Unmasking AI

My Mission to Protect What Is Human in a World of Machines

Look inside
Paperback
$22.00 US
5.19"W x 7.97"H x 0.7"D  
On sale Nov 19, 2024 | 336 Pages | 9780593241844
Grades 9-12 + AP/IB
“The conscience of the AI revolution” (Fortune) explains how we’ve arrived at an era of AI harms and oppression, and what we can do to avoid its pitfalls.

Selected for common reading at University of Washington

To most of us, it seems like recent developments in artificial intelligence emerged out of nowhere to pose unprecedented threats to humankind. But to Dr. Joy Buolamwini, who has been at the forefront of AI research, this moment has been a long time in the making.

After tinkering with robotics as a high school student in Memphis and then developing mobile apps in Zambia as a Fulbright fellow, Buolamwini followed her lifelong passion for computer science, engineering, and art to MIT in 2015. As a graduate student at the “Future Factory,” she did groundbreaking research that exposed widespread racial and gender bias in AI services from tech giants across the world.

Unmasking AI goes beyond the headlines about existential risks produced by Big Tech. It is the remarkable story of how Buolamwini uncovered what she calls “the coded gaze”—the evidence of encoded discrimination and exclusion in tech products—and how she galvanized the movement to prevent AI harms by founding the Algorithmic Justice League. Applying an intersectional lens to both the tech industry and the research sector, she shows how racism, sexism, colorism, and ableism can overlap and render broad swaths of humanity “excoded” and therefore vulnerable in a world rapidly adopting AI tools. Computers, she reminds us, are reflections of both the aspirations and the limitations of the people who create them.

Encouraging experts and non-experts alike to join this fight, Buolamwini writes, “The rising frontier for civil rights will require algorithmic justice. AI should be for the people and by the people, not just the privileged few.”

“Dr. Joy Buolamwini has been an essential figure in bringing irresponsible, profit-hungry tech giants to their knees. If you’re going to read only one book about AI, this should be it.”—Darren Walker, president of the Ford Foundation

A LOS ANGELES TIMES BEST BOOK OF THE YEAR • Shortlisted for the Inc. Non-Obvious Book Award

© Naima Green
Dr. Joy Buolamwini is the founder of the Algorithmic Justice League, a groundbreaking researcher, and a renowned speaker. Her writing has been featured in publications such as Time, The New York Times, Harvard Business Review, and The Atlantic. As the Poet of Code, she creates art to illuminate the impact of artificial intelligence on society and advises world leaders on preventing AI harms. She is the recipient of numerous awards, including the Rhodes Scholarship, the inaugural Morals & Machines Prize, and the Technological Innovation Award from the Martin Luther King Jr. Center for Nonviolent Social Change. Her MIT research on facial recognition technologies is featured in the Emmy-nominated documentary Coded Bias. Born in Canada to Ghanaian immigrants, Buolamwini lives in Cambridge, Massachusetts. View titles by Joy Buolamwini
Chapter 1

Daughter of Art and Science


I am the daughter of art and science. My mother, Frema the Akan, is the first artist I knew. As a child, I sat next to her as she filled canvas after canvas with powerful colors and made creative ideas reality. Art supplies littered our garage, mixed among drawing books, portfolios, artificial fruits, and flowers. My mother explored human conditions of the heart. Her work, she told me, was aimed at moving people to experience healing, to glimpse the divine, to be enraptured and swept into another place of awareness. I would observe her, deep in focus, considering the next stroke to apply to an evolving piece of art. Her experiments and works in progress were a constant presence for me. Seeing her sculpt, paint, draw, and etch out art was a delight to my senses. Her four-­foot paintings towered over me, and the smells of charcoal and turpentine tantalized my nose. Our world was an open invitation for me to try my hand at creative expression. I soon had sketchbooks filled with whatever had recently caught my interest—­ramps, skateboards, mustangs, animated characters, guitars, and amplifiers. My mother’s voice of encouragement, a constant echo, gave me the audacity to explore my capacities and my curiosity. But artistic experiments were not the only ones that peppered my childhood.

