The field-guide-to-data-science

THE FIELD GUIDE
to D A T A S C I E N C E
© COPYRIGHT 2013 BOOZ ALLEN HAMILTON INC. ALL RIGHTS RESERVED.

FOREWORD
Every aspect of our lives, from life-saving disease
treatments, to national security, to economic stability
and even the convenience of selecting a restaurant,
can be improved by creating better data analytics
through Data Science.
We live in a world of incredible
beauty and complexity. A world
increasingly measured, mapped,
and recorded into digital bits for
eternity. Our human existence
is pouring into the digital realm
faster than ever. From global
business operations to simple
expressions of love – an essential
part of humanity now exists in
the digital world.
Data is the byproduct of our
new digital existence. Recorded
bits of data from mundane
traffic cameras to telescopes
peering into the depths of
space are propelling us into
the greatest age of discovery
our species has ever known.
As we move from isolation into
our ever-connected and recorded
future, data is becoming the
new currency and a vital natural
resource.The power, importance,
and responsibility such incredible
data stewardship will demand of
us in the coming decades is hard
to imagine – but we often fail to
fully appreciate the insights data
can provide us today. Businesses
that do not rise to the occasion
and garner insights from this new
resource are destined for failure.
An essential part of human
nature is our insatiable curiosity
and the need to find answers to
our hardest problems.Today, the
emerging field of Data Science is
an auspicious and profound new
way of applying our curiosity
and technical tradecraft to create
value from data that solves our
hardest problems. Leaps in
human imagination, vast amounts
of data on hundreds of topics,
and humble algorithms can be
combined to create a radical new
way of thinking about data. Our
future is inextricably tied to data.
We want to share our passion for Data Science and start a
conversation with you. This is a journey worth taking.
››

Everyone you
will ever meet
knows something
you don’t. [1]

THE STORY of T H E
F I E L D
G U I D EWhile there are countless industry and academic publications
describing what Data Science is and why we should care, little
information is available to explain how to make use of data as a
resource. At Booz Allen, we built an industry-leading team of
Data Scientists. Over the course of hundreds of analytic
challenges for dozens of clients, we’ve unraveled the DNA of
Data Science. We mapped the Data Science DNA to unravel the
what, the why, the who and the how.
Many people have put forth their thoughts on single aspects of
Data Science. We believe we can offer a broad perspective on the
conceptual models, tradecraft, processes and culture of Data
Science. Companies with strong Data Science teams often focus
on a single class of problems – graph algorithms for social
network analysis and recommender models for online shopping
are two notable examples. Booz Allen is different. In our role as
consultants, we support a diverse set of clients across a variety of
domains.This allows us to uniquely understand the DNA of
Data Science. Our goal in creating The Field Guide to Data Science
is to capture what we have learned and to share it broadly.
We want this effort to help drive forward the science and art
of Data Science.
This field guide came from the passion our team feels for
its work. It is not a textbook nor is it a superficial treatment.
Senior leaders will walk away with a deeper understanding
of the concepts at the heart of Data Science. Practitioners
will add to their toolbox. We hope everyone will enjoy
the journey.
»Why Data Science DNA?
We view Data Science as having
DNA-like characteristics. Much like
DNA, Data Science is composed
of basic building blocks that are
woven into a thing of great beauty
and complexity. The building blocks
create the blueprint, but successful
replication also requires carefully
balanced processes and the right
set of environmental conditions.
In the end, every instance may look
superficially different, but the raw
materials remain the same.
››

WE ARE ALL
AUTHORS of T H I S
S T O R Y
We recognize that Data Science is a team sport. The Field Guide
to Data Science provides Booz Allen’s perspective on the complex
and sometimes mysterious field of Data Science. We cannot
capture all that is Data Science. Nor can we keep up - the pace at
which this field progresses outdates work as fast as it is produced.
As a result, we have opened this field guide to the world as a
living document to bend and grow with technology, expertise, and
evolving techniques. If you find the guide to be useful, neat, or even
lacking, then we encourage you to add your expertise, including:
› Case studies from which you have learned
› Citations for journal articles or papers that inspire you
› Algorithms and techniques that you love
› Your thoughts and comments on other people’s additions
Email us your ideas and perspectives at data_science@bah.com
or submit them via a pull request on the Github repository.
Join our conversation and take the journey with us. Tell us and
the world what you know. Become an author of this story.
››

THE OUTLINE
of O U R S T O R Y
10 ›› Meet Your Guides
13 ›› The Short Version – The Core Concepts of Data Science
14 ›› Start Here for the Basics – An Introduction to Data Science
What Do We Mean by Data Science?
How Does Data Science Actually Work?
What Does It Take to Create a Data Science Capability?
40 ›› Take off the Training Wheels – The Practitioner’s Guide to Data Science
Guiding Principles
The Importance of Reason
Component Parts of Data Science
Fractal Analytic Model
The Analytic Selection Process
Guide to Analytic Selection
Detailed Table of Analytics
76 ›› Life in the Trenches – Navigating Neck Deep in Data
Feature Engineering
Feature Selection
Data Veracity
Application of Domain Knowledge
The Curse of Dimensionality
Model Validation
90 ›› Putting it all Together – Our Case Studies
Consumer Behavior Analysis from a Multi-Terabyte Data Set
Strategic Insights with Terabytes of Passenger Data
Savings Through Better Manufacturing
Realizing Higher Returns Through Predictive Analytics
100 ›› Closing Time
Parting Thoughts
References
About Booz Allen Hamilton
››

MEET your G U I D E S
Mark Herman
(@cloudEBITDA)
End every analysis with …
‘and therefore’
Josh Sullivan
(@joshdsullivan)
Leading our Data Science team
shows me every day the incredible
power of discovery and human
curiosity. Don’t be afraid to blend
art and science to advance your
own view of data analytics – it
can be a powerful mixture.
Stephanie Rivera
(@boozallen)
I treat Data Science like I do rock
climbing: awesome dedication
leads to incremental improvement.
Persistence leads to the top.
Peter Guerra
(@petrguerra)
Data Science is the most fascinating
blend of art and math and code
and sweat and tears. It can take
you to the highest heights and the
lowest depths in an instant, but it
is the only way we will be able to
understand and describe the why.

Steven Mills
(@stevndmills)
Data Science, like life, is not linear.
It’s complex, intertwined, and can be
beautiful. Success requires the support
of your friends and colleagues.
Alex Cosmas
(@boozallen)
Data miners produce bottle cap facts
(e.g., animals that lay eggs don’t have
belly buttons). Data Scientists produce
insights - they require the intellectual
curiosity to ask “why” or “so what”?
››
THE FIELD GUIDE to D ATA S C I E N C E

Drew Farris
(@drewfarris)
Don’t forget to play. Play with
tools, play with data, and play with
algorithms. You just might discover
something that will help you solve
that next nagging problem.
Brian Keller
(@boozallen)
Grit will get you farther than talent.
Ed Kohlwey
(@ekohlwey)
Data Science is about formally
analyzing everything around you
and becoming data driven.
Armen Kherlopian
(@akherlopian)
A Data Scientist must
continuously seek truth in spite
of ambiguity; therein rests the
basis of rigor and insight.
Paul Yacci
(@paulyacci)
In the jungle of data, don’t
miss the forest for the trees,
or the trees for the forest.
Michael Kim
(@boozallen)
Data science is both an art
and science.
We would like to thank the following people for their
contributions and edits:
Tim Andrews, Mike Delurey, Greg Dupier, Jason Escaravage,
Christine Fantaskey, Juergen Klenk, and Mark Rockley.
11Meet Your Guides

The SHORT
V E R S I O N
› Data Science is the art of turning data into actions.
It’s all about the tradecraft.Tradecraft is the process, tools and
technologies for humans and computers to work together to
transform data into insights.
› Data Science tradecraft creates data products.
Data products provide actionable information without exposing
decision makers to the underlying data or analytics (e.g., buy/sell
strategies for financial instruments, a set of actions to improve
product yield, or steps to improve product marketing).
› Data Science supports and encourages shifting between
deductive (hypothesis-based) and inductive (pattern-
based) reasoning.
This is a fundamental change from traditional analysis approaches.
Inductive reasoning and exploratory data analysis provide a means
to form or refine hypotheses and discover new analytic paths.
Models of reality no longer need to be static.They are constantly
tested, updated and improved until better models are found.
› Data Science is necessary for companies to stay with the
pack and compete in the future.
Organizations are constantly making decisions based on gut
instinct, loudest voice and best argument – sometimes they are
even informed by real information.The winners and the losers in
the emerging data economy are going to be determined by their
Data Science teams.
› Data Science capabilities can be built over time.
Organizations mature through a series of stages – Collect,
Describe, Discover, Predict, Advise – as they move from data
deluge to full Data Science maturity. At each stage, they can
tackle increasingly complex analytic goals with a wider breadth
of analytic capabilities. However, organizations need not reach
maximum Data Science maturity to achieve success. Significant
gains can be found in every stage.
› Data Science is a different kind of team sport.
Data Science teams need a broad view of the organization. Leaders
must be key advocates who meet with stakeholders to ferret out
the hardest challenges, locate the data, connect disparate parts of
the business, and gain widespread buy-in.
››
13The Short Version 13

AN INTRODUCTION TO DATA SCIENCE
If you haven’t heard of Data Science, you’re behind the
times. Just renaming your Business Intelligence group
the Data Science group is not the solution.
START HERE for T H E B A S I C S

What do We Mean by
Data Science?
Describing Data Science is like trying to describe a sunset – it
should be easy, but somehow capturing the words is impossible.

17Start Here for the Basics 17Start Here for the Basics
Data Science Defined
Data Science is the art of turning data into actions.This is
accomplished through the creation of data products, which provide
actionable information without exposing decision makers to the
underlying data or analytics (e.g., buy/sell strategies for financial
instruments, a set of actions to improve product yield, or steps to
improve product marketing).
Performing Data Science requires the extraction of timely, actionable
information from diverse data sources to drive data products.
Examples of data products include answers to questions such as:
“Which of my products should I advertise more heavily to increase
profit? How can I improve my compliance program, while reducing
costs? What manufacturing process change will allow me to build a
better product?”The key to answering these questions is: understand
the data you have and what the data inductively tells you.
» Data Product
A data product provides actionable
information without exposing
decision makers to the underlying
data or analytics. Examples include:
• Movie Recommendations
• Weather Forecasts
• Stock Market Predictions
• Production Process
Improvements
• Health Diagnosis
• Flu Trend Predictions
• Targeted Advertising
Read this for additional background:
The term Data Science appeared
in the computer science literature
throughout the 1960s-1980s.
It was not until the late 1990s
however, that the field as we
describe it here, began to
emerge from the statistics and
data mining communities
(e.g., [2]
and [3]
). Data Science
was first introduced as an
independent discipline in 2001.[4]
Since that time, there have been
countless articles advancing the
discipline, culminating with
Data Scientist being declared the
sexiest job of the 21st
century.[5]
We established our first Data
Science team at Booz Allen
in 2010. It began as a natural
extension of our Business
Intelligence and cloud
infrastructure development
work. We saw the need for a
new approach to distill value
from our clients’ data. We
approached the problem
with a multidisciplinary
team of computer scientists,
mathematicians and domain
experts.They immediately
produced new insights and
analysis paths, solidifying the
validity of the approach. Since
that time, our Data Science
team has grown to 250 staff
supporting dozens of clients
across a variety of domains.
This breadth of experience
provides a unique perspective
on the conceptual models,
tradecraft, processes and culture
of Data Science.

Source: Booz Allen Hamilton
What makes Data Science Different?
Data Science supports and encourages shifting between deductive
(hypothesis-based) and inductive (pattern-based) reasoning. This is
a fundamental change from traditional analytic approaches. Inductive
reasoning and exploratory data analysis provide a means to form or
refine hypotheses and discover new analytic paths. In fact, to do the
discovery of significant insights that are the hallmark of Data Science,
you must have the tradecraft and the interplay between inductive
and deductive reasoning. By actively combining the ability to reason
deductively and inductively, Data Science creates an environment
where models of reality no longer need to be static and empirically
based. Instead, they are constantly tested, updated and improved until
better models are found.These concepts are summarized in the figure,
The Types of Reason and Their Role in Data Science Tradecraft.
THE TYPES OF REASON…
DEDUCTIVE REASONING:
› Commonly associated
with “formal logic.”
› Involves reasoning from known
premises, or premises presumed
to be true, to a certain conclusion.
› The conclusions reached are
certain, inevitable, inescapable.
INDUCTIVE REASONING
› Commonly known as “informal
logic,” or “everyday argument.”
› Involves drawing uncertain
inferences, based on
probabilistic reasoning.
› The conclusions reached
are probable, reasonable,
plausible, believable.
…AND THEIR ROLE IN DATA SCIENCE TRADECRAFT.
DEDUCTIVE REASONING:
› Formulate hypotheses about
relationships and underlying models.
› Carry out experiments with the data
to test hypotheses and models.
INDUCTIVE REASONING
› Exploratory data analysis to
discover or reﬁne hypotheses.
› Discover new relationships, insights
and analytic paths from the data.
The Types of Reason and Their Role in Data Science Tradecraft

The differences between Data Science and traditional analytic
approaches do not end at seamless shifting between deductive
and inductive reasoning. Data Science offers a distinctly different
perspective than capabilities such as Business Intelligence. Data
Science should not replace Business Intelligence functions within
an organization, however.The two capabilities are additive and
complementary, each offering a necessary view of business operations
and the operating environment.The figure, Business Intelligence and
Data Science – A Comparison, highlights the differences between the
two capabilities. Key contrasts include:
› Discovery vs. Pre-canned Questions: Data Science actually
works on discovering the question to ask as opposed to just
asking it.
› Power of Many vs. Ability of One: An entire team provides
a common forum for pulling together computer science,
mathematics and domain expertise.
› Prospective vs. Retrospective: Data Science is focused on
obtaining actionable information from data as opposed to
reporting historical facts.
LOOKING BACKWARD AND FORWARD
FIRST THERE WAS
BUSINESS INTELLIGENCE
Deductive Reasoning
Backward Looking
Slice and Dice Data
Warehoused and Siloed Data
Analyze the Past, Guess the Future
Creates Reports
Analytic Output
NOW WE'VE ADDED
DATA SCIENCE
Inductive and Deductive Reasoning
Forward Looking
Interact with Data
Distributed, Real Time Data
Predict and Advise
Creates Data Products
Answer Questions and Create New Ones
Actionable Answer
Business Intelligence and Data Science - A Comparison (adapted in part from [6])

What is the Impact of Data Science?
As we move into the data economy, Data Science is the competitive
advantage for organizations interested in winning – in whatever way
winning is defined. The manner in which the advantage is defined
is through improved decision-making. A former colleague liked to
describe data-informed decision making like this: If you have perfect
information or zero information then your task is easy – it is in between
those two extremes that the trouble begins. What he was highlighting is
the stark reality that whether or not information is available, decisions
must be made.
The way organizations make decisions has been evolving for half a
century. Before the introduction of Business Intelligence, the only
options were gut instinct, loudest voice, and best argument. Sadly, this
method still exists today, and in some pockets it is the predominant
means by which the organization acts.Take our advice and never, ever
work for such a company!
Fortunately for our economy, most organizations began to inform
their decisions with real information through the application of
simple statistics.Those that did it well were rewarded; those that did
not failed. We are outgrowing the ability of simple stats to keep pace
with market demands, however.The rapid expansion of available data,
and the tools to access and make use of the data at scale, are enabling
fundamental changes to the way organizations make decisions.
Data Science is required to maintain competitiveness in the
increasingly data-rich environment. Much like the application of
simple statistics, organizations that embrace Data Science will be
rewarded while those that do not will be challenged to keep pace.
As more complex, disparate data sets become available, the chasm
between these groups will only continue to widen.The figure,
The Business Impacts of Data Science, highlights the value awaiting
organizations that embrace Data Science.

