is not marked and the ticket cannot
be recovered. Would you pay $10 for another ticket?
The results of the trade-off are exactly the same. In either case, you
can either see the play and have $20 less in your pocket, or not see the
play and have $10 less in your pocket. But people don't see these
trade-offs as the same. Faced with Trade-off 1, 88% of subjects said
they would buy the ticket anyway. But faced with Trade-off 2, only 46%
said they would buy a second ticket. The researchers concluded that
there is some sort of mental accounting going on, and the two different
$10 expenses are coming out of different mental accounts.
The second experiment was similar. Subjects were asked:
* Imagine that you are about to purchase a jacket for $125, and a
calculator for $15. The calculator salesman informs you that the
calculator you wish to buy is on sale for $10 at the other branch of the
store, located 20 minutes' drive away. Would you make the trip to the
other store?
* Imagine that you are about to purchase a jacket for $15, and a
calculator for $125. The calculator salesman informs you that the
calculator you wish to buy is on sale for $120 at the other branch of
the store, located 20 minutes drive away. Would you make the trip to
the other store?
Ignore your amazement at the idea of spending $125 on a calculator; it's
an old experiment. These two questions are basically the same: would
you drive 20 minutes to save $5? But while 68% of subjects would make
the drive to save $5 off the $15 calculator, only 29% would make the
drive to save $5 off the $125 calculator.
There's a lot more to mental accounting.[47] In one experiment,[48]
subjects were asked to imagine themselves lying on the beach on a hot
day and how good a cold bottle of their favorite beer would feel. They
were to imagine that a friend with them was going up to make a phone
call -- this was in 1985, before cell phones -- and offered to buy them
that favorite brand of beer if they gave the friend the money. What was
the most the subject was willing to pay for the beer?
Subjects were divided into two groups. In the first group, the friend
offered to buy the beer from a fancy resort hotel. In the second group,
the friend offered to buy the beer from a run-down grocery store. From
a purely economic viewpoint, that should make no difference. The value
of one's favorite brand of beer on a hot summer's day has nothing to do
with where it was purchased from. (In economic terms, the consumption
experience is the same.) But people were willing to pay $2.65 on
average for the beer from a fancy resort, but only $1.50 on average from
the run-down grocery store.
The experimenters concluded that people have reference prices in their
heads, and that these prices depend on circumstance. And because the
reference price was different in the different scenarios, people were
willing to pay different amounts. This leads to sub-optimal results.
As Thayer writes, "The thirsty beer-drinker who would pay $4 for a beer
from a resort but only $2 from a grocery store will miss out on some
pleasant drinking when faced with a grocery store charging $2.50."
Researchers have documented all sorts of mental accounting heuristics.
Small costs are often not "booked," so people more easily spend money on
things like a morning coffee. This is why advertisers often describe
large annual costs as "only a few dollars a day." People segregate
frivolous money from serious money, so it's easier for them to spend the
$100 they won in a football pool than a $100 tax refund. And people
have different mental budgets. In one experiment that illustrates
this,[49] two groups of subjects were asked if they were willing to buy
tickets to a play. The first group was told to imagine that they had
spent $50 earlier in the week on tickets to a basketball game, while the
second group was told to imagine that they had received a $50 parking
ticket earlier in the week. Those who had spent $50 on the basketball
game (out of the same mental budget) were significantly less likely to
buy the play tickets than those who spent $50 paying a parking ticket (
out o
f a different mental budget).
One interesting mental accounting effect can be seen at race tracks.[50]
Bettors tend to shift their bets away from favorites and towards long
shots at the end of the day. This has been explained by the fact that
the average bettor is behind by the end of the day -- pari-mutuel
betting means that the average bet is a loss -- and a long shot can put
a bettor ahead for the day. There's a "day's bets" mental account, and
bettors don't want to close it in the red.