My father, Dr. John Buolamwini, is the first scientist I knew. He worked on topics that would take time for me to learn to pronounce: medical chemistry, pharmaceutical sciences, and computer- aided drug discovery using neural nets. Trips to his lab were fun and full of many things not to touch, a lesson I often learned the hard way. Chalk is not for eating. Dry ice burns. Walking to his office I would see hallways filled with scientific posters as he waved to colleagues and students. And then if I was lucky, while he worked on the latest grant, research paper, or other desk work, I got to play on one of the computers. When he walked to the freezer in his lab I trailed him like a shadow. He put on purple gloves, pulled out a tray, and placed it on a lab bench. I struggled to get the oversized gloves on my hands as my dad beamed at my efforts. Once I was protected, he placed a pipette in my grasp and gently applied pressure on my right thumb with his. Liquid drops bathed the cancer cells beneath our cradled hands, while my eyes widened with fascination and his beard tickled my head. Next to the lab bench sat more computers. He would show me machines linked to concepts like flow cytometry. I would look at the squiggles on the computers that I would later learn to call graphs.

Like my mother, he was working on experiments that required bold curiosity to ask unexplored questions. But while my mother asked questions of colors, my father asked questions of cells. In the midst of their explorations, I began to ask questions about computers. For instance, how did the images that I saw on the scientific papers come to be? They looked like abstract paintings to me. My dad showed me the software on his huge Silicon Graphics computers that would create these images containing ringlets and rods of bright reds and blues, representing different protein structures. The goal of feeding the cells, designing medicinal drugs on the computer, running all the tests, and scrutinizing the squiggles was to help people who were struggling with different conditions, from heart disease to breast cancer. He showed me the software to introduce me to chemistry, but I found myself more and more enamored with the machines themselves. I quickly found games like Doom and Cycle that came preloaded. I listened to the whirs and beeps of a dial-­up connection. In that office, I opened Netscape, my first browser experience into a portal I would later learn was the internet.

And so it was that, surrounded by art and science from a very young age, I was emboldened to explore, to ask questions, to dare to alter what seemed fixed, and also to view the artist’s and the scientist’s search for truth as common companions.

My parents taught me that the unknown was an invitation to learn, not a menacing dimension to avoid. Ignorance was a starting place to enter deeper realms of understanding. At some point, though, they would tire of my endless questions; after entertaining my curiosity for some time, my mother would sometimes bring me back down to earth with a gentle, “Why has a long tail . . .” elongating her words as she spoke. In addition to my parents, I turned to another source of knowledge, television. As first-­generation immigrants settling into Oxford, Mississippi, my parents wouldn’t let me watch commercials: They wanted to shield me from the materialism that appeared to be the backbone of American culture. “You will never find your worth in things,” they cautioned. However, they encouraged me to watch educational programs, so PBS became the television channel of choice in our home. I soon found myself anticipating shows like Nature, National Geographic, Nova, and Scientific American Frontier.

There was one episode in particular that left a lasting impact on me. When I was around nine years old, I watched a segment about robots. The program host visited a place called the Massachusetts Institute of Technology. He spoke to a graduate student named Cynthia Breazeal about her work on what she called social robots. Unlike the industrial robots I had seen before—­hulking machinery set to tasks like stamping out sheet metal—­her social robot was not focused on work but on connection and communication. She sat next to a robot she had built named Kismet, a dazzling and intricate web of metal and wires topped off with enchanting eyes, animated ears, and a cheeky smile. The moment I saw the machine appear to come to life, I was mesmerized. Could I make something like Kismet? Could I go to a place like MIT, the ever-present backdrop to so many of the science and technology shows I watched? From that moment, I decided I wanted to go to MIT and become a robotics engineer. I was blissfully unaware of any barriers or requirements. I had more questions to ask of computers, nurtured in the incubator of youthful possibilities by the belief that I could become anything I imagined.