DATA SCIENCE IS NECESSARY...
17-49% increase in productivity when organizations increase data
usability by 10%
11-42% return on assets (ROA) when organizations increase data
access by 10%
241% increase in ROI when organizations use big data to
improve competitiveness
1000%
increase in ROI when deploying analytics across most of
the organization, aligning daily operations with senior
management's goals, and incorporating big data
5-6% performance improvement for organizations making
data-driven decisions.
...TO COMPETE IN THE FUTURE
The Business Impacts of Data Science (adapted from [7], [8] and [9])

What is Different Now?
For 20 years IT systems were built the same way. We separated
the people who ran the business from the people who managed the
infrastructure (and therefore saw data as simply another thing they
had to manage). With the advent of new technologies and analytic
techniques, this artificial – and highly ineffective – separation of
critical skills is no longer necessary. For the first time, organizations
can directly connect business decision makers to the data.This simple
step transforms data from being ‘something to be managed’ into
‘something to be valued.’
In the wake of the transformation, organizations face a stark choice:
you can continue to build data silos and piece together disparate
information or you can consolidate your data and distill answers.
From the Data Science perspective, this is a false choice: The siloed
approach is untenable when you consider the (a) the opportunity
cost of not making maximum use of all available data to help
an organization succeed, and (b) the resource and time costs of
continuing down the same path with outdated processes.The tangible
benefits of data products include:
› Opportunity Costs: Because Data Science is an emerging field,
opportunity costs arise when a competitor implements and
generates value from data before you. Failure to learn and account
for changing customer demands will inevitably drive customers
away from your current offerings. When competitors are able
to successfully leverage Data Science to gain insights, they can
drive differentiated customer value propositions and lead their
industries as a result.
› Enhanced Processes: As a result of the increasingly interconnected
world, huge amounts of data are being generated and stored
every instant. Data Science can be used to transform data into
insights that help improve existing processes. Operating costs
can be driven down dramatically by effectively incorporating the
complex interrelationships in data like never before.This results
in better quality assurance, higher product yield and more
effective operations.

How does Data Science
Actually Work?
It’s not rocket science… it’s something better - Data Science
Let’s not kid ourselves - Data Science is a complex field. It is difficult,
intellectually taxing work, which requires the sophisticated integration
of talent, tools and techniques. But as a field guide, we need to cut
through the complexity and provide a clear, yet effective way to
understand this new world.
To do this, we will transform the field of Data Science into a set of
simplified activities as shown in the figure, The Four Key Activities of a
Data Science Endeavor. Data Science purists will likely disagree with
this approach, but then again, they probably don’t need a field guide,
sitting as they do in their ivory towers! In the real world, we need
clear and simple operating models to help drive us forward.

1 2 3 4
Acquire Prepare Analyze Act
Low
High
Degree
of
Effort
Data Science Activities
Try
Evaluate
Setup Do
Evaluate
Activity 1: Acquire
This activity focuses
on obtaining the
data you need.
Given the nature of
data, the details of
this activity depend
heavily on who you
are and what you
do. As a result, we
will not spend a
lot of time on this
activity other than
to emphasize its
importance and
to encourage an
expansive view on
which data can and
should be used.
Activity 2: Prepare
Great outcomes
don’t just happen
by themselves.
A lot depends on
preparation, and
in Data Science,
that means
manipulating the
data to fit your
analytic needs.
This stage can
consume a great
deal of time, but
it is an excellent
investment. The
benefits are
immediate and
long term.
Activity 3: Analyze
This is the activity
that consumes the
lion’s share of the
team’s attention.
It is also the most
challenging and
exciting (you will
see a lot of ‘aha
moments’ occur in
this space). As the
most challenging
and vexing of the
four activities,
this field guide
focuses on helping
you do this better
and faster.
Activity 4: Act
Every effective
Data Science team
analyzes its data
with a purpose
– that is, to turn
data into actions.
Actionable and
impactful insights
are the holy grail
of Data Science.
Converting insights
into action can be a
politically charged
activity, however.
This activity
depends heavily
on the culture and
character of your
organization, so
we will leave you
to figure out those
details for yourself.
The Four Key Activities of a Data Science Endeavor

Acquire
All analysis starts with access to data, and for the Data Scientist
this axiom holds true. But there are some significant differences –
particularly with respect to the question of who stores, maintains and
owns the data in an organization.
But before we go there, lets look at what is changing.Traditionally,
rigid data silos artificially define the data to be acquired. Stated
another way, the silos create a filter that lets in a very small amount of
data and ignores the rest.These filtered processes give us an artificial
view of the world based on the ‘surviving data,’ rather than one that
shows full reality and meaning. Without a broad and expansive data
set, we can never immerse ourselves in the diversity of the data. We
instead make decisions based on limited and constrained information.
Eliminating the need for silos gives us access to all the data at once –
including data from multiple outside sources. It embraces the reality
that diversity is good and complexity is okay.This mindset creates a
completely different way of thinking about data in an organization by
giving it a new and differentiated role. Data represents a significant
new profit and mission-enhancement opportunity for organizations.
But as mentioned earlier, this first activity is heavily dependent upon
the situation and circumstances. We can’t leave you with anything
more than general guidance to help ensure maximum value:
› Look inside first: What data do you have current access
to that you are not using? This is in large part the data
being left behind by the filtering process, and may be
incredibly valuable.
› Remove the format constraints: Stop limiting your data
acquisition mindset to the realm of structured databases.
Instead, think about unstructured and semi-structured data
as viable sources.
› Figure out what’s missing: Ask yourself what data would
make a big difference to your processes if you had access to it.
Then go find it!
› Embrace diversity: Try to engage and connect to publicly
available sources of data that may have relevance to your
domain area.
» Not All Data Is Created Equal
As you begin to aggregate data,
remember that not all data is
created equally. Organizations have
a tendency to collect any data that
is available. Data that is nearby
(readily accessible and easily
obtained) may be cheap to collect,
but there is no guarantee it is the
right data to collect. Focus on the
data with the highest ROI for your
organization. Your Data Science
team can help identify that data.
Also remember that you need to
strike a balance between the data
that you need and the data that you
have. Collecting huge volumes of
data is useless and costly if it is not
the data that you need.

Prepare
Once you have the data, you need to prepare it for analysis.
Organizations often make decisions based on inexact data. Data
stovepipes mean that organizations may have blind spots.They are
not able to see the whole picture and fail to look at their data and
challenges holistically.The end result is that valuable information is
withheld from decision makers. Research has shown almost 33% of
decisions are made without good data or information.[10]
When Data Scientists are able to explore and analyze all the data, new
opportunities arise for analysis and data-driven decision making.The
insights gained from these new opportunities will significantly change
the course of action and decisions within an organization. Gaining
access to an organization’s complete repository of data, however,
requires preparation.
Our experience shows time and time again that the best tool for
Data Scientists to prepare for analysis is a lake – specifically, the Data
Lake.[11]
This is a new approach to collecting, storing and integrating
data that helps organizations maximize the utility of their data.
Instead of storing information in discrete data structures, the Data
Lake consolidates an organization’s complete repository of data in
a single, large view. It eliminates the expensive and cumbersome
data-preparation process, known as Extract/Transform/Load (ETL),
necessary with data silos.The entire body of information in the Data
Lake is available for every inquiry – and all at once.

Analyze
We have acquired the data… we have prepared it… now it is time to
analyze it.
The Analyze activity requires the greatest effort of all the activities
in a Data Science endeavor.The Data Scientist actually builds the
analytics that create value from data. Analytics in this context is
an iterative application of specialized and scalable computational
resources and tools to provide relevant insights from exponentially
growing data.This type of analysis enables real-time understanding
of risks and opportunities by evaluating situational, operational and
behavioral data.
With the totality of data fully accessible in the Data Lake,
organizations can use analytics to find the kinds of connections and
patterns that point to promising opportunities.This high-speed
analytic connection is done within the Data Lake, as opposed to
older style sampling methods that could only make use of a narrow
slice of the data. In order to understand what was in the lake, you had
to bring the data out and study it. Now you can dive into the lake,
bringing your analytics to the data.The figure, Analytic Connection in
the Data Lake, highlights the concept of diving into the Data Lake to
discover new connections and patterns.
Analytic Connection in the Data Lake

Data Scientists work across the spectrum of analytic goals – Describe,
Discover, Predict and Advise.The maturity of an analytic capability
determines the analytic goals encompassed. Many variables play key
roles in determining the difficulty and suitability of each goal for an
organization. Some of these variables are the size and budget of an
organization and the type of data products needed by the decision
makers. A detailed discussion on analytic maturity can be found in
Data Science Maturity within an Organization.
In addition to consuming the greatest effort, the Analyze activity
is by far the most complex.The tradecraft of Data Science is an
art. While we cannot teach you how to be an artist, we can share
foundational tools and techniques that can help you be successful.
The entirety of Take Off the Training Wheels is dedicated to sharing
insights we have learned over time while serving countless clients.
This includes descriptions of a Data Science product lifecycle and
the Fractal Analytic Model (FAM).The Analytic Selection Process and
accompanying Guide to Analytic Selection provide key insights into one
of the most challenging tasks in all of Data Science – selecting the
right technique for the job.
Act
Now that we have analyzed the data, it’s time to take action.
The ability to make use of the analysis is critical. It is also very
situational. Like the Acquire activity, the best we can hope for is to
provide some guiding principles to help you frame the output for
maximum impact. Here are some key points to keep in mind when
presenting your results:
1. The finding must make sense with relatively little up-front
training or preparation on the part of the decision maker.
2. The finding must make the most meaningful patterns, trends
and exceptions easy to see and interpret.
3. Every effort must be made to encode quantitative data
accurately so the decision maker can accurately interpret and
compare the data.
4. The logic used to arrive at the finding must be clear and
compelling as well as traceable back through the data.
5. The findings must answer real business questions.

Proportion
of
Effort
Maturity
Stages of Maturity
Collect
Describe
Discover
Predict
Advise
DataSilos
Data Science Maturity within
an Organization
The four activities discussed thus far provide a simplified view of Data
Science. Organizations will repeat these activities with each new Data
Science endeavor. Over time, however, the level of effort necessary
for each activity will change. As more data is Acquired and Prepared
in the Data Lake, for example, significantly less effort will need to
be expended on these activities.This is indicative of a maturing Data
Science capability.
Assessing the maturity of your Data Science capability calls for a
slightly different view. We use The Data Science Maturity Model as
a common framework for describing the maturity progression and
components that make up a Data Science capability.This framework
can be applied to an organization’s Data Science capability or even
to the maturity of a specific solution, namely a data product. At each
stage of maturity, powerful insight can be gained.
The Data Science Maturity Model

When organizations start out, they have Data Silos. At this stage,
they have not carried out any broad Aggregate activities.They may
not have a sense of all the data they have or the data they need.The
decision to create a Data Science capability signals the transition into
the Collect stage.
All of your initial effort will be focused on identifying and aggregating
data. Over time, you will have the data you need and a smaller
proportion of your effort can focus on Collect. You can now begin to
Describe your data. Note, however, that while the proportion of time
spent on Collect goes down dramatically, it never goes away entirely.
This is indicative of the four activities outlined earlier – you will
continue to Aggregate and Prepare data as new analytic questions
arise, additional data is needed and new data sources become available.
Organizations continue to advance in maturity as they move through
the stages from Describe to Advise. At each stage they can tackle
increasingly complex analytic goals with a wider breadth of analytic
capabilities. As described for Collect, each stage never goes away
entirely. Instead, the proportion of time spent focused on it goes
down and new, more mature activities begin. A brief description
of each stage of maturity is shown in the table The Stages of Data
Science Maturity.
The Stages of Data Science Maturity
Stage Description Example
Collect
Focuses on collecting internal
or external datasets.
Gathering sales records and
corresponding weather data.
Describe
Seeks to enhance or
refine raw data as well
as leverage basic analytic
functions such as counts.
How are my customers
distributed with respect to
location, namely zip code?
Discover
Identifies hidden relationships
or patterns.
Are there groups within
my regular customers that
purchase similarly?
Predict
Utilizes past observations to
predict future observations.
Can we predict which products
that certain customer groups
are more likely to purchase?
Advise
Defines your possible decisions,
optimizes over those decisions,
and advises to use the decision
that gives the best outcome.
Your advice is to target advertise
to specific groups for certain
products to maximize revenue.

The maturity model provides a powerful tool for understanding
and appreciating the maturity of a Data Science capability.
Organizations need not reach maximum maturity to achieve
success. Significant gains can be found in every stage. We believe
strongly that one does not engage in a Data Science effort, however,
unless it is intended to produce an output – that is, you have the
intent to Advise.This means simply that each step forward in
maturity drives you to the right in the model diagram. Moving
to the right requires the correct processes, people, culture and
operating model – a robust Data Science capability. What Does it
Take to Create a Data Science Capability? addresses this topic.
We have observed very few organizations actually operating at
the highest levels of maturity, the Predict and Advise stages.The
tradecraft of Discover is only now maturing to the point that
organizations can focus on advanced Predict and Advise activities.
This is the new frontier of Data Science.This is the space in which
we will begin to understand how to close the cognitive gap between
humans and computers. Organizations that reach Advise will be
met with true insights and real competitive advantage.
» Where does your organization
fall in analytic maturity?
Take the quiz!
1. How many data sources do
you collect?
a. Why do we need a bunch of data?
– 0 points, end here.
b. I don’t know the exact number.
– 5 points
c. We identified the required data and
collect it. – 10 points
2. Do you know what questions
your Data Science team is trying
to answer?
a. Why do we need questions?
- 0 points
b. No, they figure it out for themselves.
– 5 points
c. Yes, we evaluated the questions that
will have the largest impact to the
business. – 10 points
3. Do you know the important factors
driving your business?
a. I have no idea. – 0 points
b. Our quants help me figure it out.
– 5 points
c. We have a data product for that.
– 10 points
4. Do you have an understanding of
future conditions?
a.I look at the current conditions and
read the tea leaves. – 0 points
b. We have a data product for that.
– 5 points
5. Do you know the best course
of action to take for your key
decisions?
a. I look at the projections and plan a
course. – 0 points
b. We have a data product for that.
– 5 points
Check your score:
0 – Data Silos, 5-10 – Collect,
10-20 – Describe, 20-30 – Discover,
30-35 – Predict, 35-40 - Advise

COMPUTER SCIENCE
Provides the environment
in which data products
are created.
DOMAIN EXPERTISE
Provides understanding
of the reality in which a
problem space exists.
MATHEMATICS
Provides the theoretical
structure in which Data
Science problems
are examined.
What does it Take to Create
a Data Science Capability?
Data Science is all about building teams and culture.
As with any team sport, Data Science depends on a diverse set of skills
to achieve its objective – winning at the game of improved insights.
You need the three skill sets shown in The Data Science Venn Diagram
to create a winning team in the world of Data Science.
Building Data Science teams is difficult. It requires an understanding
of the types of personalities that make Data Science possible, as well
as a willingness to establish a culture of innovation and curiosity in
your organization. You must also consider how to deploy the team and
gain widespread buy-in from across your organization.
The Data Science Venn Diagram (inspired by [12])