The effect of mental accounting on security trade-offs isn't clear, but
I'm certain we have a mental account for "safety" or "security," and
that money spent from that account feels different than money spent from
another account. I'll even wager we have a similar mental accounting
model for non-fungible costs such as risk: risks from one account don't
compare easily with risks from another. That is, we are willing to
accept considerable risks in our leisure account -- skydiving, knife
juggling, whatever -- when we wouldn't even consider them if they were
charged against a different account.
Time Discounting
"Time discounting" is the term used to describe the human tendency to
discount future costs and benefits. It makes economic sense; a cost
paid in a year is not the same as a cost paid today, because that money
could be invested and earn interest during the year. Similarly, a
benefit accrued in a year is worth less than a benefit accrued today.
Way back in 1937, economist Paul Samuelson proposed a discounted-utility
model to explain this all. Basically, something is worth more today
than it is in the future. It's worth more to you to have a house today
than it is to get it in ten years, because you'll have ten more years'
enjoyment of the house. Money is worth more today than it is years from
now; that's why a bank is willing to pay you to store it with them.
The discounted utility model assumes that things are discounted
according to some rate. There's a mathematical formula for calculating
which is worth more -- $100 today or $120 in twelve months -- based on
interest rates. Today, for example, the discount rate is 6.25%, meaning
that $100 today is worth the same as $106.25 in twelve months. But of
course, people are much more complicated than that.
There is, for example, a magnitude effect: smaller amounts are
discounted more than larger ones. In one experiment, [51] subjects were
asked to choose between an amount of money today or a greater amount in
a year. The results would make any banker shake his head in wonder.
People didn't care whether they received $15 today or $60 in twelve
months. At the same time, they were indifferent to receiving $250 today
or $350 in twelve months, and $3,000 today or $4,000 in twelve months.
If you do the math, that implies a discount rate of 139%, 34%, and 29%
-- all held simultaneously by subjects, depending on the initial dollar
amount.
This holds true for losses as well,[52] although gains are discounted
more than losses. In other words, someone might be indifferent to $250
today or $350 in twelve months, but would much prefer a $250 penalty
today to a $350 penalty in twelve months. Notice how time discounting
interacts with prospect theory here.
Also, preferences between different delayed rewards can flip, depending
on the time between the decision and the two rewards. Someone might
prefer $100 today to $110 tomorrow, but also prefer $110 in 31 days to
$100 in thirty days.
Framing effects show up in time discounting, too. You can frame
something either as an acceleration or a delay from a base reference
point, and that makes a big difference. In one experiment,[53] subjects
who expected to receive a VCR in twelve months would pay an average of
$54 to receive it immediately, but subjects who expected to receive the
VCR immediately demanded an average $126 discount to delay receipt for a
year. This holds true for losses as well: people demand more to
expedite payments than they would pay to delay them.[54]
Reading through the literature, it sometimes seems that discounted
utility theory is full of nuances, complications, and contradictions.
But clearly there is some mental discounting going on; it's just not
anywhere near linear, and not easily formularized.
HEURISTICS THAT AFFECT DECISIONS
And finally, there are biases and heuristics that affect trade-offs.
Like many other heuristics we've discussed, they're general, and not
specific to security. But they're still important.
First, some more framing effects.
Most of us have anecdotes about what psychologists call the "context
effect": preferences among a set of options depend on what other options
are in the set. This has been confirmed in all sorts of experiments --
remember the experiment about what people were willing to pay for a cold
beer on a hot beach -- and most of us have anecdotal confirmation of
this heuristic.
For example, people have a tendency to choose options that dominate
other options, or compromise options that lie between other options. If
you want your boss to approve your $1M security budget, you'll have a
much better chance of getting that approval if you give him a choice
among three security plans -- with budgets of $500K, $1M, and $2M,
respectively -- than you will if you give him a choice among three plans
with budgets of $250K, $500K, and $1M.
The rule of thumb makes sense: avoid extremes. It fails, however, when
there's an intelligence on the other end, manipulating the set of
choices so that a particular one doesn't seem extreme.