My first step toward building robots was learning how to program machines to do what I wanted. To give machines instruction, I discovered different kinds of programming languages. I started by learning the basics of HTML and CSS to build a website. These programming languages focused on structure and formatting. HTML allowed me to define the elements I wanted to see on a webpage, like a block of text, a button, or an image. CSS let me determine what these elements would look like, from the color of the text to how much space existed between elements. Each programming language had its own rules for how to give a computer directions. Soon enough I was using these skills to code websites for my high school sports teams and make some pocket money or barter. Even if I was a benchwarmer on the basketball team, at least I did not have to pay for my uniform or shoes.

I wanted to go deeper than websites, and I was curious about how to make games like the ones I played with my brother on his Nintendo 64 or Tony Hawk Pro Skater 2, which I enjoyed on my Sony PlayStation. So I learned another programming language called Java. Here, I was introduced to the concept of an algorithm. An algorithm, at its most basic definition, is a sequence of instructions used to achieve a specific goal. To make my character move around the screen, I would write code that followed a logical sequence. For instance, if the user hits the left arrow, move the character left on the screen. Algorithms like this, as I would eventually learn, would become the basis for more powerful and dynamic systems.

I followed my desire to work on robotics into college. By my third year at the Georgia Institute of Technology in Atlanta, I was working on social robots. One of the professors I worked with, Andrea Thomaz, was a former student of Cynthia Breazeal’s. And to my delight, when I started working on Tho­maz’s robot Simon, I learned that the code that was used to power it had descended from the CREATURES code library that once animated Kismet. My assignment with Simon was to see if I could have the robot engage in a social interaction with a human. I settled on working on a project called peekaboo Simon. The aim was to have the robot participate in a simple turn-­taking game with a human partner, similar to one that a parent might play with a young child. The larger aim behind this project was to see if we could have a robot play social games with young children and analyze how children responded and behaved during those interactions, thereby helping to diagnose early developmental delays or even early signs of autism. This kind of early detection could help a child receive necessary support as soon as possible.

To make this game work, I would need to get Simon the robot to detect a human face and direct its head toward the person. This was my introduction to face detection.

First-Year Reading (FYR) Guide for Unmasking AI

Designed specifically to be used by faculty or program facilitators for college First-Year Common Reading programs.

(Please note: the guide displayed here is the most recently uploaded version; while unlikely, any page citation discrepancies between the guide and book is likely due to pagination differences between a book’s different formats.)

 “A triumph in a literary work about artificial intelligence." —Business Insider
 
“[Joy] Buolamwini’s book recounts her journey to become one of the nation’s preeminent scholars and critics of artificial intelligence . . . and offers readers a compelling, digestible guide to some of the most pressing issues in the field.” —Los Angeles Times
 
“Buolamwini looks at the social implications of the technology and warns that biases in facial analysis systems could harm millions of people—especially if they reinforce existing stereotypes.” —NPR

“This revelatory book exposes the myriad, deeply ingrained biases encoded into facial recognition and other ‘trusted’ AI systems, pushing us to confront our blind trust in the machines that are taking over our lives. In describing how she conquered her own demons along her path towards justice for all, Dr. Joy Buolamwini offers a deeply felt, stirring call to action for ethical AI—a must-read for those who want a world in which technology serves humanity.”—Maria Ressa, Nobel Peace Prize winner, CEO and president of Rappler

“In a world plagued by AI harms and threats to our civil rights, Dr. Joy Buolamwini has been an essential figure in bringing irresponsible, profit-hungry tech giants to their knees. Unmasking AI is an inspiring story about her journey from precocious student to groundbreaking pioneer in a field where women like herself are often rendered invisible. If you’re going to read only one book about AI, this should be it.”—Darren Walker, president of the Ford Foundation

“Joy Buolamwini is a unique and powerful intellectual force, and this book explains why. We are honored to follow her on each step of her journey from an earnest and diligent grad student to an outspoken and celebrated role model for algorithmic justice, rooting for her and likewise for our combined future.”—Cathy O’Neil, author of Weapons of Math Destruction