Understanding What Makes
a Data Scientist
Data Science often requires a significant investment of time across
a variety of tasks. Hypotheses must be generated and data must be
acquired, prepared, analyzed, and acted upon. Multiple techniques
are often applied before one yields interesting results. If that seems
daunting, it is because it is. Data Science is difficult, intellectually
taxing work, which requires lots of talent: both tangible technical
skills as well as the intangible ‘x-factors.’
The most important qualities of Data Scientists tend to be the
intangible aspects of their personalities. Data Scientists are by
nature curious, creative, focused, and detail-oriented.
› Curiosity is necessary to peel apart a problem and examine
the interrelationships between data that may appear
superficially unrelated.
› Creativity is required to invent and try new approaches to
solving a problem, which often times have never been applied
in such a context before.
› Focus is required to design and test a technique over days and
weeks, find it doesn’t work, learn from the failure, and try again.
› Attention to Detail is needed to maintain rigor, and to detect
and avoid over-reliance on intuition when examining data.
Success of a Data Science team requires proficiency in three
foundational technical skills: computer science, mathematics and
domain expertise, as reflected in The Data Science Venn Diagram.
Computers provide the environment in which data-driven
hypotheses are tested, and as such computer science is necessary
for data manipulation and processing. Mathematics provides the
theoretical structure in which Data Science problems are examined.
A rich background in statistics, geometry, linear algebra, and calculus
are all important to understand the basis for many algorithms and
tools. Finally, domain expertise contributes to an understanding of
what problems actually need to be solved, what kind of data exists
in the domain and how the problem space may be instrumented
and measured.
» The Triple Threat Unicorn
Individuals who are great at all three
of the Data Science foundational
technical skills are like unicorns –
very rare and if you’re ever lucky
enough to find one they should be
treated carefully. When you manage
these people:
› Encourage them to lead
your team, but not manage
it. Don’t bog them down
with responsibilities of
management that could be
done by other staff.
› Put extra effort into managing
their careers and interests
within your organization.
Build opportunities for
promotion into your
organization that allow them
to focus on mentoring other
Data Scientists and progressing
the state of the art while also
advancing their careers.
› Make sure that they have the
opportunity to present and
spread their ideas in many
different forums, but also be
sensitive to their time.

Finding the Athletes for Your Team
Building a Data Science team is complex. Organizations must
simultaneously engage existing internal staff to create an “anchor” that
can be used to recruit and grow the team, while at the same time
undergo organizational change and transformation to meaningfully
incorporate this new class of employee.
Building a team starts with identifying existing staff within an
organization who have a high aptitude for Data Science. Good
candidates will have a formal background in any of the three
foundational technical skills we mentioned, and will most importantly
have the personality traits necessary for Data Science.They may often
have advanced (masters or higher) degrees, but not always.The very
first staff you identify should also have good leadership traits and a
sense of purpose for the organization, as they will lead subsequent
staffing and recruiting efforts. Don’t discount anyone – you will find
Data Scientists in the strangest places with the oddest combinations
of backgrounds.
Shaping the Culture
Good Data Science requires a highly academic culture of peer review,
where no member of the organization is immune from constructive
criticism. As you build your Data Science practice, you should be
prepared to subject all aspects of your corporate operations to the
curious nature of your Data Science teams. Failure to do so creates
a negative image of a culture that fails to “eat its own dog food,”
and will invite negative reflection on the brand, both internally and
externally. You should be conscious of any cultural legacies existing in
an organization that are antithetical to Data Science.
Data Scientists are fundamentally curious and imaginative. We have
a saying on our team, “We’re not nosy, we’re Data Scientists.”These
qualities are fundamental to the success of the project and to gaining
new dimensions on challenges and questions. Often Data Science
projects are hampered by the lack of the ability to imagine something
new and different. Fundamentally, organizations must foster trust and
transparent communication across all levels, instead of deference to
authority, in order to establish a strong Data Science team. Managers
should be prepared to invite participation more frequently, and offer
explanation or apology less frequently.
» Don’t judge a book by its
cover, or a Data Scientist
by his or her degree in
this case. Amazing Data
Scientists can be found
anywhere. Just look at the
diverse and surprising
sampling of degrees
held by Our Experts:
› Bioinformatics
› Biomedical Engineering
› Biophysics
› Business
› Computer Graphics
› Computer Science
› English
› Forest Management
› History
› Industrial Engineering
› Information Technology
› Mathematics
› National Security Studies
› Operations Research
› Physics
› Wildlife & Fisheries
Management

Selecting Your Operating Model
Depending on the size, complexity, and the business drivers,
organizations should consider one of three Data Science operating
models: Centralized, Deployed, or Diffused.These three models are
shown in the figure, Data Science Operating Models.
Centralized Data Science teams serve the organization across all
business units.The team is centralized under a Chief Data Scientist.
They serve all the analytical needs of an organization and they all
co-locate together.The domain experts come to this organization for
brief rotational stints to solve challenges around the business.
Deployed Data Science teams go to the business unit or group and
reside there for short- or long-term assignments.They are their own
entity and they work with the domain experts within the group
to solve hard problems.They may be working independently on
particular challenges, but they should always collaborate with the
other teams to exchange tools, techniques and war stories.
The Diffused Data Science team is one that is fully embedded with
each group and becomes part of the long-term organization.These
teams work best when the nature of the domain or business unit is
already one focused on analytics. However, building a cross-cut view
into the team that can collaborate with other Data Science teams is
critical to the success.
CENTRALIZED
Business units bring their
problems to a centralized
Data Science team.
DIFFUSED
Data Scientists are fully
embedded within the
business units.
DEPLOYED
Small Data Science teams
are forward deployed to
business units.
Data Science Operating Models

BALANCING THE DATA
SCIENCE TEAM EQUATION
Balancing the composition of a Data Science team
is much like balancing the reactants and products in
a chemical reaction. Each side of the equation must
represent the same quantity of any particular element.
In the case of Data Science, these elements are the
foundational technical skills computer science (CS),
mathematics (M) and domain expertise (DE). The
reactants, your Data Scientists, each have their own
unique skills composition. You must balance the staff
mix to meet the skill requirements of the Data Science
team, the product in the reaction. If you don’t correctly
balance the equation, your Data Science team will not
have the desired impact on the organization.
2 CS M2 + 2 CS + M DE → CS4 M5 DE
In the example above, your project requires four parts
computer science, ﬁve parts mathematics and one
part domain expertise. Given the skills mix of the
staff, ﬁve people are needed to balance the equation.
Throughout your Data Science project, the skills
requirements of the team will change. You will need
to re-balance the equation to ensure the reactants
balance with the products.

Success Starts at the Top
Data Science teams, no matter how they are deployed, must have
sponsorship.These can start as grass roots efforts by a few folks to
start tackling hard problems, or as efforts directed by the CEO.
Depending on the complexity of the organization, direction from top-
down for large organizations is the best for assuaging fears and doubts
of these new groups.
Data Science teams often face harder political headwinds when
solving problems than any technical hurdles.To prove a Data
Science team’s value, the team needs to initially focus on the hardest
problems within an organization that have the highest return for
key stakeholders and will change how the organization approaches
challenges in the future.This has the effect of keeping the team
motivated and encouraged in the face of difficult challenges. Leaders
must be key advocates who meet with stakeholders to ferret out
the hardest problems, locate the data, connect disparate parts of the
business and gain widespread buy-in.

TAKE OFF the T R A I N I N G W H E E L S
THE PRACTITIONER’S GUIDE
TO DATA SCIENCE
Read this section to get beyond the hype and
learn the secrets of being a Data Scientist.

Guiding Principles
Failing is good; failing quickly is even better.
The set of guiding principles that govern how we conduct the
tradecraft of Data Science are based loosely on the central tenets
of innovation, as the two areas are highly connected.These principles
are not hard and fast rules to strictly follow, but rather key tenets
that have emerged in our collective consciousness. You should use
these to guide your decisions, from problem decomposition
through implementation.
› Be willing to fail. At the core of Data Science is the idea of
experimentation.Truly innovative solutions only emerge when
you experiment with new ideas and applications. Failure is an
acceptable byproduct of experimentation. Failures locate regions
that no longer need to be considered as you search for a solution.
› Fail often and learn quickly. In addition to a willingness to fail, be
ready to fail repeatedly.There are times when a dozen approaches
must be explored in order to find the one that works. While you
shouldn’t be concerned with failing, you should strive to learn from
the attempt quickly.The only way you can explore a large number
of solutions is to do so quickly.
› Keep the goal in mind. You can often get lost in the details and
challenges of an implementation. When this happens, you lose
sight of your goal and begin to drift off the path from data to
analytic action. Periodically step back, contemplate your goal, and
evaluate whether your current approach can really lead you where
you want to go.
› Dedication and focus lead to success. You must often explore
many approaches before finding the one that works. It’s easy to
become discouraged. You must remain dedicated to your analytic
goal. Focus on the details and the insights revealed by the data.
Sometimes seemingly small observations lead to big successes.
› Complicated does not equal better. As technical practitioners, we
have a tendency to explore highly complex, advanced approaches.
While there are times where this is necessary, a simpler approach
can often provide the same insight. Simpler means easier and
faster to prototype, implement and verify.
» Tips From the Pros
It can be easier to rule out a solution
than conﬁrm its correctness. As a
result, focus on exploring obvious
shortcomings that can quickly
disqualify an approach. This will allow
you to focus your time on exploring
truly viable approaches as opposed to
dead ends.
If the ﬁrst thing you try to do is to
create the ultimate solution, you will
fail, but only after banging your head
against a wall for several weeks.

The Importance of Reason
Beware: in the world of Data Science, if it walks like a duck
and quacks like a duck, it might just be a moose.
Data Science supports and encourages shifting between deductive
(hypothesis-based) and inductive (pattern-based) reasoning.
Inductive reasoning and exploratory data analysis provide a means
to form or refine hypotheses and discover new analytic paths.
Models of reality no longer need to be static.They are constantly
tested, updated and improved until better models are found.
The analysis of big data has brought inductive reasoning to the
forefront. Massive amounts of data are analyzed to identify
correlations. However, a common pitfall to this approach is confusing
correlation with causation. Correlation implies but does not prove
causation. Conclusions cannot be drawn from correlations until the
underlying mechanisms that relate the data elements are understood.
Without a suitable model relating the data, a correlation may simply
be a coincidence.
» Correlation without
Causation
A common example of this
phenomenon is the high correlation
between ice cream consumption and
the murder rate during the summer
months. Does this mean ice cream
consumption causes murder or,
conversely, murder causes ice cream
consumption? Most likely not, but
you can see the danger in mistaking
correlation for causation. Our job as
Data Scientists is making sure we
understand the difference.
43Take off the Training Wheels

››
Paul Yacci
The Dangers of Rejection
In the era of big
data, one piece
of analysis that
is frequently
overlooked is
the problem of
finding patterns
when there
are actually no
apparent patterns. In statistics
this is referred to as Type I error.
As scientists, we are always
on the lookout for a new or
interesting breakthrough that
could explain a phenomenon.
We hope to see a pattern in our
data that explains something
or that can give us an answer.
The primary goal of hypothesis
testing is to limit Type I error.
This is accomplished by using
small values. For example,
a value of 0.05 states that
there is a 1 in 20 chance that
the test will show that there
is something significant when
in actuality there isn’t. This
problem compounds when
testing multiple hypotheses.
When running multiple
hypothesis tests, we are likely
to encounter Type I error. As
more data becomes available
for analysis, Type I error
needs to be controlled.
One of my projects required
testing the difference between
the means of two microarray
data samples. Microarray
data contains thousands of
measurements but is limited
in the number of observations.
A common analysis approach
is to measure the same genes
under different conditions. If
there is a significant enough
difference in the amount of
gene expression between the
two samples, we can say that
the gene is correlated with a
particular phenotype. One way
to do this is to take the mean of
each phenotype for a particular
gene and formulate a hypothesis
to test whether there is a
significant difference between
the means. Given that we were
running thousands of these tests
at = 0.05, we found several
differences that were significant.
The problem was that some
of these could be caused by
random chance.
Many corrections exist to
control for false indications of
significance. The Bonferroni
correction is one of the most
conservative. This calculation
lowers the level below which you
will reject the null hypothesis
(your p value). The formula is
alpha/n, where n equals the
number of hypothesis tests
that you are running. Thus, if
you were to run 1,000 tests of
significance at = 0.05, your
p value should be less than
0.00005 (0.05/1,000) to reject the
null hypothesis. This is obviously
a much more stringent value.
A large number of the previously
significant values were no longer
significant, revealing the true
relationships within the data.
The corrected significance gave
us confidence that the observed
expression levels were due to
differences in the cellular gene
expression rather than noise. We
were able to use this information
to begin investigating what
proteins and pathways were
active in the genes expressing
the phenotype of interest. By
solidifying our understanding
of the causal relationships, we
focused our research on the
areas that could lead to new
discoveries about gene function
and, ultimately to improved
medical treatments.

Reason and common sense are foundational to Data Science. Without it, data is simply
a collection of bits. Context, inferences and models are created by humans and carry
with them biases and assumptions. Blindly trusting your analyses is a dangerous thing
that can lead to erroneous conclusions. When you approach an analytic challenge, you
should always pause to ask yourself the following questions:
› What problem are we trying
to solve? Articulate the answer
as a sentence, especially when
communicating with the end-
user. Make sure that it sounds
like an answer. For example,
“Given a fixed amount of
human capital, deploying
people with these priorities
will generate the best return
on their time.”
› Does the approach make sense?
Write out your analytic plan.
Embrace the discipline of
writing, as it brings structure
to your thinking. Back of
the envelope calculations are
an existence proof of your
approach. Without this kind
of preparation, computers are
power tools that can produce
lots of bad answers really fast.
› Does the answer make sense?
Can you explain the answer?
Computers, unlike children,
do what they are told. Make
sure you spoke to it clearly by
validating that the instructions
you provided are the ones you
intended. Document your
assumptions and make sure
they have not introduced bias
in your work.
› Is it a finding or a mistake?
Be skeptical of surprise
findings. Experience says that
it if seems wrong, it probably
is wrong. Before you accept
that conclusion, however,
make sure you understand
and can clearly explain why
it is wrong.
› Does the analysis address the
original intent? Make sure
that you are not aligning the
answer with the expectations
of the client. Always speak
the truth, but remember that
answers of “your baby is ugly”
require more, not less, analysis.
› Is the story complete? The goal
of your analysis is to tell an
actionable story. You cannot
rely on the audience to stitch
the pieces together. Identify
potential holes in your
story and fill them to avoid
surprises. Grammar, spelling
and graphics matter; your
audience will lose confidence
in your analysis if your results
look sloppy.
› Where would we head next?
No analysis is every finished,
you just run out of resources.
Understand and explain what
additional measures could
be taken if more resources
are found.
Better a short pencil than a
long memory. End every day by
documenting where you are; you
may learn something along the way.
Document what you learned and why
you changed your plan.
Test your answers with a friendly
audience to make sure your ﬁndings
hold water. Red teams save careers.