"Choice bracketing" is another common heuristic. In other words: choose
a variety. Basically, people tend to choose a more diverse set of goods
when the decision is bracketed more broadly than they do when it is
bracketed more narrowly. For example, [55] in one experiment students
were asked to choose among one of six different snacks that they would
receive at the beginning of the next three weekly classes. One group
had to choose the three weekly snacks in advance, while the other group
chose at the beginning of each class session. Of the group that chose
in advance, 64% chose a different snack each week, but only 9% of the
group that chose each week did the same.
The narrow interpretation of this experiment is that we overestimate the
value of variety. Looking ahead three weeks, a variety of snacks seems
like a good idea, but when we get to the actual time to enjoy those
snacks, we choose the snack we like. But there's a broader
interpretation as well, one borne out by similar experiments and
directly applicable to risk taking: when faced with repeated risk
decisions, evaluating them as a group makes them feel less risky than
evaluating them one at a time. Back to finance, someone who rejects a
particular gamble as being too risky might accept multiple identical
gambles.
Again, the results of a trade-off depend on the context of the trade-off.
It gets even weirder. Psychologists have identified an "anchoring
effect," whereby decisions are affected by random information
cognitively nearby. In one experiment[56], subjects were shown the spin
of a wheel whose numbers ranged from 0 and 100, and asked to guess
whether the number of African nations in the UN was greater or less than
that randomly generated number. Then, they were asked to guess the
exact number of African nations in the UN.
Even though the spin of the wheel was random, and the subjects knew it,
their final guess was strongly influenced by it. That is, subjects who
happened to spin a higher random number guessed higher than subjects
with a lower random number.
Psychologists have theorized that the subjects anchored on the number in
front of them, mentally adjusting it for what they thought was true. Of
course, because this was just a guess, many people didn't adjust
sufficiently. As strange as it might seem, other experiments have
confirmed this effect.
And if you're not completely despairing yet, here's another experiment
that will push you over the edge.[57] In it, subjects were asked one of
these two questions:
* Question 1: Should divorce in this country be easier to obtain, more
difficult to obtain, or stay as it is now?
* Question 2: Should divorce in this country be easier to obtain, stay
as it is now, or be more difficult to obtain?
In response to the first question, 23% of the subjects chose easier
divorce laws, 36% chose more difficult divorce laws, and 41% said that
the status quo was fine. In response to the second question, 26% chose
easier divorce laws, 46% chose more difficult divorce laws, and 29%
chose the status quo. Yes, the order in which the alternatives are
listed affects the results.
There are lots of results along these lines, including the order of
candidates on a ballot.
Another heuristic that affects security trade-offs is the "confirmation
bias." People are more likely to notice evidence that supports a
previously held position than evidence that discredits it. Even worse,
people who support position A sometimes mistakenly believe that anti-A
evidence actually supports that position. There are a lot of
experiments that confirm this basic bias and explore its complexities.
If there's one moral here, it's that individual preferences are not
based on predefined models that can be cleanly represented in the sort
of indifference curves you read about in microeconomics textbooks; but
instead, are poorly defined, highly malleable, and strongly dependent on
the context in which they are elicited. Heuristics and biases matter.
A lot.
This all relates to security because it demonstrates that we are not
adept at making rational security trade-offs, especially in the context
of a lot of ancillary information designed to persuade us one way or
another.
MAKING SENSE OF THE PERCEPTION OF SECURITY
We started out by teasing apart the security trade-off, and listing five
areas where perception can diverge from reality:
1. The severity of the risk.
2. The probability of the risk.
3. The magnitude of the costs.
4. How effective the countermeasure is at mitigating the risk.
5. The trade-off itself.
Sometimes in all the areas, and all the time in area 4, we can explain
this divergence as a consequence of not having enough information. But
sometimes we have all the information and _still_ make bad security
trade-offs. My aim was to give you a glimpse of the complicated brain
systems that make these trade-offs, and how they can go wrong.