Unmasking AI shows Dr. Joy Buolamwini’s unmatched ability to break down complex topics for a wide audience. While taking us through her journey from a curious scientist excited by the possibilities of AI to one who uncovers its harms, Buolamwini breaks down the past, present, and future of AI harms in a manner that allows everyone to understand and participate in resisting them. This book is yet another artifact of her excellence.”—Timnit Gebru, founder of Distributed AI Research Institute and co-founder of Black in AI

“Through stories that are both personal and deeply relevant for all of humanity, Dr. Joy Buolamwini brings wit and clarity to the punishing reality of AI bias. Unmasking AI illuminates achievable paths for the world’s future that are far more promising and just than our current trajectories.”—Megan Smith, former chief technology officer of the United States, member of the National Academy of Engineering, and CEO of shift7

“This is as much a memoir as it is a clarion call for change. Unmasking AI belongs alongside Cathy O’Neil’s Weapons of Math Destruction and Safiya Umoja Noble’s Algorithms of Oppression as essential warnings for our time. It’s an important corrective to our unquestioning embrace of technology.”Booklist starred review

“[A] trenchant debut . . . Buolamwini proves that she’s among the sharpest critics of AI, and her list of principles for achieving ‘algorithmic justice,’ which includes the stipulation that ‘people have a voice’ in shaping the algorithms that influence their lives, charts a path forward. Urgent and incisive, this is a vital examination of AI’s pitfalls.”Publishers Weekly

About

“The conscience of the AI revolution” (Fortune) explains how we’ve arrived at an era of AI harms and oppression, and what we can do to avoid its pitfalls.

Selected for common reading at University of Washington

To most of us, it seems like recent developments in artificial intelligence emerged out of nowhere to pose unprecedented threats to humankind. But to Dr. Joy Buolamwini, who has been at the forefront of AI research, this moment has been a long time in the making.

After tinkering with robotics as a high school student in Memphis and then developing mobile apps in Zambia as a Fulbright fellow, Buolamwini followed her lifelong passion for computer science, engineering, and art to MIT in 2015. As a graduate student at the “Future Factory,” she did groundbreaking research that exposed widespread racial and gender bias in AI services from tech giants across the world.

Unmasking AI goes beyond the headlines about existential risks produced by Big Tech. It is the remarkable story of how Buolamwini uncovered what she calls “the coded gaze”—the evidence of encoded discrimination and exclusion in tech products—and how she galvanized the movement to prevent AI harms by founding the Algorithmic Justice League. Applying an intersectional lens to both the tech industry and the research sector, she shows how racism, sexism, colorism, and ableism can overlap and render broad swaths of humanity “excoded” and therefore vulnerable in a world rapidly adopting AI tools. Computers, she reminds us, are reflections of both the aspirations and the limitations of the people who create them.

Encouraging experts and non-experts alike to join this fight, Buolamwini writes, “The rising frontier for civil rights will require algorithmic justice. AI should be for the people and by the people, not just the privileged few.”

“Dr. Joy Buolamwini has been an essential figure in bringing irresponsible, profit-hungry tech giants to their knees. If you’re going to read only one book about AI, this should be it.”—Darren Walker, president of the Ford Foundation

A LOS ANGELES TIMES BEST BOOK OF THE YEAR • Shortlisted for the Inc. Non-Obvious Book Award

Author

© Naima Green
Dr. Joy Buolamwini is the founder of the Algorithmic Justice League, a groundbreaking researcher, and a renowned speaker. Her writing has been featured in publications such as Time, The New York Times, Harvard Business Review, and The Atlantic. As the Poet of Code, she creates art to illuminate the impact of artificial intelligence on society and advises world leaders on preventing AI harms. She is the recipient of numerous awards, including the Rhodes Scholarship, the inaugural Morals & Machines Prize, and the Technological Innovation Award from the Martin Luther King Jr. Center for Nonviolent Social Change. Her MIT research on facial recognition technologies is featured in the Emmy-nominated documentary Coded Bias. Born in Canada to Ghanaian immigrants, Buolamwini lives in Cambridge, Massachusetts. View titles by Joy Buolamwini