Component Parts of
Data Science
There is a web of components that interact to create your
solution space. Understanding how they are connected
is critical to your ability to engineer solutions to Data
Science problems.
The components involved in any Data Science project fall into a
number of different categories including the data types analyzed, the
analytic classes used, the learning models employed and the execution
models used to run the analytics.The interconnection across these
components, shown in the figure, Interconnection Among the Component
Parts of Data Science, speaks to the complexity of engineering Data
Science solutions. A choice made for one component exerts influence
over choices made for others categories. For example, data types
lead the choices in analytic class and learning models, while latency,
timeliness and algorithmic parallelization strategy inform the
execution model. As we dive deeper into the technical aspects of
Data Science, we will begin with an exploration of these components
and touch on examples of each.
Read this to get the quick and dirty:
When engineering a Data
Science solution, work from an
understanding of the components
that define the solution space.
Regardless of your analytic goal,
you must consider the data types
with which you will be working,
the classes of analytics you will use
to generate your data product,
how the learning models embodied
will operate and evolve, and the
execution models that will govern
how the analytic will be run.
You will be able to articulate a
complete Data Science solution
only after considering each of
these aspects.

data
streaming
data
batch
datastructured
data
unstructured
analytics
transforming
analytics
learning
analyticspredictive
learning
supervised
learning
unsupervised
learning
online
learningofﬂine
execution
batch
execution
streaming
execution
parallel
execution
serial
EXECUTION
MODELS
DATA TYPES
ANALYTIC
CLASSES
LEARNING
MODELS
Interconnection Among the Component Parts of Data Science

Data Types
Data types and analytic goals go hand-in-hand much like the chicken
and the egg; it is not always clear which comes first. Analytic goals are
derived from business objectives, but the data type also influences the
goals. For example, the business objective of understanding consumer
product perception drives the analytic goal of sentiment analysis.
Similarly, the goal of sentiment analysis drives the selection of a
text-like data type such as social media content. Data type also
drives many other choices when engineering your solutions.
There are a number of ways to classify data. It is common to
characterize data as structured or unstructured. Structured data exists
when information is clearly broken out into fields that have an
explicit meaning and are highly categorical, ordinal or numeric.
A related category, semi-structured, is sometimes used to describe
structured data that does not conform to the formal structure of
data models associated with relational databases or other forms
of data tables, but nonetheless contains tags or other markers.
Unstructured data, such as natural language text, has less clearly
delineated meaning. Still images, video and audio often fall under
the category of unstructured data. Data in this form requires
preprocessing to identify and extract relevant ‘features.’ The features
are structured information that are used for indexing and retrieval,
or training classification, or clustering models.
Data may also be classified by the rate at which it is generated,
collected or processed.The distinction is drawn between streaming
data that arrives constantly like a torrent of water from a fire
hose, and batch data, which arrives in buckets. While there is
rarely a connection between data type and data rate, data rate has
significant influence over the execution model chosen for analytic
implementation and may also inform a decision of analytic class or
learning model.

Classes of Analytic Techniques
As a means for helping conceptualize the universe of possible analytic
techniques, we grouped them into nine basic classes. Note that
techniques from a given class may be applied in multiple ways to
achieve various analytic goals. Membership in a class simply indicates
a similar analytic function.The nine analytic classes are shown in the
figure, Classes of Analytic Techniques.
» Transforming Analytics
› Aggregation: Techniques to summarize the data.These
include basic statistics (e.g., mean, standard deviation),
distribution fitting, and graphical plotting.
› Enrichment: Techniques for adding additional information
to the data, such as source information or other labels.
› Processing: Techniques that address data cleaning,
preparation, and separation.This group also includes
common algorithm pre-processing activities such as
transformations and feature extraction.
» Learning Analytics
› Regression: Techniques for estimating relationships among
variables, including understanding which variables are
important in predicting future values.
› Clustering: Techniques to segment the data into naturally
similar groups.
› Classification: Techniques to identify data element
group membership.
› Recommendation: Techniques to predict the rating or
preference for a new entity, based on historic preference
or behavior.
» Predictive Analytics
› Simulation: Techniques to imitate the operation of a real-
world process or system.These are useful for predicting
behavior under new conditions.
› Optimization: Operations Research techniques focused on
selecting the best element from a set of available alternatives
to maximize a utility function.
Aggregation Enrichment Processing Simulation OptimizationRegression Clustering Classiﬁcation Recommend
TRANSFORMING LEARNING PREDICTIVE
Classes of Analytic Techniques

Learning Models
Analytic classes that perform predictions such as regression,
clustering, classification, and recommendation employ learning
models.These models characterize how the analytic is trained to
perform judgments on new data based on historic observation.
Aspects of learning models describe both the types of judgments
performed and how the models evolve over time, as shown in the
figure, Analytic Learning Models.
The learning models are typically described as employing
unsupervised or supervised learning. Supervised learning takes place
when a model is trained using a labeled data set that has a known
class or category associated with each data element.The model
relates the features found in training instances with the labels so
that predictions can be made for unlabeled instances. Unsupervised
learning models have no a-priori knowledge about the classes into
which data can be placed.They use the features in the dataset to form
groupings based on feature similarity.
A useful distinction of learning models is between those that are
trained in a single pass, which are known as offline models, and those
that are trained incrementally over time, known as online models.
Many learning approaches have online or offline variants.The decision
to use one or another is based on the analytic goals and execution
models chosen.
Generating an offline model requires taking a pass over the entire
training data set. Improving the model requires making separate
passes over the data.These models are static in that once trained, their
predictions will not change until a new model is created through a
subsequent training stage. Offline model performance is easier to
evaluate due to this deterministic behavior. Deployment of the model
into a production environment involves swapping out the old model
for the new.
Online models have both advantages and disadvantages.They
dynamically evolve over time, meaning they only require a single
deployment into a production setting.The fact that these models do
not have the entire dataset available when being trained, however,
is a challenge.They must make assumptions about the data based
TRAINING STYLE
Ofﬂine OnlineUnsupervised Supervised
LEARNING STYLE
Analytic Learning Models

on the examples observed; these assumptions may be sub-optimal.
This can be offset somewhat in cases where feedback on the model’s
predictions is available since online models can rapidly incorporate
feedback to improve performance.
Execution Models
Execution models describe how data is manipulated to perform
an analytic function.They may be categorized across a number
of dimensions. Execution Models are embodied by an execution
framework, which orchestrates the sequencing of analytic
computation. In this sense, a framework might be as simple as a
programming language runtime, such as the Python interpreter, or
a distributed computing framework that provides a specific API for
one or more programming languages such as Hadoop, MapReduce
or Spark. Grouping execution models based on how they handle data
is common, classifying them as either batch or streaming execution
models.The categories of execution model are shown in the figure,
Analytic Execution Models.
Analytic Execution Models
A batch execution model implies that data is analyzed in large
segments, that the analytic has a state where it is running and a state
where it is not running and that little state is maintained in memory
between executions. Batch execution may also imply that the analytic
produces results with a frequency on the order of several minutes or
more. Batch workloads tend to be fairly easy to conceptualize because
they represent discrete units of work. As such, it is easy to identify
a specific series of execution steps as well as the proper execution
frequency and time bounds based on the rate at which data arrives.
Depending on the algorithm choice, batch execution models are
easily scalable through parallelism.There are a number of frameworks
that support parallel batch analytic execution. Most famously,
Hadoop provides a distributed batch execution model in its
MapReduce framework.
Conversely, a streaming model analyzes data as it arrives. Streaming
execution models imply that under normal operation, the analytic
is always executing.The analytic can hold state in memory and
SEQUENCING
Serial ParallelBatch Streaming
SCHEDULING

constantly deliver results as new data arrives, on the order of seconds
or less. Many of the concepts in streaming are inherent in the Unix-
pipeline design philosophy; processes are chained together by linking
the output of one process to the input of the next. As a result, many
developers are already familiar with the basic concepts of streaming.
A number of frameworks are available that support the parallel
execution of streaming analytics such as Storm, S4 and Samza.
The choice between batch and streaming execution models often
hinges on analytic latency and timeliness requirements. Latency refers
to the amount of time required to analyze a piece of data once it
arrives at the system, while timeliness refers to the average age of an
answer or result generated by the analytic system. For many analytic
goals, a latency of hours and timeliness of days is acceptable and
thus lend themselves to the implementation enabled by the batch
approach. Some analytic goals have up-to-the-second requirements
where a result that is minutes old has little worth.The streaming
execution model better supports such goals.
Batch and streaming execution models are not the only dimensions
within which to categorize analytic execution methods. Another
distinction is drawn when thinking about scalability. In many cases,
scale can be achieved by spreading computation over a number of
computers. In this context, certain algorithms require a large shared
memory state, while others are easily parallelizable in a context
where no shared state exists between machines.This distinction has
significant impacts on both software and hardware selection when
building out a parallel analytic execution environment.
In order to understand system capacity
in the context of streaming analytic
execution, collect metrics including:
the amount of data consumed, data
emitted, and latency. This will help
you understand when scale limits
are reached.

Fractal Analytic Model
Data Science analytics are a lot like broccoli.
Fractals are mathematical sets that display self-similar patterns. As
you zoom in on a fractal, the same patterns reappear. Imagine a stalk
of broccoli. Rip off a piece of broccoli and the piece looks much like
the original stalk. Progressively smaller pieces of broccoli still look like
the original stalk.
Data Science analytics are a lot like broccoli – fractal in nature in
both time and construction. Early versions of an analytic follow the
same development process as later versions. At any given iteration, the
analytic itself is a collection of smaller analytics that often decompose
into yet smaller analytics.

Setup Try
Evaluate
Do
Evaluate
Iterative by Nature
Good Data Science is fractal in time — an iterative process. Getting
an imperfect solution out the door quickly will gain more interest
from stakeholders than a perfect solution that is never completed.The
figure, The Data Science Product Lifecycle, summarizes the lifecycle of
the Data Science product.
Set up the infrastructure, aggregate and prepare the data, and
incorporate domain expert knowledge. Try different analytic
techniques and models on subsets of the data. Evaluate the models,
refine, evaluate again, and select a model. Do something with your
models and results – deploy the models to inform, inspire action, and
act. Evaluate the business results to improve the overall product.
The Data Science Product Lifecycle

Smaller Pieces of Broccoli: A Data
Science Product
Components inside and outside of the Data Science product will
change with each iteration. Let’s take a look under the hood of a
Data Science product and examine the components during one
such iteration.
In order to achieve a greater analytic goal, you need to first decompose
the problem into sub-components to divide and conquer.The figure,
The Fractal Analytic Model, shows a decomposition of the Data Science
product into four component pieces.
GOAL
› Describe
› Discover
› Predict
› Advise
ACTION
› Productization
› Data Monetization
› Insights & Relationships
DATA
› Text
› Imagery
› Waveform
› Geo
› Time Series
COMPUTATION
Aggregation
Enrichment
Clustering
Classification
CLASSES OF ANALYTICS
The Fractal Analytic Model

Goal
You must first have some idea of your analytic goal and the end state
of the analysis. Is it to Discover, Describe, Predict, or Advise? It is
probably a combination of several of those. Be sure that before you
start, you define the business value of the data and how you plan to
use the insights to drive decisions, or risk ending up with interesting
but non-actionable trivia.
Data
Data dictates the potential insights that analytics can provide. Data
Science is about finding patterns in variable data and comparing those
patterns. If the data is not representative of the universe of events you
wish to analyze, you will want to collect that data through carefully
planned variations in events or processes through A/B testing or
design of experiments. Data sets are never perfect so don’t wait for
perfect data to get started. A good Data Scientist is adept at handling
messy data with missing or erroneous values. Just make sure to spend
the time upfront to clean the data or risk generating garbage results.
Computation
Computation aligns the data to goals through the process of creating
insights.Through divide and conquer, computation decomposes
into several smaller analytic capabilities with their own goals, data,
computation and resulting actions, just like a smaller piece of broccoli
maintains the structure of the original stalk. In this way, computation
itself is fractal. Capability building blocks may utilize different
types of execution models such as batch computation or streaming,
that individually accomplish small tasks. When properly combined
together, the small tasks produce complex, actionable results.
Action
How should engineers change the manufacturing process to generate
higher product yield? How should an insurance company choose
which policies to offer to whom and at what price? The output of
computation should enable actions that align to the goals of the data
product. Results that do not support or inspire action are nothing but
interesting trivia.
Given the fractal nature of Data Science analytics in time and
construction, there are many opportunities to choose fantastic or
shoddy analytic building blocks. The Analytic Selection Process offers
some guidance.

The Analytic
Selection Process
If you focus only on the science aspect of Data Science you will
never become a data artist.
A critical step in Data Science is to identify an analytic technique that
will produce the desired action. Sometimes it is clear; a characteristic
of the problem (e.g., data type) points to the technique you should
implement. Other times, however, it can be difficult to know where
to begin.The universe of possible analytic techniques is large. Finding
your way through this universe is an art that must be practiced. We
are going to guide you on the next portion of your journey - becoming
a data artist.

Decomposing the Problem
Decomposing the problem into manageable pieces is the first step
in the analytic selection process. Achieving a desired analytic action
often requires combining multiple analytic techniques into a holistic,
end-to-end solution. Engineering the complete solution requires that
the problem be decomposed into progressively smaller sub-problems.
The Fractal Analytic Model embodies this approach. At any given
stage, the analytic itself is a collection of smaller computations that
decompose into yet smaller computations. When the problem is
decomposed far enough, only a single analytic technique is needed
to achieve the analytic goal. Problem decomposition creates multiple
sub-problems, each with their own goals, data, computations, and
actions.The concept behind problem decomposition is shown in the
figure, Problem Decomposition Using the Fractal Analytic Model.
GOAL
› Describe
› Discover
› Predict
› Advise
ACTION
› Productization
› Data Monetization
› Insights & Relationships
DATA
› Text
› Imagery
› Waveform
› Geo
› Time Series
DATA
GOAL
ACTION
DATA
GOAL
ACTION
Aggregation
Enrichment
Clustering
Classification
CLASSES OF ANALYTICS
Problem Decomposition Using the Fractal Analytic Model

On the surface, problem decomposition appears to be a mechanical,
repeatable process. While this may be true conceptually, it is
really the performance of an art as opposed to the solving of an
engineering problem.There may be many valid ways to decompose
the problem, each leading to a different solution.There may be
hidden dependencies or constraints that only emerge after you begin
developing a solution.This is where art meets science. Although the
art behind problem decomposition cannot be taught, we have distilled
some helpful hints to help guide you. When you begin to think about
decomposing your problem, look for:
› Compound analytic goals that create natural segmentation.
For example, many problems focused on predicting future
conditions include both Discover and Predict goals.
› Natural orderings of analytic goals. For example, when extracting
features you must first identify candidate features and then
select the features set with the highest information value.These
two activities form distinct analytic goals.
› Data types that dictate processing activities. For example, text or
imagery both require feature extraction.
› Requirements for human-in-the-loop feedback. For example,
when developing alerting thresholds, you might need to solicit
analyst feedback and update the threshold based on their
assessment.
› The need to combine multiple data sources. For example, you may
need to correlate two data sets to achieve your broader goal.
Often this indicates the presence of a Discover goal.
In addition to problem decomposition providing a tractable approach
to analytic selection, it has the added benefit of simplifying a highly
complex problem. Rather than being faced with understanding the
entire end-to-end solution, the computations are discrete segments
that can be explored. Note, however, that while this technique helps
the Data Scientist approach the problem, it is the complete end-to-
end solution that must be evaluated.
One of your ﬁrst steps should be to
explore available data sources that
have not been previously combined.
Emerging relationships between data
sources often allow you to pick low
hanging fruit.