Of course, we can make bad trade-offs in anything: predicting what snack
we'd prefer next week or not being willing to pay enough for a beer on a
hot day. But security trade-offs are particularly vulnerable to these
biases because they are so critical to our survival. Long before our
evolutionary ancestors had the brain capacity to consider future snack
preferences or a fair price for a cold beer, they were dodging predators
and forging social ties with others of their species. Our brain
heuristics for dealing with security are old and well-worn, and our
amygdalas are even older.
What's new from an evolutionary perspective is large-scale human
society, and the new security trade-offs that come with it. In the past
I have singled out technology and the media as two aspects of modern
society that make it particularly difficult to make good security
trade-offs -- technology by hiding detailed complexity so that we don't
have the right information about risks, and the media by producing such
available, vivid, and salient sensory input -- but the issue is really
broader than that. The neocortex, the part of our brain that has to
make security trade-offs, is, in the words of Daniel Gilbert, "still in
beta testing."
I have just started exploring the relevant literature in behavioral
economics, the psychology of decision making, the psychology of risk,
and neuroscience. Undoubtedly there is a lot of research out there for
me still to discover, and more fascinatingly counterintuitive
experiments that illuminate our brain heuristics and biases. But
already I understand much more clearly why we get security trade-offs so
wrong so often.
When I started reading about the psychology of security, I quickly
realized that this research can be used both for good and for evil. The
good way to use this research is to figure out how humans' feelings of
security can better match the reality of security. In other words, how
do we get people to recognize that they need to question their default
behavior? Giving them more information seems not to be the answer;
we're already drowning in information, and these heuristics are not
based on a lack of information. Perhaps by understanding how our brains
processes risk, and the heuristics and biases we use to think about
security, we can learn how to override our natural tendencies and make
better security trade-offs. Perhaps we can learn how not to be taken in
by security theater, and how to convince others not to be taken in by
the same.
The evil way is to focus on the feeling of security at the expense of
the reality. In his book _Influence,_[58] Robert Cialdini makes the
point that people can't analyze every decision fully; it's just not
possible: people need heuristics to get through life. Cialdini
discusses how to take advantage of that; an unscrupulous person,
corporation, or government can similarly take advantage of the
heuristics and biases we have about risk and security. Concepts of
prospect theory, framing, availability, representativeness, affect, and
others are key issues in marketing and politics. They're applied
generally, but in today's world they're more and more applied to
security. Someone could use this research to simply make people _feel_
more secure, rather than to actually make them more secure.
After all my reading and writing, I believe my good way of using the
research is unrealistic, and the evil way is unacceptable. But I also
see a third way: integrating the feeling and reality of security.
The feeling and reality of security are different, but they're closely
related. We make the best security trade-offs -- and by that I mean
trade-offs that give us genuine security for a reasonable cost -- when
our feeling of security matches the reality of security. It's when the
two are out of alignment that we get security wrong.
In the past, I've criticized palliative security measures that only make
people _feel_ more secure as "security theater." But used correctly,
they can be a way of raising our feeling of security to more closely
match the reality of security. One example is the tamper-proof
packaging that started to appear on over-the-counter drugs in the 1980s,
after a few highly publicized random poisonings. As a countermeasure,
it didn't make much sense. It's easy to poison many foods and
over-the-counter medicines right through the seal -- with a syringe, for
example -- or to open and reseal the package well enough that an unwary
consumer won't detect it. But the tamper-resistant packaging brought
people's perceptions of the risk more in line with the actual risk:
minimal. And for that reason the change was worth it.
Of course, security theater has a cost, just like real security. It can
cost money, time, capabilities, freedoms, and so on, and most of the
time the costs far outweigh the benefits. And security theater is no
substitute for real security. Furthermore, too much security theater
will raise people's feeling of security to a level greater than the
reality, which is also bad. But used in conjunction with real security,
a bit of well-placed security theater might be exactly what we need to
both be and feel more secure.

[1] Bruce Schneier, _Beyond Fear: Thinking Sensibly About Security in an
Uncertain World,_ Springer-Verlag, 2003.