Excerpt

Chapter 1

Daughter of Art and Science


I am the daughter of art and science. My mother, Frema the Akan, is the first artist I knew. As a child, I sat next to her as she filled canvas after canvas with powerful colors and made creative ideas reality. Art supplies littered our garage, mixed among drawing books, portfolios, artificial fruits, and flowers. My mother explored human conditions of the heart. Her work, she told me, was aimed at moving people to experience healing, to glimpse the divine, to be enraptured and swept into another place of awareness. I would observe her, deep in focus, considering the next stroke to apply to an evolving piece of art. Her experiments and works in progress were a constant presence for me. Seeing her sculpt, paint, draw, and etch out art was a delight to my senses. Her four-­foot paintings towered over me, and the smells of charcoal and turpentine tantalized my nose. Our world was an open invitation for me to try my hand at creative expression. I soon had sketchbooks filled with whatever had recently caught my interest—­ramps, skateboards, mustangs, animated characters, guitars, and amplifiers. My mother’s voice of encouragement, a constant echo, gave me the audacity to explore my capacities and my curiosity. But artistic experiments were not the only ones that peppered my childhood.

My father, Dr. John Buolamwini, is the first scientist I knew. He worked on topics that would take time for me to learn to pronounce: medical chemistry, pharmaceutical sciences, and computer- aided drug discovery using neural nets. Trips to his lab were fun and full of many things not to touch, a lesson I often learned the hard way. Chalk is not for eating. Dry ice burns. Walking to his office I would see hallways filled with scientific posters as he waved to colleagues and students. And then if I was lucky, while he worked on the latest grant, research paper, or other desk work, I got to play on one of the computers. When he walked to the freezer in his lab I trailed him like a shadow. He put on purple gloves, pulled out a tray, and placed it on a lab bench. I struggled to get the oversized gloves on my hands as my dad beamed at my efforts. Once I was protected, he placed a pipette in my grasp and gently applied pressure on my right thumb with his. Liquid drops bathed the cancer cells beneath our cradled hands, while my eyes widened with fascination and his beard tickled my head. Next to the lab bench sat more computers. He would show me machines linked to concepts like flow cytometry. I would look at the squiggles on the computers that I would later learn to call graphs.

Like my mother, he was working on experiments that required bold curiosity to ask unexplored questions. But while my mother asked questions of colors, my father asked questions of cells. In the midst of their explorations, I began to ask questions about computers. For instance, how did the images that I saw on the scientific papers come to be? They looked like abstract paintings to me. My dad showed me the software on his huge Silicon Graphics computers that would create these images containing ringlets and rods of bright reds and blues, representing different protein structures. The goal of feeding the cells, designing medicinal drugs on the computer, running all the tests, and scrutinizing the squiggles was to help people who were struggling with different conditions, from heart disease to breast cancer. He showed me the software to introduce me to chemistry, but I found myself more and more enamored with the machines themselves. I quickly found games like Doom and Cycle that came preloaded. I listened to the whirs and beeps of a dial-­up connection. In that office, I opened Netscape, my first browser experience into a portal I would later learn was the internet.

And so it was that, surrounded by art and science from a very young age, I was emboldened to explore, to ask questions, to dare to alter what seemed fixed, and also to view the artist’s and the scientist’s search for truth as common companions.

My parents taught me that the unknown was an invitation to learn, not a menacing dimension to avoid. Ignorance was a starting place to enter deeper realms of understanding. At some point, though, they would tire of my endless questions; after entertaining my curiosity for some time, my mother would sometimes bring me back down to earth with a gentle, “Why has a long tail . . .” elongating her words as she spoke. In addition to my parents, I turned to another source of knowledge, television. As first-­generation immigrants settling into Oxford, Mississippi, my parents wouldn’t let me watch commercials: They wanted to shield me from the materialism that appeared to be the backbone of American culture. “You will never find your worth in things,” they cautioned. However, they encouraged me to watch educational programs, so PBS became the television channel of choice in our home. I soon found myself anticipating shows like Nature, National Geographic, Nova, and Scientific American Frontier.