Compare
Datasets
List of
recently
registered
company
domains
List of
candidate
spoofed
domains
List of
recently
registered
company
domains
Discover spoofed
domains
Test &
Evaluation
Test &
Evaluation
Test &
Evaluation
Calculate
Metric
Set
Threshold
Data
Collection
Simulate
Spoofed
Data
Store
Generated
Domains
Generate
Candidate
Domains
Alert on spoofed domains to
provide opportuinity to
minimize brand image and
consumer confidence damage
Discover likely
candidates for
spoofed domains
List of candidate
spoofed domains
List of recently
registered
company domains
Describe closeness of
spoof to valid domains
Quantitative
measure of feature
information value
Threshold that balances
false positive and false
negative rate
Quantitative threshold for
automated result ranking
›
›
List of candidate spoofed
domains
List of recently registered
company domains
Quantitative measure of
feature information value
›
›
›
Stephanie
Rivera
Identifying Spoofed Domains
Identifying spoofed domains is important for an organization
to preserve their brand image and to avoid eroded customer
confidence. Spoofed domains occur when a malicious actor
creates a website, URL or email address that users believe is
associated with a valid organization. When users click the link,
visit the website or receive emails, they are subjected to some
type of nefarious activity.
Our team was faced with the problem of
identifying spoofed domains for a commercial
company. On the surface, the problem sounded
easy; take a recently registered domain, check
to see if it is similar to the company’s domain
and alert when the similarity is sufficiently high.
Upon decomposing the problem, however, the
main computation quickly became complicated.
We needed a computation that determined
similarity between two domains. As we
decomposed the similarity computation,
complexity and speed became a concern.
As with many security-related problems, fast
alert speeds are vital. Result speed created
an implementation constraint that forced us to
re-evaluate how we decomposed the problem.
Revisiting the decomposition process led us
to a completely new approach. In the end,
we derived a list of domains similar to those
registered by the company. We then compared
that list against a list of recently registered
domains. The figure, Spoofed Domain Problem
Decomposition, illustrates our approach. Upon
testing and initial deployment, our analytic
discovered a spoofed domain within 48 hours.
››
Spoofed Domain Problem Decomposition

SPEED: The speed at which an
analytic outcome must be produced
(e.g., near real-time, hourly, daily) or the time
it takes to develop and implement the
analytic solution
ANALYTIC COMPLEXITY:
Algorithmic complexity (e.g., complexity class
and execution resources)
ACCURACY & PRECISION: The ability
to produce exact versus approximate
solutions as well as the ability to provide a
DATA SIZE: The size of the data set
(e.g., number of rows)
DATA COMPLEXITY: The data
type, formal complexity measures
including measures of overlap and
linear separability, number of
dimensions /columns, and linkages
between data sets
SPEED
ANALYTIC
COMPLEXITY
DATA
COMPLEXITY
ACCURACY
&
PRECISION
DATA SIZE
Implementation Constraints
In the spoofed domains case study, the emergence of an
implementation constraint caused the team to revisit its approach.
This demonstrates that analytic selection does not simply mean
choosing an analytic technique to achieve a desired outcome. It also
means ensuring that the solution is feasible to implement.
The Data Scientist may encounter a wide variety of implementation
constraints.They can be conceptualized, however, in the context of
five dimensions that compete for your attention: analytic complexity,
speed, accuracy & precision, data size, and data complexity. Balancing
these dimensions is a zero sum game - an analytic solution cannot
simultaneously exhibit all five dimensions, but instead must make
trades between them.The figure, Balancing the Five Analytic
Dimensions, illustrates this relationship.
Implementation constraints occur when an aspect of the problem
dictates the value for one or more of these dimensions. As soon as
one dimension is fixed, the Data Scientist is forced to make trades
among the others. For example, if the analytic problem requires
actions to be produced in near real-time, the speed dimension is
fixed and trades must be made among the other four dimensions.
Understanding which trades will achieve the right balance among
the five dimensions is an art that must be learned over time.
As we compiled this section, we
talked extensively about ways to
group and classify implementation
constraints. After much discussion
we settled on these five dimensions.
We present this model in hopes
that others weigh in and offer
their own perspectives.
Balancing the Five Analytic Dimensions

Some common examples of implementation
constraints include:
• Computation frequency. The solution may need to run on a regular
basis (e.g., hourly), requiring that computations be completed
within a specified window of time.The best analytic is useless if it
cannot solve the problem within the required time.
• Solution timeliness. Some applications require near real-time
results, pointing toward streaming approaches. While some
algorithms can be implemented within streaming frameworks,
many others cannot.
• Implementation speed. A project may require that you rapidly
develop and implement a solution to quickly produce analytic
insights. In these cases, you may need to focus on less complex
techniques that can be quickly implemented and verified.
• Computational resource limitations. Although you may be able
to store and analyze your data, data size may be sufficiently large
that algorithms requiring multiple computations across the full
data set are too resource intensive.This may point toward needing
approaches that only require a single pass on the data (e.g., canopy
cluster as opposed to k-means clustering).
• Data storage limitations.There are times when big data becomes
so big it cannot be stored or only a short time horizon can be
stored. Analytic approaches that require long time horizons may
not be possible.
Organizational policies and regulatory requirements are a major
source of implicit constraints that merit a brief discussion. Policies
are often established around specific classes of data such as Personally
Identifiable Information (PII) or Personal Health Information (PHI).
While the technologies available today can safely house information
with a variety of security controls in a single system, these policies
force special data handling considerations including limited retention
periods and data access. Data restrictions impact the data size and
complexity dimensions outlined earlier, creating yet another layer of
constraints that must be considered.
When possible, consider approaches
that make use of previously computed
results. Your algorithm will run
much faster if you can avoid
re-computing values across
the full time horizon of data.
Our Data Science Product Lifecycle
has evolved to produce results quickly
and then incrementally improve
the solution.
Streaming approaches may be useful
for overcoming storage limitations.

4
Data
Science
3
DESCRIBE
DISCOVER
PREDICT
ADVISE
PAGE 67
PAGE 68
PAGE 69
PAGE 70
2
1
Guide to Analytic Selection
Your senses are incapable of perceiving the entire universe, so
we drew you a map.
The universe of analytic techniques is vast and hard to comprehend.
We created this diagram to aid you in finding your way from data
and goal to analytic action. Begin at the center of the universe
(Data Science) and answer questions about your analytic goals and
problem characteristics.The answers to your questions will guide you
through the diagram to the appropriate class of analytic techniques
and provide recommendations for a few techniques to consider.
TIP: There are several situations where dimensionality reduction may be needed:
› Models fail to converge
› Models produce results equivalent to
random chance
› You lack the computational power to
perform operations across the
feature space
› You do not know which aspects of the
data are the most important
Feature Extraction is a broad topic and is highly dependent upon the domain area.
This topic could be the subject of an entire book. As a result, a detailed exploration
has been omitted from this diagram. See the Featuring Engineering and Feature
Selection sections in the Life in the Trenches chapter for additional information.
TIP: Always check data labels for correctness. This is particularly true for time
stamps, which may have reverted to system default values.
TIP: Smart enrichment can greatly speed computational time. It can also be a huge
differentiator between the accuracy of different end-to-end analytic solutions.

Data
Science
FILTERING
How do I identify
data based on
its absolute or
relative values?
IMPUTATION
How do I fill in
missing values
in my data?
DIMENSIONALITY
REDUCTION
How do I reduce
the number of
dimensions
in my data?
NORMALIZATION &
TRANSFORMATION
How do I reconcile
duplication
representations
in the data?
FEATURE
EXTRACTION
PROCESSING
How do I clean
and separate
my data?
If you want to add or remove data based on its value, start with:
› Relational algebra projection and selection
If early results are uninformative and duplicative, start with:
› Outlier removal › Gaussian filter
› Exponential smoothing › Median filter
If you are unfamiliar with the data set, start with
basic statistics:
› Count › Standard deviation › Box plots
› Mean › Range › Scatter plots
If your approach assumes the data follows a
distribution, start with:
› Distribution fitting
If you want to understand all the information
available on an entity, start with:
› “Baseball card” aggregation
If you need to keep track of source information or other
user-defined parameters, start with:
› Annotation
If you often process certain data fields together or use
one field to compute the value of another, start with:
› Relational algebra rename,
› Feature addition (e.g., Geography, Technology, Weather)
If you want to generate values from other observations in your data set, start with:
› Random sampling
› Markov Chain Monte Carlo (MC)
If you want to generate values without using other observations in your data set,
start with:
› Mean › Regression models
› Statistical distributions
If you need to determine whether there is multi-dimensional correlation,
start with:
› PCA and other factor analysis
If you can represent individual observations by membership in a group, start with:
› K-means clustering
› Canopy clustering
If you have unstructured text data, start with:
› Term Frequency/Inverse Document Frequency (TF IDF)
If you have a variable number of features but your
algorithm requires a fixed number, start with:
› Feature hashing
If you are not sure which features are the most important, start with:
› Wrapper methods
› Sensitivity analysis
If you need to facilitate understanding of the
probability distribution of the space, start with:
› Self organizing maps
If you suspect duplicate data elements, start with:
› Deduplication
If you want your data to fall within a specified range, start with:
› Normalization
If your data is stored in a binary format, start with:
› Format Conversion
If you are operating in frequency space, start with:
› Fast Fourier Transform (FFT),
› Discrete wavelet transform
If you are operating in Euclidian space, start with:
› Coordinate transform
DESCRIBE
How do I develop
an understanding
of the content of
my data?
ENRICHMENT
How do I add
new information
to my data?
AGGREGATION
How do I collect
and summarize
my data?
1
2
4
3
PREDICT
DISCOVER
ADVISE

If you want an ordered set of clusters with variable precision, start with:
› Hierarchical
If you have an unknown number of clusters, start with:
› X-means
› Canopy
If you have text data, start with:
› Topic modeling
If you have non-elliptical clusters, start with:
› Fractal
› DB Scan
If you want soft membership in the clusters, start with:
› Gaussian mixture models
If you have an known number of clusters, start with:
› K-means
If your data has unknown structure, start with:
› Tree-based methods
If statistical measures of importance are needed,
start with:
› Generalized linear models
If statistical measures of importance are not needed,
start with:
› Regression with shrinkage (e.g., LASSO, Elastic net)
› Stepwise regression
2
DISCOVER
What are the
key relationships
in the data?
REGRESSION
How do I
determine which
variables may be
important?
CLUSTERING
How do I segment
the data to
ﬁnd natural
groupings?
1
DESCRIBE
Data
Science
4
3
PREDICT
ADVISE
TIP: Canopy clustering is good when you only want to make a single pass
over the data.
TIP: Use canopy or hierarchical clustering to estimate the number of clusters
you should generate.

If you are unsure of feature importance, start with:
› Neural nets,
› Random forests
If you require a highly transparent model, start with:
› Decision trees
If you have <20 data dimensions, start with:
› K-nearest neighbors
If you have a large data set with an unknown classification signal, start with:
› Naive Bayes
If you want to estimate an unobservable state based on observable variables, start with:
› Hidden Markov model
If you don't know where else to begin, start with:
› Support Vector Machines (SVM)
› Random forests
If the data structure is unknown, start with:
› Tree-based methods
If you require a highly transparent model, start with:
› Generalized linear models
If you have <20 data dimensions, start with:
› K-nearest neighbors
PREDICT
What are the
likely future
outcomes?
REGRESSION
How do I predict
a future value?
If you only have knowledge of how people interact with items,
start with:
› Collaborative filtering
If you have a feature vector of item characteristics, start with:
› Content-based methods
If you only have knowledge of how items are connected to one
another, start with:
› Graph-based methods
RECOMMENDATION
How do I predict
relevant conditions?
CLASSIFICATION
How do I
predict group
membership?
3
2
DISCOVER
1
DESCRIBE
Data
Science
4
ADVISE
TIP: It can be difficult to predict which classifier will work best on your data set.
Always try multiple classifiers. Pick the one or two that work the best to refine and
explore further.
TIP: These are our favorite, go-to classification algorithms.
TIP: Be careful of the "recommendation bubble", the tendency of recommenders to
recommend only what has been seen in the past. You must ensure you add diversity to
avoid this phenomenon.
TIP: SVD and PCA are good tools for creating better features for recommenders.

If your problem is represented by a
non-deterministic utility function, start with:
› Stochastic search
If approximate solutions are acceptable,
start with:
› Genetic algorithms
› Simulated annealing
› Gradient search
If your problem is represented by a
deterministic utility function, start with:
› Linear programming
› Integer programming
› Non-linear programming
ADVISE
What course
of action
should I take?
OPTIMIZATION
How do I identify the
best course of action
when my objective
can be expressed as
a utility function?
If you must model discrete entities, start with:
› Discrete Event Simulation (DES)
If there are a discrete set of possible states, start with:
› Markov models
If there are actions and interactions among autonomous
entities, start with:
› Agent-based simulation
If you do not need to model discrete entities, start with:
› Monte Carlo simulation
If you are modeling a complex system with feedback
mechanisms between actions, start with:
› Systems dynamics
If you require continuous tracking of system behavior,
start with:
› Activity-based simulation
If you already have an understanding of what factors
govern the system, start with:
› ODES
› PDES
RECOMMENDATION
How do I predict
relevant conditions?
4
2
DISCOVER
1
DESCRIBE
Data
Science
3
PREDICT

Compiled by: Booz Allen Hamilton
Algorithms or
Method Name
Description Tips From the Pros
References and Papers
We Love to Read
Agent Based
Simulation
Simulates the actions
and interactions of
autonomous agents.
In many systems, complex behavior
results from surprisingly simple rules.
Keep the logic of your agents simple
and gradually build in sophistication.
Macal, Charles, and Michael
North. “Agent-based Modeling
and Simulation.” Winter
Simulation Conference. Dec.
2009. Print.
Collaborative
Filtering
Also known as
'Recommendation,' suggest
or eliminate items from a
set by comparing a history
of actions against items
performed by users. Finds
similar items based on who
used them or similar users
based on the items they use.
Use Singular Value Decomposition
based Recommendation for cases
where there are latent factors in your
domain, e.g., genres in movies.
Owen, Sean, Robin Anil, Ted
Dunning, and Ellen Friedman.
Mahout in Action. New Jersey:
Manning, 2012. Print.
Coordinate
Transforma-
tion
Provides a different
perspective on data.
Changing the coordinate system for data, for
example, using polar or cylindrical coordinates,
may more readily highlight key structure in the
data. A key step in coordinate transformations
is to appreciate multidimensionality and to
systematically analyze subspaces of the data.
Abbott, Edwin. A. Flatland: A
Romance of Many Dimensions.
United Kingdom: Seely & Co,
1884. Print.
Design of
Experiments
Applies controlled
experiments to quantify
effects on system output
caused by changes to inputs.
Fractional factorial designs can signiﬁcantly
reduce the number of different types of
experiments you must conduct.
Montgomery, Douglas. Design
and Analysis of Experiments.
New Jersey: John Wiley
& Sons, 2012. Print.
Detailed Table of Analytics
Getting you to the right starting point isn’t enough. We also
provide a translator so you understand what you’ve been told.
Identifying several analytic techniques that can be applied to your
problem is useful, but their name alone will not be much help.The
Detailed Table of Analytics translates the names into something more
meaningful. Once you’ve identified a technique in the Guide to
Analytic Selection, find the corresponding row in the table.There you
will find a brief description of the techniques, tips we’ve learned and a
few references we’ve found helpful.