[2] David Ropeik and George Gray, _Risk: A Practical Guide for Deciding
What's Really Safe and What's Really Dangerous in the World Around You,_
Houghton Mifflin, 2002.
[3] Barry Glassner, _The Culture of Fear: Why Americans are Afraid of
the Wrong Things,_ Basic Books, 1999.
[4] Paul Slovic, _The Perception of Risk,_ Earthscan Publications Ltd, 2000.
[5] Daniel Gilbert, "If only gay sex caused global warming," _Los
Angeles Times,_ 2 Jul 2006.
[6] Jeffrey Kluger, "How Americans Are Living Dangerously," _Time,_ 26
Nov 2006.
[7] Steven Johnson, _Mind Wide Open: Your Brain and the Neuroscience of
Everyday Life,_ Scribner, 2004.
[8] Daniel Gilbert, "If only gay sex caused global warming," _Los
Angeles Times,_ July 2, 2006.
[9] Donald A. Norman, "Being Analog,"
http://www.jnd.org/dn.mss/being_analog.html. Originally published as
Chapter 7 of _The Invisible Computer,_ MIT Press, 1998.
[10] Daniel Kahneman, "A Perspective on Judgment and Choice," _American
Psychologist,_ 2003, 58:9, 697-720.
[11] Gerg Gigerenzer, Peter M. Todd, et al., _Simple Heuristics that
Make us Smart,_ Oxford University Press, 1999.
[12] Daniel Kahneman and Amos Tversky, "Prospect Theory: An Analysis of
Decision Under Risk," _Econometrica,_ 1979, 47:263-291.
[13] Amos Tversky and Daniel Kahneman, "The Framing of Decisions and the
Psychology of Choice," _Science,_ 1981, 211: 453-458.
[14] Amos Tversky and Daniel Kahneman, "Evidential Impact of Base
Rates," in Daniel Kahneman, Paul Slovic, and Amos Tversky (eds.),
_Judgment Under Uncertainty: Heuristics and Biases,_ Cambridge
University Press, 1982, pp. 153-160.
[15] Daniel J. Kahneman, Jack L. Knetsch, and R.H. Thaler, "Experimental
Tests of the Endowment Effect and the Coase Theorem," _Journal of
Political Economy,_ 1990, 98: 1325-1348.
[16] Jack L. Knetsch, "Preferences and Nonreversibility of Indifference
Curves," _Journal of Economic Behavior and Organization,_ 1992, 17: 131-139.
[17] Amos Tversky and Daniel Kahneman, "Advances in Prospect Theory:
Cumulative Representation of Subjective Uncertainty," _Journal of Risk
and Uncertainty,_ 1992, 5:xx, 297-323.
[18] John Adams, "Cars, Cholera and Cows," ((citation)).
[19] David L. Rosenhan and Samuel Messick, "Affect and Expectation,"
_Journal of Personality and Social Psychology,_ 1966, 3: 38-44.
[20] Neil D. Weinstein, "Unrealistic Optimism about Future Life Events,"
_Journal of Personality and Social Psychology,_ 1980, 39: 806-820.
[21] D. Kahneman, I. Ritov, and D. Schkade, "Economic preferences or
attitude expressions? An analysis of dollar responses to public
issues," _Journal of Risk and Uncertainty,_ 1999, 19:220-242.
[22] P. Winkielman, R.B. Zajonc, and N. Schwarz, "Subliminal affective
priming attributional interventions," _Cognition and Emotion,_ 1977,
11:4, 433-465.
[23] Daniel Gilbert, "If only gay sex caused global warming," _Los
Angeles Times,_ July 2, 2006.
[24] Robyn S. Wilson and Joseph L. Arvai, "When Less is More: How Affect
Influences Preferences When Comparing Low-risk and High-risk Options,"
_Journal of Risk Research,_ 2006, 9:2, 165-178.
[25] J. Cohen, _The Privileged Ape: Cultural Capital in the Making of
Man,_ Parthenon Publishing Group, 1989.