There was one episode in particular that left a lasting impact on me. When I was around nine years old, I watched a segment about robots. The program host visited a place called the Massachusetts Institute of Technology. He spoke to a graduate student named Cynthia Breazeal about her work on what she called social robots. Unlike the industrial robots I had seen before—­hulking machinery set to tasks like stamping out sheet metal—­her social robot was not focused on work but on connection and communication. She sat next to a robot she had built named Kismet, a dazzling and intricate web of metal and wires topped off with enchanting eyes, animated ears, and a cheeky smile. The moment I saw the machine appear to come to life, I was mesmerized. Could I make something like Kismet? Could I go to a place like MIT, the ever-present backdrop to so many of the science and technology shows I watched? From that moment, I decided I wanted to go to MIT and become a robotics engineer. I was blissfully unaware of any barriers or requirements. I had more questions to ask of computers, nurtured in the incubator of youthful possibilities by the belief that I could become anything I imagined.

My first step toward building robots was learning how to program machines to do what I wanted. To give machines instruction, I discovered different kinds of programming languages. I started by learning the basics of HTML and CSS to build a website. These programming languages focused on structure and formatting. HTML allowed me to define the elements I wanted to see on a webpage, like a block of text, a button, or an image. CSS let me determine what these elements would look like, from the color of the text to how much space existed between elements. Each programming language had its own rules for how to give a computer directions. Soon enough I was using these skills to code websites for my high school sports teams and make some pocket money or barter. Even if I was a benchwarmer on the basketball team, at least I did not have to pay for my uniform or shoes.

I wanted to go deeper than websites, and I was curious about how to make games like the ones I played with my brother on his Nintendo 64 or Tony Hawk Pro Skater 2, which I enjoyed on my Sony PlayStation. So I learned another programming language called Java. Here, I was introduced to the concept of an algorithm. An algorithm, at its most basic definition, is a sequence of instructions used to achieve a specific goal. To make my character move around the screen, I would write code that followed a logical sequence. For instance, if the user hits the left arrow, move the character left on the screen. Algorithms like this, as I would eventually learn, would become the basis for more powerful and dynamic systems.

I followed my desire to work on robotics into college. By my third year at the Georgia Institute of Technology in Atlanta, I was working on social robots. One of the professors I worked with, Andrea Thomaz, was a former student of Cynthia Breazeal’s. And to my delight, when I started working on Tho­maz’s robot Simon, I learned that the code that was used to power it had descended from the CREATURES code library that once animated Kismet. My assignment with Simon was to see if I could have the robot engage in a social interaction with a human. I settled on working on a project called peekaboo Simon. The aim was to have the robot participate in a simple turn-­taking game with a human partner, similar to one that a parent might play with a young child. The larger aim behind this project was to see if we could have a robot play social games with young children and analyze how children responded and behaved during those interactions, thereby helping to diagnose early developmental delays or even early signs of autism. This kind of early detection could help a child receive necessary support as soon as possible.

To make this game work, I would need to get Simon the robot to detect a human face and direct its head toward the person. This was my introduction to face detection.

Guides

First-Year Reading (FYR) Guide for Unmasking AI

Designed specifically to be used by faculty or program facilitators for college First-Year Common Reading programs.

(Please note: the guide displayed here is the most recently uploaded version; while unlikely, any page citation discrepancies between the guide and book is likely due to pagination differences between a book’s different formats.)

Praise

 “A triumph in a literary work about artificial intelligence." —Business Insider
 
“[Joy] Buolamwini’s book recounts her journey to become one of the nation’s preeminent scholars and critics of artificial intelligence . . . and offers readers a compelling, digestible guide to some of the most pressing issues in the field.” —Los Angeles Times
 
“Buolamwini looks at the social implications of the technology and warns that biases in facial analysis systems could harm millions of people—especially if they reinforce existing stereotypes.” —NPR