Algorithms or
Method Name
We Love to Read
Differential
Equations
Used to express
relationships between
functions and their
derivatives, for example,
change over time.
Differential equations can be used to formalize
models and make predictions. The equations
themselves can be solved numerically and
tested with different initial conditions to study
system trajectories.
Zill, Dennis, Warren Wright,
and Michael Cullen. Differential
Equations with Boundary-Value
Problems. Connecticut: Cengage
Learning, 2012. Print.
Discrete Event
Simulation
Simulates a discrete
sequence of events where
each event occurs at a
particular instant in time.
The model updates its state
only at points in time when
events occur.
Discrete event simulation is useful when
analyzing event based processes such as
production lines and service centers to
determine how system level behavior changes
as different process parameters change.
Optimization can integrate with simulation to
gain efficiencies in a process.
Cassandras, Christopher, and
Stephanie Lafortune. Introduction
to Discrete Event Systems. New
York: Springer, 1999. Print.
Discrete
Wavelet
Transform
Transforms time series
data into frequency
domain preserving
locality information.
Offers very good time and frequency
localization. The advantage over Fourier
transforms is that it preserves both frequency
and locality.
Burrus, C.Sidney, Ramesh A.
Gopinath, Haitao Guo, Jan E.
Odegard, and Ivan W. Selesnick.
Introduction to Wavelets
and Wavelet Transforms:
A Primer. New Jersey:
Prentice Hall, 1998. Print.
Exponential
Smoothing
Used to remove artifacts
expected from collection
error or outliers.
In comparison to a using moving average
where past observations are weighted equally,
exponential smoothing assigns exponentially
decreasing weights over time.
Chatfield, Chris, Anne B. Koehler,
J. Keith Ord, and Ralph D.
Snyder. “A New Look at Models
for Exponential Smoothing.”
Journal of the Royal Statistical
Society: Series D (The Statistician)
50.2 (July 2001): 147-159. Print.
Factor
Analysis
Describes variability among
correlated variables with the
goal of lowering the number
of unobserved variables,
namely, the factors.
If you suspect there are inmeasurable
influences on your data, then you may want to
try factor analysis.
Child, Dennis. The Essentials of
Factor Analysis. United Kingdom:
Cassell Educational, 1990. Print.
Fast Fourier
Transform
Transforms time series from
time to frequency domain
efficiently. Can also be used
for image improvement by
spatial transforms.
Filtering a time varying signal can be done
more effectively in the frequency domain. Also,
noise can often be identified in such signals by
observing power at aberrant frequencies.
Mitra, Partha P., and Hemant
Bokil. Observed Brain Dynamics.
United Kingdom: Oxford
University Press, 2008. Print.
Format
Conversion
Creates a standard
representation of data
regardless of source format.
For example, extracting raw
UTF-8 encoded text from
binary file formats such as
Microsoft Word or PDFs.
There are a number of open source software
packages that support format conversion and
can interpret a wide variety of formats. One
notable package is Apache Tikia.
Ingersoll, Grant S., Thomas S.
Morton, and Andrew L. Farris.
Taming Text: How to Find,
Organize, and Manipulate It. New
Jersey: Manning, 2013. Print.
Gaussian
Filtering
Acts to remove noise
or blur data.
Can be used to remove speckle
noise from images.
Parker, James R. Algorithms for
Image Processing and Computer
Vision. New Jersey: John Wiley &
Sons, 2010. Print.
Generalized
Linear Models
Expands ordinary linear
regression to allow
for error distribution
that is not normal.
Use if the observed error in your system does
not follow the normal distribution.
MacCullagh, P., and John A.
Nelder. Generalized Linear
Models. Florida: CRC Press,
1989. Print.
Genetic
Algorithms
Evolves candidate
models over generations
by evolutionary
inspired operators of
mutation and crossover
of parameters.
Increasing the generation size adds diversity
in considering parameter combinations, but
requires more objective function evaluation.
Calculating individuals within a generation
is strongly parallelizable. Representation of
candidate solutions can impact performance.
De Jong, Kenneth A. Evolutionary
Computation - A Unified
Approach. Massachusetts:
MIT Press, 2002. Print.
Grid Search
Systematic search across
discrete parameter
values for parameter
exploration problems.
A grid across the parameters is used to
visualize the parameter landscape and assess
whether multiple minima are present.
Kolda, Tamara G., Robert M.
Lewis, and Virginia Torczon.
“Optimization by Direct Search:
New Perspectives on Some
Classical and Modern Methods.”
SIAM Review 45.3 (2003): 385-
482. Print.

Algorithms or
Method Name
We Love to Read
Hidden Markov
Models
Models sequential data by
determining the discrete
latent variables, but
the observables may be
continuous or discrete.
One of the most powerful properties of Hidden
Markov Models is their ability to exhibit
some degree of invariance to local warping
(compression and stretching) of the time axis.
However, a signiﬁcant weakness of the Hidden
Markov Model is the way in which it represents
the distribution of times for which the system
remains in a given state.
Bishop, Christopher M. Pattern
Recognition and Machine
Learning. New York: Springer,
2006. Print.
Hierarchical
Clustering
Connectivity based
clustering approach
that sequentially builds
bigger (agglomerative)
or smaller (divisive)
clusters in the data.
Provides views of clusters at multiple
resolutions of closeness. Algorithms
begin to slow for larger data sets due
to most implementations exhibiting
O(N3
) or O(N2
) complexity.
Rui Xu, and Don Wunsch.
Clustering. New Jersey: Wiley-
IEEE Press, 2008. Print.
K-means
and X-means
Clustering
Centroid based clustering
algorithms, where with
K means the number
of clusters is set and X
means the number of
clusters is unknown.
When applying clustering techniques, make
sure to understand the shape of your data.
Clustering techniques will return poor results if
your data is not circular or ellipsoidal shaped.
Rui Xu, and Don Wunsch.
Clustering. New Jersey: Wiley-
IEEE Press, 2008. Print.
Linear,
Non-linear,
and Integer
Programming
Set of techniques for
minimizing or maximizing a
function over a constrained
set of input parameters.
Start with linear programs because algorithms
for integer and non-linear variables can take
much longer to run.
Winston, Wayne L. Operations
Research: Applications and
Algorithms. Connecticut:
Cengage Learning, 2003. Print.
Markov Chain
Monte Carlo
(MCMC)
A method of sampling
typically used in Bayesian
models to estimate the joint
distribution of parameters
given the data.
Problems that are intractable using analytic
approaches can become tractable using MCMC,
when even considering high-dimensional
problems. The tractability is a result of using
statistics on the underlying distributions of
interest, namely, sampling with Monte Carlo and
considering the stochastic sequential process of
Markov Chains.
Andrieu, Christophe, Nando
de Freitas, Amaud Doucet,
and Michael I. Jordan. “An
Introduction to MCMC for
Machine Learning.” Machine
Learning, 50.1 (January 2003):
5-43. Print.
Monte Carlo
Methods
Set of computational
techniques to generate
random numbers.
Particularly useful for numerical integration,
solutions of differential equations, computing
Bayesian posteriors, and high dimensional
multivariate sampling.
Fishman, George S. Monte
Carlo: Concepts, Algorithms, and
Applications. New York: Springer,
2003. Print.
Naïve Bayes
Predicts classes following
Bayes Theorem that
states the probability of
an outcome given a set of
features is based on the
probability of features given
an outcome.
Assumes that all variables are independent,
so it can have issues learning in the context of
highly interdependent variables. The model can
be learned on a single pass of data using simple
counts and therefore is useful in determining
whether exploitable patterns exist in large data
sets with minimal development time.
Neural
Networks
Learns salient features in
data by adjusting weights
between nodes through a
learning rule.
Training a neural network takes substantially
longer than evaluating new data with an already
trained network. Sparser network connectivity
can help to segment the input space and
improve performance on classiﬁcation tasks.
Haykin, Simon O. Neural
Networks and Learning
Machines. New Jersey:
Outlier
Removal
Method for identifying and
removing noise or artifacts
from data.
Be cautious when removing outliers. Sometimes
the most interesting behavior of a system is at
times when there are aberrant data points.
Maimon, Oded, and Lior
Rockach. Data Mining and
Knowledge Discovery Handbook: A
Complete Guide for Practitioners
and Researchers. The
Netherlands: Kluwer Academic
Publishers, 2005. Print.
Principal
Components
Analysis
Enables dimensionality
reduction by identifying
highly correlated
dimensions.
Many large datasets contain correlations
between dimensions; therefore part of the
dataset is redundant. When analyzing the
resulting principal components, rank order
them by variance as this is the highest
information view of your data. Use skree plots to
infer the optimal number of components.
Wallisch, Pascal, Michael E.
Lusignan, Marc D. Benayoun,
Tanya I. Baker, Adam Seth
Dickey, and Nicholas G.
Hatsopoulos. Matlab for
Neuroscientists. New Jersey:

Algorithms or
Method Name
We Love to Read
Regression
with Shrinkage
(Lasso)
A method of variable
selection and prediction
combined into a possibly
biased linear model.
There are different methods to select the
lambda parameter. A typical choice is cross
validation with MSE as the metric.
Tibshirani, Robert. “Regression
Shrinkage and Selection
via the Lasso.” Journal of
the Royal Statistical Society.
Series B (Methodological) 58.1
(1996): 267-288. Print.
Sensitivity
Analysis
Involves testing individual
parameters in an analytic
or model and observing the
magnitude of the effect.
Insensitive model parameters during an
optimization are candidates for being set to
constants. This reduces the dimensionality
of optimization problems and provides an
opportunity for speed up.
Saltelli, A., Marco Ratto, Terry
Andres, Francesca Campolongo,
Jessica Cariboni, Debora Gatelli,
Michaela Saisana, and Stefano
Tarantola. Global Sensitivity
Analysis: the Primer. New Jersey:
John Wiley & Sons, 2008. Print.
Simulated
Annealing
Named after a controlled
cooling process in
metallurgy, and by
analogy using a changing
temperature or annealing
schedule to vary
algorithmic convergence.
The standard annealing function allows for
initial wide exploration of the parameter space
followed by a narrower search. Depending on
the search priority the annealing function can
be modified to allow for longer explorative
search at a high temperature.
Bertsimas, Dimitris, and John
Tsitsiklis. “Simulated Annealing.”
Statistical Science. 8.1 (1993):
10-15. Print.
Stepwise
Regression
A method of variable
selection and prediction.
Akaike's information
criterion AIC is used as
the metric for selection.
The resulting predictive
model is based upon
ordinary least squares,
or a general linear model
with parameter estimation
via maximum likelihood.
Caution must be used when considering
Stepwise Regression, as over fitting often
occurs. To mitigate over fitting try to limit the
number of free variables used.
Hocking, R. R. “The Analysis and
Selection of Variables in Linear
Regression.” Biometrics. 32.1
(March 1976): 1-49. Print.
Stochastic
Gradient
Descent
General-purpose
optimization for learning of
neural networks, support
vector machines, and
logistic regression models.
Applied in cases where the objective
function is not completely differentiable
when using sub-gradients.
Witten, Ian H., Eibe Frank,
and Mark A. Hall. Data Mining:
Practical Machine Learning Tools
and Techniques. Massachusetts:
Morgan Kaufmann, 2011. Print.
Support Vector
Machines
Projection of feature vectors
using a kernel function into
a space where classes are
more separable.
Try multiple kernels and use k-fold cross
validation to validate the choice of the best one.
Hsu, Chih-Wei, Chih-Chung
Chang, and Chih-Jen Lin. “A
Practical Guide to Support Vector
Classification.” National Taiwan
University. 2003. Print.
Term
Frequency
Inverse
Document
Frequency
A statistic that measures
the relative importance of a
term from a corpus.
Typically used in text mining. Assuming a
corpus of news articles, a term that is very
frequent such as “the” will likely appear many
times in many documents, having a low value. A
term that is infrequent such as a person’s last
name that appears in a single article will have a
higher TD IDF score.
Topic Modeling
(Latent
Dirichlet
Allocation)
Identifies latent topics
in text by examining
word co-occurrence.
Employ part-of-speech tagging to eliminate
words other than nouns and verbs. Use raw
term counts instead of TF/IDF weighted terms.
Blei, David M., Andrew Y. Ng,
and Michael I Jordan. “Latent
Dirichlet Allocation.” Journal of
Machine Learning Research. 3
(March 2003): 993-1022. Print.
Tree Based
Methods
Models structured as graph
trees where branches
indicate decisions.
Can be used to systematize a process or act as
a classifier.
James, G., D. Witten, T. Hastie,
and R Tibshirani. Tree-Based
Methods. In An Introduction to
Statistical Learning. New York:
Springer, 2013. Print.
Wrapper
Methods
Feature set reduction
method that utilizes
performance of a set of
features on a model, as
a measure of the feature
set’s performance. Can
help identify combinations
of features in models that
achieve high performance.
Utilize k-fold cross validation
to control over fitting.
John, G. H, R Kohavi, and K.
Pfleger. “Irrelevant Features
and the Subset Selection
Problem.” Proceedings of
ICML-94, 11th International
Conference on Machine
Learning. New Brunswick,
New Jersey. 1994. 121-129.
59. Conference Presentation.

LIFE in T H E T R E N C H E S
NAVIGATING NECK DEEP IN DATA
Our Data Science experts have learned
and developed new solutions over the years
from properly framing or reframing analytic
solutions. In this section, we list a few
important topics to Data Science coupled
with firsthand experience from our experts.

Feature Engineering
Feature engineering is a lot like oxygen. You can’t do without
it, but you rarely give it much thought.
Feature engineering is the process by which one establishes the
representation of data in the context of an analytic approach. It is the
foundational skill in Data Science. Without feature engineering, it
would not be possible to understand and represent the world through
a mathematical model. Feature engineering is a challenging art. Like
other arts, it is a creative process that manifests uniquely in each
Data Scientist. It will be influenced substantially by the scientist’s
experiences, tastes and understanding of the field.
As the name suggests, feature engineering can be a complex task
that may involve chaining and testing different approaches. Features
may be simple such as “bag of words,” a popular technique in the
text processing domain, or or may be based on more complex
representations derived through activities such as machine learning.
You make use of the output of one analytic technique to create the
representation that is consumed by another. More often than not, you
will find yourself operating in the world of highly complex activities.