[26] Paul Slovic, _The Perception of Risk,_ Earthscan Publications Ltd,
2000.
[27] John Allen Paulos, _Innumeracy: Mathematical Illiteracy and Its
Consequences,_ Farrar, Straus, and Giroux, 1988.
[28] Amos Tversky and Daniel Kahneman, "Judgment under Uncertainty:
Heuristics and Biases," _Science,_ 1974, 185:1124-1130.
[29] Bruce Schneier,_ Beyond Fear: Thinking Sensibly About Security in
an Uncertain World,_ Springer-Verlag, 2003.
[30] Barry Glassner, _The Culture of Fear: Why Americans are Afraid of
the Wrong Things,_ Basic Books, 1999.
[31] Amos Tversky and Daniel Kahneman, "Availability: A Heuristic for
Judging Frequency," _Cognitive Psychology,_ 1973, 5:207-232.
[32] John S. Carroll, "The Effect of Imagining an Event on Expectations
for the Event: An Interpretation in Terms of the Availability
Heuristic," _Journal of Experimental Social Psychology,_ 1978, 14:88-96.
[33] Robert M. Reyes, William C. Thompson, and Gordon H. Bower,
"Judgmental Biases Resulting from Differing Availabilities of
Arguments," _Journal of Personality and Social Psychology,_ 1980, 39:2-12.
[34] S. Jim Sherman, Robert B. Cialdini, Donna F. Schwartzman, and Kim
D. Reynolds, "Imagining Can Heighten or Lower the Perceived Likelihood
of Contracting a Disease: The Mediating Effect of Ease of Imagery,"
_Personality and Social Psychology Bulletin,_ 1985, 11:118-127.
[35] C. K. Morewedge, D.T. Gilbert, and T.D. Wilson, "The Least Likely
of Times: How Memory for Past Events Biases the Prediction of Future
Events," _Psychological Science,_ 2005, 16:626-630.
[36] Cass R. Sunstein, "Terrorism and Probability Neglect," _Journal of
Risk and Uncertainty_, 2003, ((volume and page numbers)).
[37] Scott Plous, _The Psychology of Judgment and Decision Making,_
McGraw-Hill, 1993.
[38] S.E. Taylor and S.T. Fiske, "Point of View and Perceptions of
Causality," _Journal of Personality and Social Psychology,_ 1975, 32:
439-445.
[39] Paul Slovic, Baruch Fischhoff, and Sarah Lichtenstein, "Rating the
Risks," _Environment,_ 1979, 2: 14-20, 36-39.
[40] Amos Tversky and Daniel Kahneman, "Extensional vs Intuitive
Reasoning: The Conjunction Fallacy in Probability Judgment,"
_Psychological Review,_ 1983, 90:??, 293-315.
[41] Amos Tversky and Daniel Kahneman, "Judgments of and by
Representativeness," in Daniel Kahneman, Paul Slovic, and Amos Tversky
(eds.), _Judgment Under Uncertainty: Heuristics and Biases,_ Cambridge
University Press, 1982.
[42] Daniel Kahneman and Amos Tversky, "On the Psychology of
Prediction," _Psychological Review_, 1973, 80: 237-251.
[43] Daniel Kahneman and S. Frederick, "Representativeness Revisited:
Attribute Substitution in Intuitive Judgement," in T. Gilovich, D.
Griffin, and D. Kahneman (eds.), _Heuristics and Biases, _Cambridge
University Press_,_ 2002, pp. 49-81.
[44] Thomas Gilovich, Robert Vallone, and Amos Tversky, "The Hot Hand in
Basketball: On the Misperception of Random Sequences," _Cognitive
Psychology,_ 1985, 17: 295-314.
[45] Richard H. Thaler, "Toward a Positive Theory of Consumer Choice,"
_Journal of Economic Behavior and Organization,_ 1980, 1:39-60.
[46] Amos Tversky and Daniel Kahneman, "The Framing of Decisions and the
Psychology of Choice," _Science,_ 1981, 211:253:258.