“This revelatory book exposes the myriad, deeply ingrained biases encoded into facial recognition and other ‘trusted’ AI systems, pushing us to confront our blind trust in the machines that are taking over our lives. In describing how she conquered her own demons along her path towards justice for all, Dr. Joy Buolamwini offers a deeply felt, stirring call to action for ethical AI—a must-read for those who want a world in which technology serves humanity.”—Maria Ressa, Nobel Peace Prize winner, CEO and president of Rappler

“In a world plagued by AI harms and threats to our civil rights, Dr. Joy Buolamwini has been an essential figure in bringing irresponsible, profit-hungry tech giants to their knees. Unmasking AI is an inspiring story about her journey from precocious student to groundbreaking pioneer in a field where women like herself are often rendered invisible. If you’re going to read only one book about AI, this should be it.”—Darren Walker, president of the Ford Foundation

“Joy Buolamwini is a unique and powerful intellectual force, and this book explains why. We are honored to follow her on each step of her journey from an earnest and diligent grad student to an outspoken and celebrated role model for algorithmic justice, rooting for her and likewise for our combined future.”—Cathy O’Neil, author of Weapons of Math Destruction

Unmasking AI shows Dr. Joy Buolamwini’s unmatched ability to break down complex topics for a wide audience. While taking us through her journey from a curious scientist excited by the possibilities of AI to one who uncovers its harms, Buolamwini breaks down the past, present, and future of AI harms in a manner that allows everyone to understand and participate in resisting them. This book is yet another artifact of her excellence.”—Timnit Gebru, founder of Distributed AI Research Institute and co-founder of Black in AI

“Through stories that are both personal and deeply relevant for all of humanity, Dr. Joy Buolamwini brings wit and clarity to the punishing reality of AI bias. Unmasking AI illuminates achievable paths for the world’s future that are far more promising and just than our current trajectories.”—Megan Smith, former chief technology officer of the United States, member of the National Academy of Engineering, and CEO of shift7

“This is as much a memoir as it is a clarion call for change. Unmasking AI belongs alongside Cathy O’Neil’s Weapons of Math Destruction and Safiya Umoja Noble’s Algorithms of Oppression as essential warnings for our time. It’s an important corrective to our unquestioning embrace of technology.”Booklist starred review

“[A] trenchant debut . . . Buolamwini proves that she’s among the sharpest critics of AI, and her list of principles for achieving ‘algorithmic justice,’ which includes the stipulation that ‘people have a voice’ in shaping the algorithms that influence their lives, charts a path forward. Urgent and incisive, this is a vital examination of AI’s pitfalls.”Publishers Weekly

Books for Native American Heritage Month

In celebration of Native American Heritage Month this November, Penguin Random House Education is highlighting books that detail the history of Native Americans, and stories that explore Native American culture and experiences. Browse our collections here: Native American Creators Native American History & Culture

Read more

2024 Middle and High School Collections

The Penguin Random House Education Middle School and High School Digital Collections feature outstanding fiction and nonfiction from the children’s, adult, DK, and Grupo Editorial divisions, as well as publishers distributed by Penguin Random House. Peruse online or download these valuable resources to discover great books in specific topic areas such as: English Language Arts,

Read more

PRH Education High School Collections

All reading communities should contain protected time for the sake of reading. Independent reading practices emphasize the process of making meaning through reading, not an end product. The school culture (teachers, administration, etc.) should affirm this daily practice time as inherently important instructional time for all readers. (NCTE, 2019)   The Penguin Random House High

Read more

PRH Education Translanguaging Collections

Translanguaging is a communicative practice of bilinguals and multilinguals, that is, it is a practice whereby bilinguals and multilinguals use their entire linguistic repertoire to communicate and make meaning (García, 2009; García, Ibarra Johnson, & Seltzer, 2017)   It is through that lens that we have partnered with teacher educators and bilingual education experts, Drs.

Read more

New Thematic Educator Guides: Teaching Media Literacy

The COVID-19 global pandemic forever changed the way humans interact with information and with each other. Social media saved us from disconnection, but it also provided an opportunity for the dissemination of disinformation, the rise of polarization, and the distrust of traditional news media. Amidst concerns over children’s mental health and internet communication, many state

Read more