››
Ed Kohlwey
Chemoinformatic Search
On one assignment, my
team was confronted
with the challenge of
developing a search
engine over chemical
compounds. The goal
of chemoinformatic
search is to predict
the properties that
a molecule will exhibit as well as to
provide indices over those predicted
properties to facilitate data discovery
in chemistry-based research. These
properties may either be discreet (e.g.,
“a molecule treats disease x well”)
or continuous (e.g., “a molecule may
be dissolved up to 100.21 g/ml”).
Molecules are complex 3D structures,
which are typically represented as
a list of atoms joined by chemical
bonds of differing lengths with varying
electron domain and molecular
geometries. The structures are
specified by the 3-space coordinates
and the electrostatic potential
surface of the atoms in the molecule.
Searching this data is a daunting
task when one considers that
naïve approaches to the problem
bear significant semblance to the
Graph Isomorphism Problem.[13]
The solution we developed was
based on previous work in molecular
fingerprinting (sometimes also called
hashing or locality sensitive hashing).
Fingerprinting is a dimensionality
reduction technique that dramatically
reduces the problem space by
summarizing many features, often
with relatively little regard to the
importance of the feature. When
an exact solution is likely to be
infeasible, we often turn to heuristic
approaches such as fingerprinting.
Our approach used a training set
where all the measured properties
of the molecules were available. We
created a model of how molecular
structural similarities might affect
their properties. We began by
finding all the sub-graphs of each
molecule with length n, resulting
in a representation similar to
the bag-of-words approach from
natural language processing.
We summarized each molecule
fragment in a type of fingerprint
called a “Counting Bloom Filter.”
Next, we used several exemplars from
the set to create new features. We
found the distance from each member
of the full training set to each of the
exemplars. We fed these features into
a non-linear regression algorithm
to yield a model that could be used
on data that was not in the original
training set. This approach can be
conceptualized as a “hidden manifold,”
whereby a hidden surface or shape
defines how a molecule will exhibit a
property. We approximate this shape
using a non-linear regression and a
set of data with known properties.
Once we have the approximate
shape, we can use it to predict the
properties of new molecules.
Our approach was multi-staged and
complex – we generated sub-graphs,
created bloom filters, calculated
distance metrics and fit a linear-
regression model. This example
provides an illustration of how many
stages may be involved in producing a
sophisticated feature representation.
By creatively combining and building
“features on features,” we were able
to create new representations of data
that were richer and more descriptive,
yet were able to execute faster and
produce better results.
79Life in the Trenches

Feature Selection
Models are like honored guests; you should only feed them the
good parts.
Feature selection is the process of determining the set of features with
the highest information value to the model.Two main approaches are
filtering and wrapper methods. Filtering methods analyze features
using a test statistic and eliminate redundant or non-informative
features. As an example, a filtering method could eliminate features
that have little correlation to the class labels. Wrapper methods
utilize a classification model as part of feature selection. A model is
trained on a set of features and the classification accuracy is used to
measure the information value of the feature set. One example is that
of training a neural network with a set of features and evaluating the
accuracy of the model. If the model scores highly on the test set, then
the features have high information value. All possible combinations of
features are tested to find the best feature set.
There are tradeoffs between these techniques. Filtering methods
are faster to compute since each feature only needs to be compared
against its class label. Wrapper methods, on the other hand, evaluate
feature sets by constructing models and measuring performance.This
requires a large number of models to be trained and evaluated (a
quantity that grows exponentially in the number of features). Why
would anyone use a wrapper method? Feature sets may perform better
than individual features.[14]
With filter methods, a feature with weak
correlation to its class labels is eliminated. Some of these eliminated
features, however, may have performed well when combined with
other features.

››
Paul Yacci
Cancer Cell Classification
On one project,
our team was
challenged
to classify
cancer cell
profiles. The
overarching
goal was
to classify different types
of Leukemia, based on
Microarray profiles from 72
samples[15]
using a small
set of features. We utilized
a hybrid Artificial Neural
Network (ANN)[16]
and Genetic
Algorithm[17]
to identify subsets
of 10 features selected from
thousands.[18]
We trained the
ANN and tested performance
using cross-fold validation.
The performance measure
was used as feedback into
the Genetic Algorithm. When
a set of features contained
no useful information, the
model performed poorly and
a different feature set would
be explored. Over time, this
method selected a set of
features that performed with
high accuracy. The down-
selected feature set increased
speed and performance as
well as allowed for better
insight into the factors that
may govern the system. This
allowed our team to design
a diagnostic test for only a
few genetic markers instead
of thousands, substantially
reducing diagnostic test
complexity and cost.

Data Veracity
We’re Data Scientists, not data alchemists. We can’t make
analytic gold from the lead of data.
While most people associate data volume, velocity, and variety with
big data, there is an equally important yet often overlooked dimension
– data veracity. Data veracity refers to the overall quality and
correctness of the data. You must assess the truthfulness and accuracy
of the data as well as identify missing or incomplete information. As
the saying goes, “Garbage in, garbage out.” If your data is inaccurate or
missing information, you can’t hope to make analytic gold.
Assessing data truthfulness is often subjective. You must rely on your
experience and an understanding of the data origins and context.
Domain expertise is particularly critical for the latter. Although
data accuracy assessment may also be subjective, there are times that
quantitative methods may be used. You may be able to re-sample from
the population and conduct a statistical comparison against the stored
values, thereby providing measures of accuracy.
The most common issues you will encounter are missing or
incomplete information.There are two basic strategies for dealing
with missing values – deletion and imputation. In the former, entire
observations are excluded from analysis, reducing sample size and
potentially introducing bias. Imputation, or replacement of missing
or erroneous values, uses a variety of techniques such as random
sampling (hot deck imputation) or replacement using the mean,
statistical distributions or models.
»Tips From the Pros
Find an approach that works,
implement it, and move on. You
can worry about optimization and
tuning your approaches later during
incremental improvement.

Brian Keller
›› Time Series Modeling
On one of our projects, the team was faced with correlating the time
series for various parameters. Our initial analysis revealed that the
correlations were almost non-existent. We examined the data and
quickly discovered data veracity issues. There were missing and
null values, as well as negative-value observations, an impossibility
given the context of the measurements (see the figure, Time Series
Data Prior to Cleansing). Garbage data meant garbage results.
Because sample size was already small, deleting
observations was undesirable. The volatile nature
of the time series meant that imputation through
sampling could not be trusted to produce values
in which the team would be confident. As a result,
we quickly realized that the best strategy was an
approach that could filter and correct the noise in
the data.
We initially tried a simplistic approach in which we
replaced each observation with a moving average.
While this corrected some noise, including the
outlier values in our moving-average computation
shifted the time series. This caused undesirable
distortion in the underlying signal, and we quickly
abandoned the approach.
One of our team members who had experience in
signal processing suggested a median filter. The
median filter is a windowing technique that moves
through the data point-by-point, and replaces it
with the median value calculated for the current
window. We experimented with various window
sizes to achieve an acceptable tradeoff between
smoothing noise and smoothing away signal. The
figure, Time Series Data After Cleansing, shows the
same two time series after median filter imputation.
The application of the median filter approach was
hugely successful. Visual inspection of the time
series plots reveals smoothing of the outliers
without dampening the naturally occurring peaks
and troughs (no signal loss). Prior to smoothing,
we saw no correlation in our data, but afterwards,
Spearman’s Rho was ~0.5 for almost all parameters.
By addressing our data veracity issues, we were
able to create analytic gold. While other approaches
may also have been effective, implementation speed
constraints prevented us from doing any further
analysis. We achieved the success we were after and
moved on to address other aspects of the problem.
Time Series Data Prior to Cleansing
Time Series Data After Cleansing

Application of
Domain Knowledge
We are all special in our own way. Don’t discount what
you know.
Knowledge of the domain in which a problem lies is immensely
valuable and irreplaceable. It provides an in-depth understanding
of your data and the factors influencing your analytic goal. Many
times domain knowledge is a key differentiator to a Data Science
team’s success. Domain knowledge influences how we engineer and
select features, impute data, choose an algorithm, and determine
success. One person cannot possibly be a domain expert in every
field, however. We rely on our team, other analysts and domain
experts as well as consult research papers and publications to build
an understanding of the domain.

››
GEOSPATIAL HOTSPOTS
TEMPORAL HOTSPOT
Sun
Sat
Fri
Thu
Wed
Tue
Mon
9pm6pm3pmNoon9am6am3am
9pm6pm3pmNoon9am6am3am
Armen
Kherlopian
Motor Vehicle Theft
On one project,
our team explored
how Data Science
could be applied to
improve public safety.
According to the
FBI, approximately
$8 Billion is lost
annually due to
automobile theft. Recovery of the
one million vehicles stolen every
year in the U.S. is less than 60%.
Dealing with these crimes represents
a significant investment of law
enforcement resources. We wanted
to see if we could identify how to
reduce auto theft while efficiently
using law enforcement resources.
Our team began by parsing and
verifying San Francisco crime data.
We enriched stolen car reporting with
general city data. After conducting
several data experiments across both
space and time, three geospatial and
one temporal hotspot emerged (see
figure, Geospatial and Temporal Car
Theft Hotspots). The domain expert
on the team was able to discern
that the primary geospatial hotspot
corresponded to an area surrounded
by parks. The parks created an urban
mountain with a number of over-foot
access points that were conducive to
car theft.
Our team used the temporal hotspot information in tandem with the insights
from the domain expert to develop a Monte Carlo model to predict the likelihood
of a motor vehicle theft at particular city intersections. By prioritizing the
intersections identified by the model, local governments would have the
information necessary to efficiently deploy their patrols. Motor vehicle thefts
could be reduced and law enforcement resources could be more efficiently
deployed. The analysis, enabled by domain expertise, yielded actionable insights
that could make the streets safer.
Geospatial and Temporal Car Theft Hotspots

The Curse of
Dimensionality
There is no magical potion to cure the curse, but there is PCA.
The “curse of dimensionality” is one of the most important results
in machine learning. Most texts on machine learning mention this
phenomenon in the first chapter or two, but it often takes many years
of practice to understand its true implications.
Classification methods, like most machine learning methods, are
subject to the implications of the curse of dimensionality.The basic
intuition in this case is that as the number of data dimensions
increases, it becomes more difficult to create generalizable
classification models (models that apply well over phenomena not
observed in the training set).This difficulty is usually impossible to
overcome in real world settings.There are some exceptions in domains
where things happen to work out, but usually you must work to
minimize the number of dimensions.This requires a combination
of clever feature engineering and use of dimensionality reduction
techniques (see Feature Engineering and Feature Selection Life in the
Trenches). In our practical experience, the maximum
number of dimensions seems to be ~10 for linear model-based
approaches.The limit seems to be in the tens of thousands for more
sophisticated methods such as support vector machines, but the limit
still exists nonetheless.
A counterintuitive consequence of the curse of dimensionality is
that it limits the amount of data needed to train a classification
model.There are roughly two reasons for this phenomenon. In one
case, the dimensionality is small enough that the model can be
trained on a single machine. In the other case, the exponentially
expanding complexity of a high-dimensionality problem makes it
(practically) computationally impossible to train a model. In our
experience, it is quite rare for a problem to fall in a “sweet spot”
between these two extremes.
This observation is not to say that such a condition never arises. We
believe it is rare enough, however, that practitioners need not concern
themselves with how to address this case. Rather than trying to create
super-scalable algorithm implementations, focus your attention on
solving your immediate problems with basic methods. Wait until you
encounter a problem where an algorithm fails to converge or provides
poor cross-validated results, and then seek new approaches. Only
when you find that alternate approaches don’t already exist, should you
begin building new implementations.The expected cost of this work
pattern is lower than over-engineering right out of the gate.
Put otherwise, “Keep it simple, stupid”.

Baking the Cake
I was once given a time series set of roughly
1,600 predictor variables and 16 target variables
and asked to implement a number of modeling
techniques to predict the target variable
values. The client was challenged to handle the
complexity associated with the large number of
variables and needed help. Not only did I have
a case of the curse, but the predictor variables
were also quite diverse. At first glance, it looked
like trying to bake a cake with everything in the cupboard.
That is not a good way to bake or to make predictions!
The data diversity could be
partially explained by the fact
that the time series predictors
did not all have the same
periodicity. The target time
series were all daily values
whereas the predictors were
daily, weekly, quarterly, and
monthly. This was tricky to
sort out, given that imputing
zeros isn’t likely to produce
good results. For this specific
reason, I chose to use neural
networks for evaluating the
weekly variable contributions.
Using this approach, I was
able to condition upon week,
without greatly increasing
the dimensionality. For the
other predictors, I used
a variety of techniques,
including projection and
correlation, to make heads
or tails of the predictors. My
approach successfully reduced
the number of variables,
accomplishing the client’s goal
of making the problem space
tractable. As a result, the cake
turned out just fine.
››
Stephanie
Rivera

Model Validation
Repeating what you just heard does not mean that you
learned anything.
Model validation is central to construction of any model.This answers
the question “How well did my hypothesis fit the observed data?”
If we do not have enough data, our models cannot connect the dots.
On the other hand, given too much data the model cannot think
outside of the box.The model learns specific details about the training
data that do not generalize to the population.This is the problem of
model over fitting.
Many techniques exist to combat model over fitting.The simplest
method is to split your data set into training, testing and validation
sets.The training data is used to construct the model.The model
constructed with the training data is then evaluated with the testing
data.The performance of the model against the testing set is used to
further reduce model error.This indirectly includes the testing data
within model construction, helping to reduce model over fit. Finally,
the model is evaluated on the validation data to assess how well the
model generalizes.
A few methods where the data is split into training and testing sets
include: k-fold cross-validation, Leave-One-Out cross-validation,
bootstrap methods, and resampling methods. Leave-One-Out cross-
validation can be used to get a sense of ideal model performance
over the training set. A sample is selected from the data to act as the
testing sample and the model is trained on the rest of the data.The
error on the test sample is calculated and saved, and the sample is
returned to the data set. A different sample is then selected and the
process is repeated.This continues until all samples in the testing set
have been used.The average error over the testing examples gives a
measure of the model’s error.
There are other approaches for testing how well your hypothesis
reflects the data. Statistical methods such as calculating the coefficient
of determination, commonly called the R-squared value are used to
identify how much variation in the data your model explains. Note
that as the dimensionality of your feature space grows, the R-squared
value also grows. An adjusted R-squared value compensates for this
phenomenon by including a penalty for model complexity. When
testing the significance of the regression as a whole, the F-test
compares the explained variance to unexplained variance. A regression
result with a high F-statistic and an adjusted R-squared over 0.7 is
almost surely significant.
»Do we really need a case study
to know that you should
check your work?