[47] Richard Thayer, "Mental Accounting Matters," in Colin F. Camerer,
George Loewenstein, and Matthew Rabin, eds., _Advances in Behavioral
Economics,_ Princeton University Press, 2004.
[48] Richard Thayer, "Mental Accounting and Consumer Choice," _Marketing
Science,_ 1985, 4:199-214.
[49] Chip Heath and Jack B. Soll, "Mental Accounting and Consumer
Decisions," _Journal of Consumer Research,_ 1996, 23:40-52.
[50] Muhtar Ali, "Probability and Utility Estimates for Racetrack
Bettors," _Journal of Political Economy,_ 1977, 85:803-815.
[51] Richard Thayer, "Some Empirical Evidence on Dynamic Inconsistency,"
_Economics Letters,_ 1981, 8: 201-207.
[52] George Loewenstein and Drazen Prelec, "Anomalies in Intertemporal
Choice: Evidence and Interpretation," _Quarterly Journal of Economics,_
1992, 573-597.
[53] George Loewenstein, "Anticipation and the Valuation of Delayed
Consumption," _Economy Journal,_ 1987, 97: 666-684.
[54] Uri Benzion, Amnon Rapoport, and Joseph Yagel, "Discount Rates
Inferred from Decisions: An Experimental Study," _Management Science,_
1989, 35:270-284.
[55] Itamer Simonson, "The Effect of Purchase Quantity and Timing on
Variety-Seeking Behavior," _Journal of Marketing Research,_ 1990,
17:150-162.
[56] Amos Tversky and Daniel Kahneman, "Judgment under Uncertainty:
Heuristics and Biases," _Science,_ 1974,_ _185: 1124-1131.
[57] Howard Schurman and Stanley Presser, _Questions and Answers in
Attitude Surveys: Experiments on Wording Form, Wording, and Context,_
Academic Press, 1981.
[58] Robert B. Cialdini, _Influence: The Psychology of Persuasion,_
HarperCollins, 1998.

** *** ***** ******* *********** *************
Comments from Readers


I am very interested in comments on this draft essay. It's a work in
progress, and I would very much appreciate any and all comments,
criticisms, additions, corrections, suggestions for further research,
and so on. I think security technology has a lot to learn from
psychology, and that I've only scratched the surface of the interesting
and relevant research -- and what it means.
I posted a previous draft of this essay on my blog on February 6th. At
this writing, there are 105 comments. Please add yours to the mix.
http://www.schneier.com/blog/archives/2007/02/the_psychology_2.html

** *** ***** ******* *********** *************
CRYPTO-GRAM is a free monthly newsletter providing summaries, analyses,
insights, and commentaries on security: computer and otherwise. You can
subscribe, unsubscribe, or change your address on the Web at
<http://www.schneier.com/crypto-gram.html>. Back issues are also
available at that URL.
Please feel free to forward CRYPTO-GRAM, in whole or in part, to
colleagues and friends who will find it valuable. Permission is also
granted to reprint CRYPTO-GRAM, as long as it is reprinted in its entirety.
CRYPTO-GRAM is written by Bruce Schneier. Schneier is the author of the
best sellers "Beyond Fear," "Secrets and Lies," and "Applied
Cryptography," and an inventor of the Blowfish and Twofish algorithms.
He is founder and CTO of BT Counterpane, and is a member of the Board of
Directors of the Electronic Privacy Information Center (EPIC). He is a
frequent writer and lecturer on security topics. See
<http://www.schneier.com>.
BT Counterpane is the world's leading protector of networked information
- the inventor of outsourced security monitoring and the foremost
authority on effective mitigation of emerging IT threats. BT
Counterpane protects networks for Fortune 1000 companies and governments
world-wide. See <http://www.counterpane.com>.
Crypto-Gram is a personal newsletter. Opinions expressed are not
necessarily those of BT or BT Counterpane.
Copyright (c) 2007 by Bruce Schneier.

Data breach law could put financial burden on retailers

Data breach law could put financial burden on retailers