PU TTING it A L L T O G E T H E R

Consumer Behavior
Analysis from a
Multi-Terabyte
Dataset
Analytic Challenge
After storing over 10 years’ worth of retail
transaction in the natural health space, a retail
client was interested in employing advanced
machine learning techniques to mine the data for
valuable insights. The client wanted to develop a
database structure for long term implementation
of retail supply chain analytics and select the
proper algorithms needed to develop insights
into supplier, retailer, and consumer interactions.
Determining the actual worth of applying big
data analytics to the end-to-end retail supply
chain was also of particular interest.
Our Approach
The client’s data
included 3TBs of
product descriptions,
customer loyalty
information and B2B
and B2C transactions
for thousands of natural
health retailers across
North America. Because
the data had been stored
in an ad-hoc fashion, the
ﬁrst step was creating
a practical database
structure to enable
analytics. We selected
a cloud environment
in order to quickly
implement analytics on
the client’s disparate
and sometimes
redundant datasets.
Once we created a
suitable analytics
architecture, we
moved on to identifying
appropriate machine
learning techniques that
would add value across
three key focus areas:
product receptivity, loyal
program analysis, and
market basket analysis.
For product receptivity,
our team used Bayesian
Belief Networks (BBN)
to develop probabilistic
models to predict the
success, failure, and
longevity of a new or
current product. We
joined transaction data
with attribute data of
both successful and
failed products to
››
» Our Case Studies
Hey, we have given you a lot of
really good technical content. We
know that this section has the look
and feel of marketing material,
but there is still a really good story
here. Remember, storytelling comes
in many forms and styles, one of
which is the marketing version. You
should read this chapter for what it
is – great information told with a
marketing voice.

transform the data into usable
form. Once we created this
data ﬁle, we used it to train
BBNs and create a predictive
model for future products.
For loyalty program analysis, we
joined transactional data and
customer attribute data, which
included location information
and shopping trends. We
used k-means clustering to
segment customers based
on their behavior over time.
This allowed us to cluster
and characterize groups of
customers that exhibited
similar loyalty patterns.
For market basket analysis,
we employed Latent Dirichlet
Allocation (LDA), a natural
language processing technique,
to create consistent product
categorization. The client’s
product categorization was
ad-hoc, having been entered
by individual suppliers and
retailers. As a result, it was
inconsistent and often contained
typographical errors or missing
values. LDA allowed our team
to use the existing text to derive
new, consistent customer
categories for the market basket
analysis. After joining the new
product categorization data
with transaction data, we used
Association Rules Learning
to identify sets of product
categories that customers
tended to purchase together at
individual retailer locations.
Our Impact
Our team provided key ﬁndings and recommendations to describe
how the machine learning techniques could be operationalized
to provide real-time reporting to retailers. The client received
suggestions for improving product nomenclature, product
promotions, and end-to-end visibility of the product and process
lifecycle. As an example, we used our market basket analysis to
create product recommendations for individual retail locations.
Our recommendations have the potential to improve sales
within certain product categories by up to 50% across the retail
network. Together with time savings realized from automated
data processing (such as a 300x increase in product categorization
speed), these insights demonstrated the clear value of big data
analytics to the client’s organization.
93Putting it all Together

Strategic Insights
within Terabytes of
Passenger Data
Analytic Challenge
A commercial airline client was faced with increasing market
competition and challenges in profitability. They wanted to address
these challenges with rapid deployment of advanced, globalized
analytical tools within their private electronic data warehouse.
In the past, the client had analyzed smaller datasets in-house.
Because smaller datasets are filtered or diluted subsets of the
full data, the airline had not been able to extract the holistic
understanding it was seeking.
Booz Allen was engaged to create capabilities to analyze hundreds
of gigabytes of client data. The ultimate goal was to generate
insights into airline operations, investment decisions and consumer
preferences that may not have been apparent from studying data
subsets. Specifically, the airline wanted to be able to understand
issues such as: how they perform in different city-pair markets
relative to competitors; how booking behaviors change, based on
passenger and flight characteristics; and how connection times
impact demand.
Our Solution
Due to data privacy issues, our
team set up a cloud environment
within the client’s electronic
data warehouse. Leveraging
this analytic environment,
analysis proceeded with an
approach that focused on the
client’s three priorities: market
performance, booking behavior,
and passenger choice.
We performed probabilistic
analysis using machine learning
techniques, particularly
Bayesian Belief Networks
(BBN). We merged passenger
booking and other data to
create a BBN training file. Our
team developed and validated
comprehensive BBN models
to represent significant
customer behavior and market-
based factors that influence
passenger preference, with
respect to selection of flights
by connection times. Finally,
our team developed custom big
data visualizations to convey
the findings to technical and
non-technical audiences alike.
››

Our Impact
We demonstrated the ability to rapidly deploy big data analytical
tools and machine learning on massive datasets located inside a
commercial airline’s private cloud environment. Results included
insights that seemed counterintuitive, but could improve financial
performance nonetheless. An example of one such finding was
that under certain circumstances, passengers are willing to pay a
premium to book itineraries with modified connection times. This
translates into a potential revenue increase of many millions of
dollars. These insights, often at the level of named customers, can
be acted upon immediately to improve financial performance.

Savings Through
Better Manufacturing
Analytic Challenge
A manufacturing company engaged Booz Allen to explore data
related to chemical compound production. These processes are
quite complex. They involve a long chain of interconnected events,
which ultimately leads to high variability in product output. This
makes production very expensive.
Understanding the production process is not easy – sensors collect
thousands of time series variables and thousands of point-in-
time measurements, yielding terabytes of data. There was a huge
opportunity if the client could make sense of this data. Reducing the
variance and improving the product yield by even a small amount
could result in significant cost savings.
Our Solution
Due to the size and complexity of
the process data, prior analysis
efforts that focused on data
from only a single sub-process
had limited success. Our Data
Science team took a different
approach: analyzing all the data
from all the sub-processes
with the goal of identifying the
factors driving variation. Once
we understood those factors, we
could develop recommendations
on how to control them to
increase yield. The client’s
process engineers had always
wanted to pursue this approach
but lacked the tools to carry out
the analysis.
We decomposed the problem
into a series of smaller
problems. First, it was
necessary to identify which
time series parameters likely
affected product yield. We
engaged the client’s domain
experts to identify their
hypotheses surrounding the
process. Once we discerned a
set of hypotheses, we identified
the sensors that collected the
relevant data.
We began initial data processing,
which included filtering
bad values and identifying
patterns in the time series. We
then needed to segment the
data streams into individual
production runs. We identified a
sensor that stored the high-level
information indicating when a
production process began. This
sensor provided exactly what we
needed, but we quickly noticed
that half of the expected data
was missing. Examining the
data more closely, we realized
the sensor had only been used
within recent years. We had to
take a step back and reassess
our plan. After discussions
with the domain experts, we
identified a different sensor
››

that gave us raw values directly
from the production process.
The raw values included a tag
that indicated the start of a
production run. The sensor was
active for every production run
and could be used reliably to
segment the data streams into
production runs.
Next, we had to determine
which time series parameters
affected product yield. Using the
cleaned and processed data and
a non-parametric correlation
technique, we compared each
time series in a production
run to all other time series in
that same run. Given the pair-
wise similarities, we estimated
correlation of the similarities
to final product yield. We then
used the correlations as input
into a clustering algorithm to
find clusters of time series
parameters that correlated with
each other in terms of product
yield, not in terms of the time
series themselves. This data
analysis was at a scale not
previously possible – millions
of comparisons for whole
production runs. Engineers were
able to look at all the data for the
first time, and to see impacts
of specific parameters across
different batches and sensors.
In addition to identifying the
key parameters, the engineers
needed to know how to control
the parameters to increase
product yield. Discussions
with domain experts provided
insight into which time series
parameters could be easily
controlled. This limited the
candidate parameters to only
those that the process engineers
could influence. We extracted
features from the remaining
time series signals and fed
them into our models to predict
yield. The models quantified the
correlation between the pattern
of parameter values and yield,
providing insights on how to
increase product yield.
Our Impact
With controls identified and desirable patterns quantified, we
provided the engineers with a set of process control actions
to improve product output. The raw sensor data that came
directly from the production process drove our analysis and
recommendations, thus providing the client with confidence in the
approach. The reduction in product yield variability will enable the
client to produce a better product with lower risk at a reduced cost.

Realizing Higher
Returns Through
Predictive Analytics
Analytic Challenge
A major investment house wanted to explore whether the
application of Data Science techniques could yield increased
investment returns. In particular, the company wanted to predict
future commodity value movements based on end-of-day and
previous-day equity metrics. The client hoped the predictions
could be used to optimize their trading activities. By translating
the approach across their entire portfolio, they could dramatically
improve the yield curve for their investors.
Several challenges were immediately apparent. The data volume
was very large, consisting of information from tens of thousands
of equities, commodities, and options across most major world
markets across multiple time intervals. The need to recommend
a predictive action (go short, go long, stay, increase position size,
or engage in a particular option play) with very low latency was
an even greater challenge. The team would need to develop an
approach that addressed both of these implicit constraints.
Our Solution
The client challenged Booz
Allen to use 3,500 independent
variables to predict the daily
price movements of 16 financial
instruments. The client hid the
meaning and context of the
independent variables, however,
forcing our team to perform
analysis without qualitative
information. The team
immediately began searching
for supplemental data sources.
We identified unstructured data
from other companies, financial
institutions, governments and
social media that could be
used in our analysis. The team
paid considerable attention to
database access efficiency and
security as well as the speed
of computation.
Our team implemented
a multifaceted approach,
including a mix of neural
network optimization and a
variety of principal component,
regression, and unsupervised
learning techniques. We were
able to infer insight into small-
scale exogenous events that
provided a richer basis for
predicting localized fluctuations
in the equity prices. Our
team was able to use these
predictions to determine the
optimal combination of actions
››

that would generate the best
aggregate return over 12 months
of trading. Careful consideration
of the residuals and skilled
modeling of the variance added
additional value to the outcome
for this client.
Our Impact
Our Data Science team conducted an experiment to determine the
efﬁcacy of our approach. We used our model to generate buy/sell
recommendations based on training data provided by the client.
The test cases converged on a set of recommendations in less
than ten minutes, satisfying the solution timeliness constraint. The
experiment revealed a true positive accuracy of approximately 85%
with a similar outcome for true negative accuracy when compared
against optimal recommendations based on perfect information.
The typical return on investment was, as desired, quite large.
The ability to determine the position to take, not just for a single
ﬁnancial instrument but also for a complete portfolio, is invaluable
for this client. Achieving this outcome required predictive analytics
and the ability to rapidly ingest and process large data sets,
including unstructured data. This could not have been accomplished
without a diverse team of talented Data Scientists bringing the
entirety of their tradecraft to bear on the problem.

PARTING
T H O U G H T S
Data Science capabilities are creating data analytics that are
improving every aspect of our lives, from life-saving disease
treatments, to national security, to economic stability, and even
the convenience of selecting a restaurant. We hope we have
helped you truly understand the potential of your data and how
to become extraordinary thinkers by asking the right questions of
your data. We hope we have helped drive forward the science and
art of Data Science. Most importantly, we hope you are leaving
with a newfound passion and excitement for Data Science.
Thank you for taking this journey with us. Please join our
conversation and let your voice be heard. Email us your ideas
and perspectives at data_science@bah.com or submit them
via a pull request on the Github repository.
Tell us and the world what you know. Join us. Become an
author of this story.
››
103Closing Time

REFERENCES
1. Commonly attributed to: Nye, Bill. Reddit Ask Me Anything (AMA).
July 2012. Web. Accessed 15 October 2013. SSRN: <http://www.reddit.
com/r/IAmA/comments/x9pq0/iam_bill_nye_the_science_guy_ama>
2. Fayyad, Usama, Gregory Piatetsky-Shapiro, and Padhraic Smyth. “From
Data Mining to Knowledge Discovery in Databases.” AI Magazine 17.3
(1996): 37-54. Print.
3. “Mining Data for Nuggets of Knowledge.” Knowledge@Wharton,1999.
Web. Accessed 16 October 2013. SSRN: <http://knowledge.wharton.
upenn.edu/article/mining-data-for-nuggets-of-knowledge>
4. Cleveland, William S. “Data Science: An Action Plan for Expanding
the Technical Areas of the Field of Statistics.” International Statistical
Review 69.1 (2001): 21-26. Print.
5. Davenport,Thomas H., and D.J. Patil. “Data Scientist: The Sexiest Job
of the 21st Century.” Harvard Business Review 90.10 (October 2012):
70–76. Print.
6. Smith, David. “Statistics vs Data Science vs BI.” Revolutions, 15
May 2013. Web. Accessed 15 October 2013. SSRN:<http://blog.
revolutionanalytics.com/2013/05/statistics-vs-data-science-vs-bi.html>
7. Brynjolfsson, Erik, Lorin M. Hitt, and Heekyung H. Kim. “Strength
in Numbers: How Does Data-Driven Decision Making Affect Firm
Performance?” Social Science Electronic Publishing, 22 April 2011. Web.
Accessed 15 October 2013. SSRN: <http://ssrn.com/abstract=1819486
or http://dx.doi.org/10.2139/ssrn.1819486>
8. “The Stages of an Analytic Enterprise.” Nucleus Research. February 2012.
Whitepaper.
9. Barua, Anitesh, Deepa Mani, and Rajiv Mukherjee. “Measuring the
Business Impacts of Effective Data.” University of Texas. Web. Accessed
15 October 2013. SSRNL: <http://www.sybase.com/files/White_Papers/
EffectiveDataStudyPt1-MeasuringtheBusinessImpactsofEffectiveDa
ta-WP.pdf>
››

10. Zikopoulos, Paul, Dirk deRoos, Kirshnan Parasuraman,Thomas Deutsch,
David Corrigan and James Giles. Harness the Power of Big Data: The IBM
Big Data Platform. New York: McGraw Hill, 2013. Print. 281pp.
11. Booz Allen Hamilton. Cloud Analytics Playbook. 2013. Web. Accessed 15
October 2013. SSRN: <http://www.boozallen.com/media/file/Cloud-
playbook-digital.pdf>
12. Conway, Drew. “The Data Science Venn Diagram.” March 2013.
Web. Accessed 15 October 2013. SSRN: <http://drewconway.com/
zia/2013/3/26/the-data-science-venn-diagram>
13. Torán, Jacobo. “On the Hardness of Graph Isomorphism.” SIAM Journal
on Computing. 33.5 (2004): 1093-1108. Print.
14. Guyon, Isabelle and Andre Elisseeff. “An Introduction to Variable and
Feature Selection.” Journal of Machine Learning Research 3 (March
2003):1157-1182. Print.
15. Golub T., D. Slonim, P.Tamayo, C. Huard, M. Gaasenbeek, J. Mesirov,
H. Coller, M. Loh, J. Downing, M. Caligiuri, C. Bloomfield, and E.
Lander. “Molecular Classification of Cancer: Class Discovery and Class
Prediction by Gene Expression Monitoring.” Science. 286.5439 (1999):
531-537. Print.
16. Haykin, Simon O. Neural Networks and Learning Machines. New Jersey:
17. De Jong, Kenneth A. Evolutionary Computation - A Unified Approach.
Massachusetts: MIT Press, 2002. Print.
18. Yacci, Paul, Anne Haake, and Roger Gaborski. “Feature Selection of
Microarray Data Using Genetic Algorithms and Artificial Neural
Networks.” ANNIE 2009. St Louis, MO. 2-4 November 2009.
Conference Presentation.
105Closing Time

About
BOOZ ALLEN
H A M I L T O N
Booz Allen Hamilton has been at the forefront of strategy and
technology consulting for nearly a century. Today, Booz Allen
is a leading provider of management consulting, technology, and
engineering services to the US government in defense, intelligence,
and civil markets, and to major corporations, institutions, and not-
for-profit organizations. In the commercial sector, the firm focuses
on leveraging its existing expertise for clients in the financial
services, healthcare, and energy markets, and to international clients
in the Middle East. Booz Allen offers clients deep functional
knowledge spanning consulting, mission operations, technology, and
engineering—which it combines with specialized expertise in clients’
mission and domain areas to help solve their toughest problems.
The firm’s management consulting heritage is the basis for its unique
collaborative culture and operating model, enabling Booz Allen
to anticipate needs and opportunities, rapidly deploy talent and
resources, and deliver enduring results. By combining a consultant’s
problem-solving orientation with deep technical knowledge and
strong execution, Booz Allen helps clients achieve success in their
most critical missions—as evidenced by the firm’s many client
relationships that span decades. Booz Allen helps shape thinking
and prepare for future developments in areas of national importance,
including cybersecurity, homeland security, healthcare, and
information technology.
Booz Allen is headquartered in McLean, Virginia, employs more than
23,000 people, and had revenue of $5.76 billion for the 12 months
ended March 31, 2013. For over a decade, Booz Allen’s high standing
as a business and an employer has been recognized by dozens of
organizations and publications, including Fortune, Working Mother,
G.I. Jobs, and DiversityInc. More information is available at
www.boozallen.com. (NYSE: BAH)
››
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